Organophosphorus Chemistry Volume 18
A Specialist Periodical Report
Organophosphorus Chemistry Volume 18 ~~
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Organophosphorus Chemistry Volume 18
A Specialist Periodical Report
Organophosphorus Chemistry Volume 18 ~~
~
A Review of the Literature published between July 1985 and June 1986 Senior Reporter
B. J. Walker, Department of Chemistry, David Keir Building, The Queen's University of Belfast Reporters
C. W. Allen, University of Vermont, U.S.A. D. W. Allen, Sheffield City Polytechnic
0. Dahl, University of Copenhagen, Denmark
R. S. Edmundson, formerly of University of Bradford C. D. Hall, King's College, London
J. B. Hobbs, The City University, London J. C. Tebby, North Staffordshire Polytechnic, Stoke-on- Trent
SOCIETY OF HEMISTRY
ISBN 0-85186-166-0 ISSN 0306-0713 Copyright 0 1987 The Royal Society of Chemistry
All Rights Reserved No part of this book may be reproduced or transmitted in any form or by any means-graphic, electronic, including photocopying, recording, taping, or information storage and retrieval systems- without written permksion from the Royal Society of Chemistry
Published by The Royal Society of Chemistry Burlington House, London, W1V OBN Printed in Great Britain by Staples Printers Rochester Limited, Love Lane, Rochester, Kent.
Introduction Professor Stewart Trippett is an initiator and has led the development of modern organophosphorus chemistry. He is also a founder and the original Senior Reporter of this Report and we were all concerned to hear 0.f his recent illness. colleagues wish him well.
A l l his friends and
It is appropriate and significant that
the areas where he has contributed so much, those of the Wittig reaction and hypervalent intermediates, are still among the most actively investigated topics. The increased availability of "user friendly" MO programmes is reflected in the proliferation of papers concerned with theoretical aspects. In view of this Professor John Tebby has agreed to add to his chapter on Physical Methods a new section significally covering this area. The continuing revelations of enzyme-like activity of certain RNA molecules offer new opportunities and challenges for both
chemists and biochemists. This must result in an increased demand for oligoribonucleotides of defined sequence and significant e f f o r t s have been made to improve methods of synthesis with the ultimate aim to render it as easy and reliable as present-day oligodeoxyribonucleotide synthesis. While this latter process is still being refined, the ready accessibility of oligodeoxyribonucleotides of defined sequence prepared on automated synthesizers using phosphoramidite chemistry is permitting chemists, biochemists and molecular biologists to address problems previously beyond reach. Oligodeoxyribonucleotide analogues containing methylphosphonate linkages offer exciting prospects for the control of gene expression in living systems, as also do sequence-specific DNA cleavage agents. The interest in pT-bonded phosphorus, as measured by the number of publications, continues to increase (the fairly small number of phospnaalkynes known has been significantly increased and all show very high field 31P chemical shifts). However, there are some signs that we are approaching a point where consolidation, rather than exciting new results, will dominate the subject area.
Introduction
vi
There has been c o n t r o v e r s y o v e r t h e mechanism o f h y d r o l y s i s o f e t h y l e n e methyl p h o s p h a t e and i n v e s t i g a t i o n s i n t o t h e n a t u r e o f metaphosphate and i t s r o l e i n t h E h y d r o l y s i s o f p h o s p h o r u s e s t e r s have c o n t i n u e d .
Elegant experiments r e l a t i n g t o each of these
problems have been r e p o r t e d . I n v e s t i g a t i o n s o f h y p e r v a l e n t p h o s p h o r u s compounds have t e n d e d t o c o n c e n t r a t e on t h e more s t a b l e b i c y c l i c s y s t e m s .
Elegant s t u d i e s
of s p i r o p h o s p h o r a n e s and a t h o r o u g h i n v e s t i g a t i o n o f p e r m u t a t i o n a l i s o m e r i s a t i o n s w i t h i n amidinium f l u o r p h o s p h a t e s a r e w o r t h n o t i n g . The n o t a b l e i n c r e a s e s i n t h e o r e t i c a l s t u d i e s o f y l i d e s and t h e i r r e a c t i o n s r e f l e c t s s i m i l a r developments t h r o u g h o u t o r g a n i c chemistry.
The renewed i n t e r e s t i n t h e mechanism o f t h e W i t t i g
r e a c t i o n have c o n t i n u e d , b u t i n s p i t e of s e v e r a l y e a r s o f c o n s i d e r a b l e e f f o r t from a number o f r e s p e c t e d r e s e a r c h g r o u p s a f u l l y s a t i s f a c t o r y e x p l a n a t i o n i s s t i l l some way o f f . Work on phosphazene h i g h polymers c o n t i n u e s t o a t t r a c t increased interest.
Advances i n t h e s t u d y o f t h e r i n g - o p e n i n g
p o l y m e r i z a t i o n , and p h y s i c a l c h a r a c t e r i z a t i o n i n t h e s o l i d s t a t e , o f t h e m a t e r i a l s produced by t h e s e r e a c t i o n s have been r e p o r t e d . A number o f a b i n i t i o m o l e c u l a r o r b i t a l c a l c u l a t i o n s have b e e n
p e r f o r m e d on a c y c l i c and c y c l i c p h o s p h a z e n e s .
These c a l c u l a t i o n s
p o i n t t o a p h o s p h o r u s - n i t r o g e n bond w i t h a l a r g e d e g r e e o f c h a r g e s e p a r a t i o n and a small b u t e s s e n t i a l c o n t r i b u t i o n from p h o s p h o r u s d-orbitals. I n t h e a r e a o f t h e o r y and p h y s i c a l methods t h e r e h a s b e e n a s u g g e s t i o n t h a t five-membered r i n g s may p s e u d o r o t a t e v i a t o p s t r u c t u r e s p o s s e s s i n g a d i r a d i c a l five-membered
ring.
The i n t r o d -
u c t i o n o f o r t h o and p a r a s u b s t i t u e n t s t o a l l t h e p h e n y l r i n g s o f triphenylphosphine dramatically increases t h e b a s i c i t y , t h e r e s u l t i n g compounds b e i n g more b a s i c t h a n p i p e r i d i n e . F i n a l l y , I am v e r y p l e a s e d t o r e p o r t t h a t Dr. John Hobbs h a s a g r e e d t o become j o i n t S e n i o r R e p o r t e r from Volume 1 9 onwards.
B. J
.
Walker
Contents CHAPTER 1
Phosphines and Phosphonium Salts
D.M.
By
1
Allen
1
Phosphines
I. 1
1.1.1
From H a l o g e n o p h o s p h i n e s a n d O r g a n o metallic Reagents From M e t a l l a t e d P h o s p h i n e s By A d d i t i o n o f P - H t o U n s a t u r a t e d Compounds By R e d u c t i o n Miscellaneous Methods
1.1.2 1.1.3 1.1.4 1.1.5 1.2
3
Nucleophilic Attack a t Carbon Nucleophilic Attack a t Halogen N u c l e o p h i l i c A t t a c k a t O t h e r Atoms Miscellaneous Reactions
6 8 8
11 11 13 14
Halogenophosphines
17
2.1 2.2
17 19
Preparation Reactions
Phosphonium S a l t s
22
3.1 3.2
22
Preparation Reactions
4
p
5
Phosphirenes,
-Bonded
24
P h o s p h o r u s Compounds Phospholes,
and Phosphorins
References
CHAPTER 2
1 3
11
Reactions 1.2.1 1.2.2 1.2.3 1.2.4
2
1
Preparation
27 38
41
Pentaco-ordinated and Hexaco-ordinated Compounds By C.D.
Hall
1
Introduction
52
2
Structure,
52
3
Acyclic P h o s p h o r a n e s
55
4
Ring Containing Phosphoranes
58
4.1 4.2
58 65
5
Bonding and Ligand Reorganization
Monocyclic B i c y c l i c and T r i c y c l i c
Hexaco-ordinated References
P h o s p h o r u s Compounds
77
81
OrganophosphorusChemistry
viii CHAPTER 3
Phosphine Oxides and Related Compounds By B . J .
Walker
1
Introduction
83
2
P r e p a r a t i o n of Acyclic Phosphine Oxides
83
3
P r e p a r a t i o n of C y c l i c P h o s p h i n e O x i d e s
83
4
S t r u c t u r e and P h y s i c a l Aspects
85
5
Reactions a t Phosphorus
88
6
Reactions a t t h e Side-chain
90
7
Phosphine Oxide Complexes and E x t r a c t a n t s
99
References
CHAPTER 4
102
Tervalent Phosphorus Acids By 0 . Dahl
1
Introduction
104
2
Nucleophilic Reactions
104
2.1 2.2 2.3
104 107 107
3
A t t a c k on S a t u r a t e d Carbon Attack on Unsaturated Carbon Attack on Nitrogen, Chalcogen, o r Halogen
Electrophilic Reactions
110
3.1 3.2 3.3 3.4
110 116 119 126
Preparation Mechanistic Studies Use f o r N u c l e o t i d e S y n t h e s i s Miscellaneous
Reactions i n v o l v i n g Two-co-ordinate
5
Miscellaneous Reactions
129
References
129
CHAPTER 5
Quinquevalent Phosphorus Acids By R . S .
1
Edmundson
Phosphoric Acids and t h e i r D e r i v a t i v e s
134
1.1
134 135
1.2
2
Phosphorus
126
4
Synthesis Reactions and P r o p e r t i e s
P h o s p h o n i c a n d P h o s p h i n i c A c i d s a n d t h e i r D e r i v a t i v e s 151 2.1 2.2
Synthesis Reactions and P r o p e r t i e s
References
151 167 182
ix
Contents CHAPTER 6
Nucleotides and Nucleic Acids B y J.B.
Hobbs
1
Intrcauction
187
2
Mononucleotides
187
2.1 2.2
187 201
Chemical Synthesis Cyclic Nucleotides
3
Nucleoside
4
Oligo-
4.1 4.2 5
6
CHAPTER 7
Polyphosphates
and Poly-nucleotides
Chemical Synthesis Enzymatic Synthesis
203 216 216 238
Other Studies
245
5.1 5.2 5.3 5.4 5.5
245 248 254 263 278
Affinity Separation Affinity Labelling Post-synthetic Modification Sequencing and Cleavage Studies Metal C o m p l e x e s
A n a l y t i c a l Techniques and P h y s i c a l Methods
280
References
285
Ylides and Related Compounds B y B.J.
Walker
298
1
Introduction
2
Methylenephosphoranes
298
2.1 2.2
298
PreparatZon Reactions
2.2.1 2.2.2 2.2.3
and Structure
Alaehydes Ketones Miscellaneous Reactions
302
30 2 309 312
3
R e a c t i o n s of P h o s p h o n a t e A n i o n s
322
4
Selected Applications i n Synthesis
331
4.1 4.2 4.3 4.4 4.5 4.6
331 334 338 34 1 345 345
C a r o t e n o i d s , R e t i n o i d s a n d R e l a t e d Compounds a-Lactams L e u k o t r i e n e s a n d R e l a t e d Compounds M a c r o l i d e s a n d R e l a t e d Compounds Pheromones Miscellaneous Reactions
References
CHAPTER 8
356
Phosphazenes By C.W.
Allen
1
Introduction
364
2
Acyclic Phosphazenes
364
Organophosphorus Chemistry
X
3
Cyclophosphazenes
371
4 5
Cyclophospha(thia)zenes Miscellaneous Phosphazene-containing Ring Systems
377 378
6 7
Poly(ph0sphazenes)
380
Molecular Structures of Phosphazenes
385
References
387
CHAPTER 9
Physical Methods By J.C.
l'ebby
1
Theoretical Studies
394
2
Nuclear Magnetic Resonance Spectroscopy 2.1 Biological and Analytical Applications
397 397
2.2.1
2.5.1 J(PP) 2.5.2 J(P0) and J(PN) 2.5.3 J(PC) 2.5.4 J(PH) 2.6 Anisotropy, Magnetisation Transfer, Relaxation and CIDNP 2.7 Nuclear Quadrupole Resonance Electron Spin Resonance Vibrational Spectroscopy
40 1 402 402 402
4.1 4.2 4.3
405 405
2.5
4
5
Assignments Bonding Stereochemistry
Electronic Spectroscopy 5.1 5.2 5.3 5.4
6
397 397 397 398 399 399 399
2.3 2.4
3
Phosphorus-31
6 p of n1 and n2 compounds d p of n3 compounds 6p of n4 compounds 6p of n5 and n6 compounds 2.2.2 Carbon-13 Shift Reagents and Liquid Crystals Valence Isomerism, Restricted Rotation and Permutational Isomerism Spin-Spin Couplings
Absorption Spectroscopy Fluorescence Circular Dichroism Photoelectron and X-ray Spectroscopy
401 401
403 403 405 405
406 406 406 407 407 407
Diffraction
409
6.1
X-ray Diffraction
409
6.1.1
409 409 409 412 412
6.2
n 2 Compounds 6.1.2 n3 Compounds 6.1.3 n4 Compounds 6.1.4 n5 Compounds Electron Diffraction
xi
Contents 7
D i p o l e M o m e n t s , Kerr E f f e c t s , P o l a r o g r a p h y and Conductance
412
7.1 7.2
412 412
D i p o l e M o m e n t s a n d Kerr E f f e c t Polarography and Conductance
8
Mass S p e c t r o s c o p y
413
9
A c i d i t i e s , B a s i c i t i e s and Thermochemistry
413
10
11
Chromatography
415
10.1 10.2 10.3
415 416
Gas L i q u i d c h r o m a t o g r a p h y Thin Layer Chromatography Liquid Chromatography
416
Kinetics
416
References
417
AUTHOR INDEX
425
Abbreviations * AIBN CIDNP CNDO CP DAD DBN DBU DCC DIOP DMF DMSO DMTr EDTA E.H.T. ENU FID g.1.c.-m.s HMPT h.p.1.c. i.r. L.F.E.R. MIND0 MMT r MO MS-C1 MS-nt MS-tet WBS n.q.r. p.e. PPA SCF TBDMS TDAP TFAA Tf 20 THF Thf ThP TIPS t.1.c. TPS-C 1 TPS-nt TPS-te t TsOH U.V.
bisazoisobutyronitrile Chemically Induced Dynamic Nuclear Polarization Complete Neglect of Differential Overlap cyclopentadienyl diethy: azodicarboxylate 1,5-diazabicycl0[4.3.C]non-5-ene 1,5-diazabicyclo[ 5 . 4 .O jundec-5-ene dicyclohexylcarbodi-imide
[(L,?-dimethyl-1,3-dioxolan-4,5-diyl)bis-(methylene)] bisidiphenylphosphine) dimethylformamide dimethyl sulphoxide 4,4‘-dimethoxytrityl e t h y l e n e d i a m i n e t e t r a - a c e t i c acid Extended HKckel Treatment N-ethyl-N-nitrosourea Free Induction Decay gas-liquid chromatography-mass spectrometry hexamethylphosphortriamide
high-performance liquid chromatography infrared Linear Free-Energy Relationship Modified Intermediate Neglect of Differential Overlap 4-monomethoxytrityl Molecular Orbital mesitylenesulphonly chloride mesitylenesulphonly-3-nitro-l,2,4-triazole mesitylenesulphonyltetrazole
A!-bromosuccinimide nuclear quadrupole resonance photoelectron polyphosphoric acid Self-consistent Field t-butyldimethylsilyl tris(diethy1amino)phosphine
trifluoroacetic acid t r i f l u o r e m e t h a n e s u l p h o n i c anhydride
tetrahydrofuran 2-tetrahydrofuranyl 2-tetrahydropyranyl tetraisopropyldisiloxanyl
thin-layer chromatography chloride tri-isopropylbenzenesulphonyl-3-nitro-l,Z,4-triazole tri-isopropylbenzenesulphonyl
tri-isopropylbenzenesulphonyltetrazole
toluene-p-sulphonic acid ultraviolet
“Abbreviations used in Chapter 6 are detailed in Biochem. J.,1970,120,449 and 1978,171,i
Phosphines and Phosphonium Salts BY D. W. ALLEN
1 Phosohines
1.1 P r e p a r a t i o n
1.1.1 From Halogenophosphines and O r g a n o m e t a l l i c R e a g e n t s . g r e a t l y improved r o u t e t o t r i s - t - b u t y l p h o s p h i n e
A
i s a f f o r d e d by
t h e a d d i t i o n of a benzene s o l u t i o n of p h o s p h o r u s t r i c h l o r i d e t o a pentane s o l u t i o n of t - b u t y l l i t h i u m .
D i r e c t m e t a l l a t i o n of
benzenechromiumtricarbonyl w i t h b u t y l l i t h i u m a t - 3 O o C , f o l l o w e d by t r e a t m e n t w i t h c h l o r o d i p h e n y l p h o s p h i n e , p r o v i d e s a more d i r e c t r o u t e t o d i p h e n y l b e n c h r o t e n y l p h o s p h i n e ( 1). 2 The r e a c t i o n s o f p e n t a d i e n y l l i t h i u m w i t h h a l o g e n o p h o s p h i n e s have g i v e n a s e r i e s of pentadienylphosphines, e.g.
(2),
i s o l a t e d as t h e corresponding
o x i d e s a f t e r t r e a t m e n t w i t h hydrogen p e r o x i d e . 3
L i t h i a t i o n of
o-bromophenyldimethylarsine w i t h b u t y l l i t h i u m , f o l l o w e d by t r e a t m e n t w i t h p h o s p h o r u s t r i c h l o r i d e , g i v e s t h e new p o l y d e n t a t e l i g a n d ( 3 ) , b u t i n o n l y 15% y i e l d . 4
The r e a c t i o n of t h e
a - d i a z o m e t h y l l i t h i u m r e a g e n t ( 4 ) w i t h chlorodi(isopropy1amino)p h o s p h i n e l e a d s t o t h e f i r s t a - d i a z o m e t h y l p h o s p h i n e , ( 5 1 , which is s t a b l e t o d i s t i l l a t i o n . P h o t o l y s i s of ( 5 ) g e n e r a t e s t h e p h o s p h i n o c a r b e n e ( 6 1 , which is found t o b e more s t a b l e t h a n might have b e e n e x p e c t e d , b e h a v i n g e i t h e r a s a p h o s p h o r u s v i n y l y l i d e o r a s a X 5 - p h o s p h a - a c e t y l e n e . ' 6 The h e t e r o c y c l i c s y s t e m s ( 7 a r e formed i n t h e r e a c t i o n s o f t r i p h e n y l s i l y l l i t h i u m w i t h t h e corresponding h e t e r o c y c l i c c h l o r o p h o s p h i n e s .
7
C o n v e n t i o n a l a r y l G r i g n a r d p r o c e d u r e s have b e e n u s e d i n t h e s y n t h e s i s of t h e new p h o s p h i n e s ( 8 ) , 8
(9)
9
and
The
r e a c t i o n s of chlorodiphenylphosphine with Grignard r e a g e n t s d e r i v e d from c h l o r o m e t h y l s i l a n e s have g i v e n a r a n g e of p h o s p h i n e s b e a r i n g a s i l i c o n - c o n t a i n i n g s u b s t i t u e n t o r back-bone, ( l l ) . l l The t r i d e n t a t e p h o s p h i n e l i g a n d ( 1 2 ; R =
e .g. Me) i s formed o n
t r e a t m e n t of t h e p r e c u r s o r h a l o g e n o p h o s p h i n e ( 1 2 ; R = C l ) w i t h a n e x c e s s o f methylmagnesium c h l o r i d e . l 2 The r e a c t i o n s of t h e u n s a t u r a t e d dichloro(amino)phosphine
(13) with a range of a l k y l
G r i g n a r d r e a g e n t s g i v e r i s e t o a m i x t u r e of t h e r e a r r a n g e d 1
2
OrganophosphorusChemistry
Me3Si-C-Li
(Pr'2N12P-C
II
II
-Si Me,
(Pri2Nl2P-t-SiMe3
N2
N2
(4)
(7) R'=BuS, But, PhCH2 or Ph 2 R = H or Me n = O or 1
( 5 )
(6)
( 8 )
(9)
,CH,PR, RP
Ph,PC H2Si Me,CH=C H
But
MeCH=CHN
0
'
PCL,
(13)
Me ' c R2P0
=N Bu+
HcH
\
CH2PR2
Me >C=CHNHR R2P
1: Phosphines and Phosphonium Salts phosphines 1.1.2
(
14) and
(
3
1 5 ) . l3
P r e p a r a t i o n o f P h o s p h i n e s from M e t a l l a t e d P h o s p h i n e s . -
It
h a s b e e n shown t h a t p h o s p h i d e a n i o n s may be g e n e r a t e d from p r i m a r y and s e c o n d a r y p h o s p h i n e s u n d e r a q u e o u s c o n d i t i o n s u s i n g concent r a t e d a q u e o u s a l k a l i i n DMSO o r o t h e r d i p o l a r a p r o t i c s o l v e n t s . A l k y l a t i o n o f t h e r e s u l t i n g a n i o n s h a s g i v e n a r a n g e of s e c o n d a r y 14
and t e r t i a r y p h o s p h i n e s .
The g e n e r a t i o n of t h e b i s m e t a l l o p h o s p h i d e r e a g e n t s ( 1 6 1 by l i t h i u m - i n d u c e d c l e a v a g e of p h e n y l g r o u p s from a,w-bis(dipheny1phosphino)alkanes i s g r e a t l y f a c i l i t a t e d by i r r a d i a t i o n w i t h u l t r a s o u n d . l 5 The d i r e c t i o n of t h e l i t h i u m i n d u c e d c l e a v a g e of t h e h e t e r o c y c l i c d i p h o s p h i n e ( 1 7 ) d e p e n d s on t h e n a t u r e of t h e non-phosphorus s u b s t i t u e n t s . When R = P h , P-P t c l e a v a g e t a k e s p l a c e , w h e r e a s when R = Bu , c l e a v a g e o f a n exoc y c l i c p h e n y l g r o u p o c c u r s , r e s u l t i n g i n t h e f o r m a t i o n of t h e c y c l i c a n i o n ( 1 8 ) , which u n d e r g o e s t h e e x p e c t e d p r o t o n a t i o n a n d a l k y l a t i o n r e a c t i o n s a t p h o s p h o r u s on s u b s e q u e n t t r e a t m e n t w i t h e l e c t r o p h i l i c r e a g e n t s . l 6 T r e a t m e n t of 2 , 4 - b i s ( c h l o r o m e t h y l ) pyrazolium s a l t s with l i t h i u m diphenylphosphide a f f o r d s t h e p y r a z o l y l d i p h o s p h i n e ( 1 9 ) , which i s f o u n d t o b e v e r y e a s i l y o x i d i s e d by a i r a n d i s t h e r e f o r e s t o r e d i n t h e form of a n i c k e l complex from which it c a n b e f r e e d by c y a n i d e i o n . " The r e a c t i o n of t h e d i l i t h i o d i p h o s p h i d e ( 2 0 ) w i t h w h i t e p h o s p h o r u s g e n e r a t e s t h e l i t h i o p h o s p h i d e (21) d e r i v e d from t h e 2,3-dihydro-lHb e n z o t r i p h o s p h o l e s y s t e m . l8
The [ 2 + 1 1 c y c l o c o n d e n s a t i o n o f 1,2-dichloropropane with d i l i t h i u m t-butylphosphide y i e l d s t h e 19 s u r p r i s i n g l y s t a b l e p h o s p h i r a n e ( 2 2 1. Baudler's group h as co n ti n u ed t o i n v e s t i g a t e t h e u s e s o f i n o r g a n i c p o l y p h o s p h i d e s , e . g . L i 3 P 7 and L i 2 P 1 6 , i n t h e s y n t h e s i s 20,21
of p o l y c y c l i c o r g a n o p h o s p h i n e s o f e v e r - i n c r e a s i n g c o m p l e x i t y .
I n r e l a t e d work, t h e f i r s t bicyclo[3,2,0]heptaphosphine, P7But5, ( 2 3 ) , h a s been i s o l a t e d from t h e r e a c t i o n of b u t y l d i chlorophosphine , phosphorus t r i c h l o r i d e
, and
magnesium. 2 2
The
r e a c t i o n s of various l i t h i u m phosphides with dichlorodiorganos i l a n e s have g i v e n a r a n g e of c y c l i c s i l y l p h o s p h i n e s . 23-26 four-membered
The
r i n g s y s t e m ( 2 4 ) , i s o l a t e d i n 76% y i e l d i n t h e
r e a c t i o n of m o n o l i t h i u m p h o s p h i d e w i t h di-t-butyldichlorosilane, h a s been u s e d f o r t h e s y n t h e s i s of o t h e r , more complex, s i l y l phosphines bearing t h i s s t r u c t u r a l u n i t , e.g.
(25).
24
23
4
Organophosphorus Chemistry
RT_1R PhPLi(CH&,PLi (16) n = 2
Ph
-6
PhP(17 1
PPh
Bu*
But
I 7
PhP-P-
R = But or Ph
(18)
Ph
CH2PPh, W
Ph2PCH20N
P P Li
H
Ph (21 1
(201
(19 1
But
But
I P - - P- P But I .I ButP 'p' P - P But
(23)
(22)
Ph,P
Ph,P
I
Me,N -CH
I
n NH NH
W
(27)
fH=c
n
HN
2c
CHzSMe (28)
(241
(26)
(25)
CH,PPh,
But,Si-PH I I HP-si e u t 2
(29)
Nup (30)
5
I : Phosphines and Phosphonium Salts Sodium a n d p o t a s s i u m o r g a n o p h o s p h i d e r e a g e n t s c o n t i n u e t o b e employed i n t h e s y n t h e s i s of new p h o s p h i n e s .
The t e t r a d e n t a t e
s y s t e m ( 2 6 ) i s formed i n t h e r e a c t i o n s of sodium d i o r g a n o p h o s p h i d e A series r e a g e n t s w i t h N , N ’ -bis(2-chloroethyl)ethylenediamine.27 o f phosphino-functionalised m a c r o c y c l i c s y s t e m s , e . g . ( 2 7 1 , h a s b e e n p r e p a r e d by t h e r e a c t i o n s o f t h e r e l a t e d 2 - c h l o r o e t h y l a m i n o d e r i v a t i v e s w i t h p o t a s s i u m d i p h e n y l p h o s p h i d e . 2 8 The r e a c t i o n between p o t a s s i u m d i p h e n y l p h o s p h i d e and c h l o r o f o r m h a s been explored as a p o s s i b l e r o u t e t o tris(diphenylphosphino)methane, but without success. isolated in
ca
However, bis(dipheny1phosphino)methane
is
40% y i e l d from t h e above r e a c t i o n c o n d u c t e d i n
l i q u i d ammonia.2g
New c h i r a l p h o s p h i n e s , e . g .
( 2 8 1 , d e r i v e d from
L - c y s t e i n e , L-methionine,
and D-penicillamine,
have been p r e p a r e d
by t h e m e s y l a t e - p o t a s s i u m
o r g a n o p h o s p h i d e r o u t e . 30
The r e a c t i o n
of monopotassium p h o s p h i d e w i t h allyl(2-chloroethy1)amine
gives
t h e p r i m a r y p h o s p h i n e ( 2 9 ) which, on t r e a t m e n t w i t h formaldehyde i n e t h a n o l , is c o n verted i n t o t h e b i c y c l i c system ( 3 0 ) .
Curiously,
w h i l e t h i s compound reacts n o r m a l l y w i t h s u l p h u r t o p r o d u c e t h e
r e l a t e d p h o s p h i n e s u l p h i d e , t h e r e a c t i o n w i t h iodomethane r e s u l t s i n q u a t e r n i z a t i o n a t n i t r o g e n . 31
Baudler’ s group h a s r e p o r t e d a
number of s t u d i e s o f t h e c l e a v a g e r e a c t i o n s undergone by t h r e e membered p h o s p h o r u s h e t e r o c y c l e s on t r e a t m e n t w i t h p o t a s s i u m , and o f t h e s y n t h e t i c u t i l i t y of t h e r e s u l t i n g p h o s p h i d e a n i o n s . e.g.,
the cyclotriphosphine (31; X
=
Thus,
But) undergoes cleavage t o
form t h e p h o s p h i d e ( 3 1 ; X = K ) , 3 2 h y d r o l y s i s o f which y i e l d s t ( 3 1 ; X = HI which i s t h e r m a l l y s t a b l e , 3 3 u n l i k e ( 3 1 ; X = Bu 1. The r e a c t i o n of ( 3 1 ; X = K ) w i t h c h l o r o t r i m e t h y l s t a n n a n e y i e l d s t h e s t a n n y l p h o s p h i n e ( 3 1 ; X = SnMe,), which on s u b s e q u e n t t r e a t ment w i t h dichloro(methyl)phosphine, is c o n v e r t e d i n t o t h e
bis(cyc1otriphosphino)phosphine ( 3 2 ) . 34 I n r e l a t e d work, i t h a s been shown t h a t p o t a s s i u m - i n d u c e d c l e a v a g e o f ( 3 3 ; X = BNPri, 01” CMe,) p r o c e e d s w i t h r i n g - o p e n i n g c l e a v a g e of t h e phosphorusp h o s p h o r u s bond, w h e r e a s t h e c o r r e s p o n d i n g r e a c t i o n of ( 3 3 ; X = NPrl) proceeds w i t h c l e a v a g e of t h e phosphorus-nitrogen bond.35y36 I n t e r e s t c o n t i n u e s i n t h e a p p l i c a t i o n of r e a g e n t s d e r i v e d from p h o s p h i n e s by l i t h i a t i o n a t c a r b o n of one of t h e p h o s p h o r u s substituents.
The p r o p y n y l p h o s p h i n e ( 3 4 ) is m e t a l l a t e d o n t r e a t -
ment w i t h b u t y l l i t h i u m t o g i v e ( 3 5 ) , which g i v e s r i s e t o t h e t e t r a p h o s p h a a l l e n e ( 3 6 ) on s u b s e q u e n t r e a c t i o n w i t h c h l o r o d i p h e n y l p h o s p h i n e . 37
The B-hydroxyethylphosphines
(37
and ( 3 8 ) are
OrganophosphorusChemistry
6
formed i n t h e r e a c t i o n s o f lithiomethyldiphenylphosphine w i t h hexaf l u o r o a ~ e t o n eand ~ ~ di-t-butylketone
39 r e s p e c t i v e l y
.
T r e a t m e n t of t h e d i a l k y l a m i n o p h o s p h i n e s ( 3 9 ) w i t h b u t y l l i t h i u m and N,N'-tetramethylethylenediamine r e s u l t s i n predominant l i t h i a t i o n at carbon;
however, d i r e c t d i s p l a c e m e n t o f a d i m e t h y l -
amino g r o u p from p h o s p h o r u s is a c o m p e t i n g p r o c e s s . 4 0
Further
examples have been g i v e n of t h e p r e p a r a t i o n of p h o s p h i n o m e t h y l d e r i v a t i v e s o f metals
e . g. t i t a n i u m , 4 1 z i r c o n i u m , 4 1 , 4 2 h a f n i u m , 42
and a l u m i n i u m , 4 3 from t h e r e a c t i o n s o f l i t h i o m e t h y l d i o r g a n o p h o s p h i n e s w i t h a p p r o p r i a t e metal h a l i d e s .
The r e a g e n t l i t h i u m
trisCdimethy1phosphino)methanide h a s been found t o b e v e r y u s e f u l for t h e p r e p a r a t i o n o f c o o r d i n a t i o n complexes of t h e main g r o u p e l e m e n t s , e . g . aluminium44 a n d t i n , 4 5 i n which a l l l i g a t e d atoms are p h o s p h o r u s . M e t a l l a t i o n r e a c t i o n s a t c a r b o n of c o o r d i n a t e d p h o s p h i n e s have been r e v i e w e d .
46
1 . 1 . 3 P r e p a r a t i o n o f P h o s p h i n e s by Addit i o n of P-H t o U n s a t u r a t e d Compounds.-
The a d d i t i o n r e a c t i o n s of P-H compounds t o C=O a n d
C=N s y s t e m s have been r e v i e w e d . 4 7
A modified procedure f o r t h e
b a s e - c a t a l y s e d a d d i t i o n of d i p h e n y l p h o s p h i n e t o a c r y l o n i t r i l e h a s b e e n d e v e l o p e d , and s u b s e q u e n t l y u s e d i n t h e s y n t h e s i s o f
.
2 - ~ y a n o p r o p y l d i p h e n y l p h o s p h i n e , (40 ) 48
The a d d i t i o n o f
b i s ( p h o s p h i n 0 ) m e t h a n e t o d i e t h y l ( v i n y 1 ) p h o s p h i n e y i e l d s t h e new l i g a n d (41), c a p a b l e of b r i d g i n g t w o m e t a l c e n t r e s . 4 9 A study of t h e r a d i c a l - i n i t i a t e d a d d i t i o n of s e c o n d a r y p h o s p h i n e s t o a series o f d i ( a l l y 1 ) o r g a n o p h o s p h i Q e s h a s r e v e a l e d t h a t t h e r e a c t i o n is i n h i b i t e d by t h e p r e s e n c e o f b u l k y s u b s t i t u e n t s i n t h e s e c o n d a r y phosphine. I n c o n t r a s t , dimethylphosphine r e a d i l y a d d s t o t h e t e r m i n a l d o u b l e bonds o f w - a l k e n y l p h o s p h i n e s t o form new p o l y d e n t a t e p h o s p h i n e s , e . g . ( 4 2 ) . 5 0 A series o f n o v e l 1,4-diphosphac y c l o h e x a n e s e . g . ( 4 3 ) , i n which t h e bonds from p h o s p h o r u s t o t h e e x o c y c l i c s u b s t i t u e n t s a r e o f o p p o s i t e p o l a r i t y , is a c c e s s i b l e from t h e r a d i c a l - i n i t i a t e d a d d i t i o n o f t r i m e t h y l s i l y l p h o s p h i n e t o d i e t hy l a m i n o d i ( viny1)phosphine. 51
Formation of a h e t e r o c y c l i c
p h o s p h i n e is a l s o o b s e r v e d i n t h e a d d i t i o n of p h e n y l p h o s p h i n e t o t h e amino-enone
(441, which r e s u l t s i n t h e b i c y c l i c s y s t e m (45),
together with other products.
52
7
I : Phosphines and Phosphonium Salts
(32I
(311
(331
Ph,P Ph2PC=CMe
n Bu Li
---+
Ph2PCH C ( C F3l2 0 H
(37)
(
Ph2PCH2CH(MelCN
(401
(43l
e3
)But2
38 I
[(Et2PCH,CH,)2P],CH2 (41 1
n
pw ps
Ph,PCH,C(OH
\
/c=c=c \
Ph2P
(351
(34)
Et2
P h 2 P C G CCH,Li
Ph2PCI
PPh,
ZCH2P( NMe,),
(39)Z=Ph or Me3Si
P[(CH,),PMe2]3
(421
8
Organophosphorus Chemistry 1.1.4 P r e p a r a t i o n of P h o s p h i n e s by R e d u c t i o n . -
A procedure f o r
t h e r e d u c t i o n of p h o s p h i n e o x i d e s u s i n g t r i c h l o r o s i l a n e i n i n e r t
h a l o g e n a t e d hydrocarbon s o l v e n t s h a s been d e s c r i b e d i n a p a t e n t . 5 3
T r i c h l o r o s i l a n e h a s a l s o been u s e d for t h e s t e r e o s p e c i f i c r e d u c t i o n of a series of p r e v i o u s l y r e s o l v e d c h i r a l phosphine o x i d e s t o y i e l d b o t h (R) and ( S )
forms of t h e c h i r a l b i n a p h t h y l
d i p h o s p h i n e s ( 4 6 ) , 5 4 and a l s o i n t h e f i n a l s t e p o f t h e s y n t h e s i s o f t h e p h o s p h a j u l o l i d i n e s y s t e m ( 4 7 ) by r e d u c t i o n of t h e corresponding phosphine oxide.
An _X-ray s t u d y o f ( 4 7 ) h a s shown t h a t
t h e geometry a t p h o s p h o r u s i s p y r a m i d a l , i n s p i t e o f t h e c o n s t r a i n t s imposed by t h e r i n g s y s t e m . 5 5
P r o c e d u r e s for t h e
r e d u c t i o n o f phosphine oxides u s i n g combinations o f a t r i a l k y l aluminium a n d a b o r o n t r i h a l i d e o r e s t e r a t 200-400" d e v e l o p e d . 56 ' 5 7
have b e e n
Combination of l i t h i u m aluminium h y d r i d e w i t h
c e r i u m ( I I 1 ) c h l o r i d e g i v e s a r e a g e n t which r e d u c e s p h o s p h i n e o x i d e s i n good y i e l d u n d e r m i l d c o n d i t i o n s , b u t which i s u n f o r t u n a t e l y n o t s t e r e o s p e c i f i c . 58
I n c o r p o r a t i o n o f sodium
b o r o h y d r i d e i n t o t h e above s y s t e m r e s u l t s i n t h e i s o l a t i o n o f phosphine-borane
a d d u c t s ( 4 8 ) which are u s e f u l r e a g e n t s f o r t h e
s y n t h e s i s o f new p h o s p h i n e s .
Thus, e . g . ,
metallation of t h e
adduct (49) with sec-butyllithium r e s u l t s i n t h e lithiomethyl d e r i v a t i v e (50), which, on t r e a t m e n t w i t h c o p p e r ( I1 ) c h l o r i d e , g i v e s t h e d i p h o s p h i n o e t h a n e d e r i v a t i v e (51). The b o r a n e p r o t e c t i n g 59
g r o u p i s e a s i l y removed o n t r e a t m e n t w i t h d i e t h y l a m i n e . Reduction of phosphine o x i d e s under mild conditions is also a f f o r d e d by sodium aluminium h y d r i d e i n c o m b i n a t i o n w i t h aluminium c h l o r i d e o r a mixed sodium-aluminium c h l o r i d e r e a g e n t . 6 0 9 6 1 L i t h i u m aluminium h y d r i d e h a s been u s e d t o c l e a v e a f u r f u r y l g r o u p from a r a n g e o f f u r f u r y l p h o s p h o n i u m s a l t s , which are e a s i l y a c c e s s i b l e by t h e r e a c t i o n s o f trimethylsilylphosphines w i t h f u r f u r y l bromide.
Thus, e . g . ,
t h e r e a c t i o n of d i p h e n y l t r i m e t h y l -
s i l y l p h o s p h i n e y i e l d s t h e s a l t (52) which, o n t r e a t m e n t w i t h l i t h i u m aluminium h y d r i d e , is c o n v e r t e d i n t o t h e p h o s p h i n e ( 5 3 ) .
62
L i t h i u m aluminium h y d r i d e h a s a l s o been u s e d f o r t h e p r e p a r a t i o n o f p r i m a r y and s e c o n d a r y p h o s p h i n e s which b e a r b u l k y d i a l k y l a m i n o 63,64 s u b s t i t u e n t s , e.g. (54). 1 . 1 . 5 M i s c e l l a n e o u s Methods o f P r e p a r i n g P h o s p h i n e s . -
Methods f o r
t h e p r e p a r a t i o n o f c h i r a l p h o s p h i n e s have been r e v i e w e d . 6 5
A new
r o u t e t o c h i r a l p h o s p h i n e s i s a f f o r d e d by t h e r e a c t i o n s o f b u l k y o r g a n o l i t h i u m r e a g e n t s w i t h o p t i c a l l y a c t i v e menthyl o r b o r n y l
esters ( 5 5 ) o f phenylphosphonous a c i d which p r o c e e d w i t h a h i g h
I: Phosphines and Phosphonium Salts
(46)A r = P h , p-tolyl
9
(471
(48)
or p - 6 d ~ ~ t - 1 ~
Ph,PCH,
i
%
Ph,PCH,Li
Ph2PCH2CH2PPh2
I
BH,
BH3
Ph,PCH (52)
2o
R’*N P H R ~ 1
(53)
c
BH3
(54)R.H, Pr’
, But
or
Me3S i 2 R = H IBut, or NPrZi
,OR’ PhP
/
PhP
‘OR’
\
R2
O*O
OR’
H--)L~H Ph2P
1
( 5 5 ) R = bornyl or menthyl
( 56
1
PPh2
(57)
Organophosphorus Chemistry
10
degree of asymmetric induction to give differing amounts of the diastereoisomeric phosphinous acid esters (56). Subsequent reactions of these with a second organolithium reagent yield chiral phosphines 66 Chiral polymer -bound phosphines based on the well-established DIOP system have been prepared by copolymerisation of the chiral, unsaturated phosphine (571, which is accessible from DIOP by acid-catalysed ring-opening of the ketal unit, followed by formation of the acetal with 2-vinylbenzaldehyde.67 The reaction of white phosphorus with a mixture of 2,4,6tri(t-buty1)bromobenzene and 2,4,6-tri-(t-butyl)phenyllithium leads to the predominant formation of the bicyclotetraphosphine Three diastereoisomeric forms of the macrocyclic ( 5 8 ) .68 tetraphosphine (59) have been isolated in the fprm of palladium complexes from the palladium(I1) template-assisted cyclocondensation of 1,2-bis(methylphosphino)ethane with 1,2-bis(ch10romethyl)benzene.~~ A range of new hybrid P,N-donor ligands, e.g. (601, has been prepared utilising conventional functional group transformations of 2-aminophenyldiphenylphosphine (and its oxide), 2-diphenylphosphinobenzaldehyde, and 2-diphenylphosphinobenzoic acid.70 The reactions of the mixture of isomeric secondary phosphines formed on addition of phosphine to 1,5-cyclooctadiene with alkyl halides, followed by treatment of the intermediate phosphonium salts with sodium hydride, lead to new bicyclic terxiary phosphines, e.g. (61). The corresponding reactions with perfluoroalkyl halides lead to mixtures of isomeric PP-diphosphines and not to the expected p e r f l u o r o a l k y l p h o s p h i n e s . 71 Various 72 routes to 1,3,2,4-diazaphosphaboretidines (62) have been studied. Haloacylphosphines, e.g. (63), have been prepared by the reactions of trimethylsilylphosphines with haloacyl halides. In general, these compounds are found to be thermally unstable, but can be 73-75 studied in the form of the related transition metal complexes. Studies of the effect of various catalysts on the formation of tris(hydroxymethy1)phosphine from formaldehyde and phosphine have been reported.76 ’77 The reaction between dimethylaluminium hydride and methylphenylphosphine leads to the elimination of hydrogen with the formation of the aluminophosphine Me,AlPMePh, 78 which is reported t o exist as a trimer in benzene solution.
.
1: Phosphines and Phosphonium Salts
11
1 . 2 R e a c t i o n s of P h o s p h i n e s
1 . 2 . 1 N u c l e o p h i l i c A t t a c k a t C a r b o n . - The r e a c t i o n s o f s i l y l a m i n o p h o s p h i n e s w i t h c a r b o n d i s u l p h i d e r e s u l t i n t h e f o r m a t i o n of t h e b e t a i n e s ( 6 4 ) , no c l e a v a g e o f , o r i n s e r t i o n i n t o , P-N o r Si-N b o n d s b e i n g ~ b s e r v e d . ~ ’The s t a b i l i s e d y l i d e ( 6 5 ) i s f o r m e d i n t h e r e a c t i o n of t r i b u t y l p h o s p h i n e w i t h c a r b o n d i s e l e n i d e .
80
F u r t h e r e x a m p l e s o f e n a n t i o s e l e c t i v e n u c l e o p h i l i c a d d i t i o n of p h o s p h i n e s t o c o o r d i n a t e d d i e n e s h a v e b e e n d e s c r i b e d . 81
Treat-
ment o f t h e 1:l a d d u c t of t r i b u t y l p h o s p h i n e w i t h e t h o x y a c e t y l e n e w i t h a s e c o n d mole o f t h e a c e t y l e n e g i v e s a 1 : 2 a d d u c t of u n c e r t a i n s t r u c t u r e , which, on r e a c t i o n w i t h bromoethane, i s 82 c o n v e r t e d i n t o t h e phosphonium s a l t ( 6 6 ) . 1.2.2 N u c l e o p h i l i c Attack a t Halogen.-
F u r t h e r a p p l i c a t i o n s of
t e r t i a r y phosphine-tetrahalogenomethane have been d e s c r i b e d .
and r e l a t e d “ r e a g e n t s ”
The r e a c t i o n s o f p r i m a r y a n d s e c o n d a r y
a l c o h o l s w i t h p o t a s s i u m c a r b o x y l a t e s i n t h e p r e s e n c e of t h e
triphenylphosphine-tetrachloromethane r e a g e n t l e a d t o t h e f o r m a t i o n of e s t e r s i n good y i e l d . However, a p p l i c a t i o n of t h i s p r o c e d u r e t o t h e e s t e r i f i c a t i o n of ( - ) - 2 - o c t a n o l w i t h p o t a s s i u m b e n z o a t e w a s f o u n d t o p r o c e e d w i t h b o t h i n v e r s i o n and r a c e m i s a t i o n a t t h e c h i r a l c a r b o n atoms.83 formed
via
I t h a s now b e e n shown t h a t 6-hydroxyamides
t h e c o n d e n s a t i o n o f c a r b o x y l i c a c i d s and a m i n o a l c o h o l s ,
i n t h e p r e s e n c e of triphenylphosphine-tetrachloromethane,undergo c y c l i s a t i o n t o o x a z o l i n e s w i t h complete i n v e r s i o n o f t h e c a r b i n o l centre.84 The y l i d e (6’7) i s r e p o r t e d t o be f o r m e d i n the r e a c t i o n cf p-nitrophenylsulphenamide
with t h e triphenylphosphine-
t e t r a c h l o r o m e t h a n e c o m b i n a t i o n . 85
Polymer-bound d i h a l o m e t h y l e n e y l i d e s a r e formed i n t h e r e a c t i o n s o f polymer-bound t r i a r y l -
p h o s p h i n e s w i t h t e t r a h a l o g e n o m e t h a n e s . 86 Polymer-bound p h o s p h i n e h a l o g e n r e a g e n t s h a v e b e e n shown t o b e c o n v e n i e n t r e a g e n t s f o r t h e c o n v e r s i o n of e p o x i d e s t o h a l o h y d r i n s u n d e r m i l d a n d n o n - a c i d i c c o n d i t i o n s , t h e procedure r e q u i r i n g only a f i l t r a t i o n and e v a p o r a t i o n s t a g e f o r p r o d u c t i s o l a t i o n . 87
The t r i b u t y l p h o s p h i n e t e t r a c h l o r o m e t h a n e c o m b i n a t i o n h a s b e e n shown t o p r o m o t e t h e
c o n v e r s i o n of (€I)-(+)-a-phenylneopentyl
a l c o h o l i n t o ( S ) - ( ->-a-
p h e n y l n e o p e n t y l c h l o r i d e w i t h t h e greatest d e g r e e of stereos p e c i f i c i t y y e t r e c o r d e d . 88
Dichlorophosphoranes are formed i n
t h e r e a c t i o n s of t e r t i a r y p h o s p h i n e s w i t h n i t r o g e n t r i c h l o r i d e . 89 The r e a c t i o n o f t r i p h e n y l p h o s p h i n e w i t h t h e g e m i n a l d i c h l o r o
Cl) i n t h e p r e s e n c e o f water l e a d s t o t h e f o r m a t i o n o f ( 6 8 ; R = H). However, i n t h e a b s e n c e o f water, t h e
compound ( 6 8 ; R
=
Organophosphorus Chemistry
12
(59)
(60)
RpG R’N-BR,
I
I
CCI,COPR,
MeP-NR’
(61)
( 6 2 1 R’= Me or But 2 R = F,CI, Br,Me,
(63 1 R = C6H,,
E t or Ph Me
OE t
I+ Me3SiNR P - CS, I
+I 6u3PC=CH-C =C H E t
I
OEt
Me
( 6 4 ) R = Me3Si or Me
(651
Br-
(661
(69 1
(67)
+ R3P-
BH,CN
(70)
Ph,PC H,PP h,
4
BH3
(71)
-
I
I : Phosphines and Phosphoniurn Salts
13
a l k e n e ( 6 9 ) i s formed, p o s s i b l y i m p l y i n g t h e involvement of a carbene intermediate.
90
1 . 2 . 3 N u c l e o p h i l i c A t t a c k a t O t h e r Atoms.-
The r e a c t i o n o f t e r t i a r y
p h o s p h i n e s w i t h sodium b o r o h y d r i d e and i o d i n e i n THF p r o v i d e s a new r o u t e t o p h o s p h i n e - b o r a n e a d d u c t s . 91
The cyanoborane a d d u c t s ( 7 0 ) are s i m i l a r l y formed i n t h e r e l a t e d r e a c t i o n s w i t h sodium
.
cyanoborohydride 92
The react i o n of b i s ( d i p h e n y l p h o s p h i n o )methane
w i t h sodium b o r o h y d r i d e and i o d i n e p r o v i d e s t h e monoborane a d d u c t
( 7 1 ) , whereas t h e corresponding r e a c t i o n with iodoborane r e s u l t s i n t h e formation of t h e c y c l i c salt ( 7 2 ; g
salts (72;
J-I
= 2-4)
=
l ) . 9 3 The r e l a t e d
have been p r e p a r e d by t h e r e a c t i o n s o f
a ,w-bis ( d i p h e n y l p h o s p h i n o ) a l k a n e s w i t h t h e dimet h y l s u l p h i d e - b o r a n e
a d d u c t i n t h e p r e s e n c e of i o d i n e .
94
Diethoxytriphenylphosphorane ( t h e p r o d u c t o f i n s e r t i o n o f triphenylphosphine i n t o diethyl peroxide) f i n d s use as a mild, n e u t r a l r e a g e n t which i n i t i a t e s c y c l o d e h y d r a t i o n o f N- and Cs u b s t i t u t e d 6 - a m i n o a l c o h o l s t o form a z i r i d i n e s i n e x c e l l e n t y i e l d , w i t h t h e e x p e c t e d c o m p l e t e r e t e n t i o n o f c o n f i g u r a t i o n a t t h e amino carbon. 95
The r e l a t e d phosphorane d e r i v e d f rom a polymer-bound
t r i a r y l p h o s p h i n e a c t s a s an e f f i c i e n t c y c l o d e h y d r a t i o n r e a g e n t 96 f o r t h e c y c l i s a t i o n of s i m p l e a , L O - d i o l s t o c y c l i c e t h e r s . Second o r d e r k i n e t i c s have been o b s e r v e d f o r oxygen t r a n s f e r from a r s e n i c t o p h o s p h o r u s i n t h e r e a c t i o n between t r i p h e n y l a r s i n e o x i d e and t r i p h e n y l p h o s p h i n e i n t h e m o l t e n s t a t e . 9 7
A second
o r d e r r a t e l a w h a s a l s o been o b s e r v e d i n t h e o x i d a t i o n of t r i p h e n y l p h o s p h i n e ( a n d a l s o t r i p h e n y l a r s i n e and t r i p h e n y l s t i b i n e ) by p o t a s s i u m p e r o x o d i p h o s p h a t e , and a mechanism i n v o l v i n g n u c l e o p h i l i c a t t a c k a t oxygen s u g g e ~ t e d . ’ ~A d e t a i l e d s t u d y of t h e
r a t e s o f r e a c t i o n o f t r i a r y l p h o s p h i n e s (and o t h e r t r i v a l e n t p h o s p h o r u s compounds) w i t h e l e m e n t a l s u l p h u r i n t o l u e n e i s c o n s i s t e n t w i t h b i p h i l i c i n s e r t i o n i n t o t h e sulphur-sulphur bond, i n v o l v i n g a p o l a r t r a n s i t i o n s t a t e i n which p h o s p h o r u s a c q u i r e s a p a r t i a l p o s i t i v e c h a r g e . 99
Tris(dimethy1amino)phosphine h a s been
u s e d f o r t h e c o n v e r s i o n o f d i s u l p h i d e s t o t h i o e t h e r s . l o o The r e a c t i o n s of t r i s - ( t - b u t y 1 ) p h o s p h i n e
w i t h e l e m e n t a l s e l e n i u m and
t e l l u r i u m have g i v e n t h e r e s p e c t i v e s e l e n i d e and t e l l u r i d e , t h e
l a t t e r undergoing r a p i d t e l l u r i u m t r a n s f e r t o o t h e r phosphide A l k y l t e l l u r o p h o s p h i n o u s esters have been
m o l e c u l e s i n s o l u t i o n . lo’
p r e p a r e d by t h e exchange r e a c t i o n s o f t e t r a - a l k y l d i p h o s p h i n e s and 102 dialkylditellurides.
14
Organophosphorus Chemistry N u c l e o p h i l i c a t t a c k a t n i t r o g e n a p p e a r s t o be i n v o l v e d i n t h e 103
r e a c t i o n s of t r i p h e n y l p h o s p h i n e w i t h b i c y c l i c t h i a z y l s y s t e m s . F u r t h e r examples of t h e f o r m a t i o n o f X'-phosphazenes
in the
r e a c t i o n s o f p h o s p h i n e s w i t h a z i d o compounds have b e e n described.1049105
The r e a c t i o n s of a z i d e s w i t h one mole e q u i -
v a l e n t of t r i p h e n y l p h o s p h i n e , i n
t h e presence of a s l i g h t excess
Of
w a t e r , i n THF r e s u l t i n t h e c h e m o s e l e c t i v e f o r m a t i o n o f p r i m a r y amines. lo6 A g e n e r a l r o u t e t o f i v e - ,
six-,
and seven-membered
c y c l i c i m i n e s i s o f f e r e d by t h e r e a c t i o n s i n a n h y d r o u s media of t r i p h e n y l p h o s p h i n e w i t h w - a z i d o k e t o n e s . l o 7 The t r i p h e n y l p h o s p h i n e d i e t h y l a z o d i c a r b o x y l a t e s y s t e m h a s now been u s e d t o p r e p a r e a c i d a n h y d r i d e s from c a r b o x y l i c a c i d s . l o * Under h i g h - d i l u t i o n c o n d i t i o n s , s i x - and seven-membered c y c l i c d i o x y t r i p h e n y l p h o s p h o r a n e s are formed i n t h e r e a c t i o n s of p r o p a n e - 1 , 3 - d i o l butane-1,4-diol, di-isopropyl
and
r e s p e c t i v e l y , w i t h t r i p h e n y l p h o s p h i n e and
azodicarboxylate.
A t higher concentrations, t h e s e 109
phosphoranes appear t o oligomerise.
1 . 2 . 4 M i s c e l l a n e o u s R e a c t i o n s of P h o s p h i n e s . -
The r o l e o f c h i r a l
p h o s p h i n e s a s l i g a n d s i n t h e c a t a l y s i s of r e a c t i o n s l e a d i n g t o t h e f o r m a t i o n o f c h i r a l p r o d u c t s h a s b e e n r e v i e w e d . 'lo A p r o c e d u r e f o r t h e d e t e r m i n a t i o n of t h e e n a n t i o m e r i c e x c e s s i n c h i r a l p h o s p h i n e s h a s been d e v e l o p e d , b a s e d on '!C n.m.r. s t u d i e s of t h e d i a s t e r e o i s o m e r i c complexes formed by p h o s p h i n e s w i t h t h e c h i r a l p i n e n y l n i c k e l bromide complex. '11 Studies of t h e sulphonation o f t r i p h e n y l p h o s p h i n e and o f c h i r a l a r y l p h o s p h i n e s have been r e p o r t e d i n a t t e m p t s t o p r e p a r e water s o l u b l e l i g a n d s which a i d p r o d u c t i s o l a t i o n and c a t a l y s t - r e c o v e r y from homogeneouslyc a t a l y s e d r e a c t i o n s . '12-'14 t h e p r o m o t i o n of Michael-type
F u r t h e r examples have a p p e a r e d o f a d d i t i o n s t o t h e d o u b l e bond o f
1,l-bis(dipheny1phosphino)ethene
a s a r e s u l t of c o o r d i n a t i o n of
t h e p h o s p h o r u s atoms t o t r a n s i t i o n metal a c c e p t o r s . 115-117 E v i d e n c e of phosphorus-carbon
c l e a v a g e r e a c t i o n s undergone by
t e r t i a r y p h o s p h i n e s a s components o f homogenous c a t a l y s t s y s t e m s c o n t i n u e s t o accumulate.
In hydroformylation systems involving
c o b a l t - p h o s p h i n e complexes, it h a s been shown t h a t e l e c t r o n w i t h d r a w i n g a r y l g r o u p s enhance t h e r a t e o f p h o s p h i n e d e g r a d a t i o n , 118,119 whereas electron-donating s u b s t i t u e n t s reduce t h e rate. Phenyl-phosphorus c l e a v a g e h a s a l s o been o b s e r v e d i n a dimolybdenum-triphenylphosphine complex, 120 and c l e a v a g e of t h e p h o s p h o r u s - c a r b o n backbone of diphosphinomethane-di-iron complexes h a s b e e n r e p o r t e d . 12' ,122 An u n p r e c e d e n t e d c l e a v a g e of a m e t h y l
I : Phosphines and Phosphonium Salts
15
group from p h o s p h o r u s o c c u r s i n t h e r e a c t i o n of a d i m e t h y l -
(pheny1)phosphine-tantalum(II1) b a s e s . 123
bromide complex w i t h s t r o n g
C o n s t a n t c u r r e n t e l e c t r o l y s i s of t r i p h e n y l p h o s p h i n e i n d i c h l o r o m e t h a n e i n t h e p r e s e n c e of amides and N , N ' - d i s u b s t i t u t e d u r e a s l e a d s t o t h e f o r m a t i o n o f n i t r i l e s and c a r b o d i m i d e s ,
.
r e s p e c t i v e l y 124 A triphenylphosphine-dibutylt i n d i c h l o r i d e complex h a s found u s e a s a c a t a l y s t f o r t h e r e g i o s e l e c t i v e r i n g o p e n i n g o f o x i r a n e s . 125
P h e n y l p h o s p h i n e h a s been found t o r e d u c e
a r o m a t i c k e t o n e s t o t h e c o r r e s p o n d i n g d i a r y l m e t h a n e s . 12'
The
r e a c t i o n of 2 - q u i n o n e monoimides w i t h t r i p h e n y l p h o s p h i n e g i v e s 127 r i s e t o benzoxazoles. Valence i s o m e r i s m of t h e 7,8-bis(phosphino)cycloocta-l,3,5t r i e n e s (73) h a s been s t u d i e d i n a r a n g e of compounds, and t h e p r o d u c t s a r i s i n g from c o n r o t a t o r y (74) and d i s r o t a t o r y (75) r i n g o p e n i n g i d e n t i f i e d . 12'
Both +-and
t r a n s - i s o m e r s of t h e
p h o s p h i r a n e s (76) u n d e r g o t h e r m a l r e a r r a n g e m e n t a t 150' t h e p h o s p h o l e n e (77 1. 12'
t o form
The r e a c t i o n s of a l k y l b i s ( t r i m e t h y 1 -
sily1)phosphines with phenylisocyanate give rise t o t h e adducts
(78) which on t r e a t m e n t w i t h sodium h y d r i d e form hexamethyld i s i l o x a n e and o l i g o m e r i c ( p h e n y l i m i n o ) m e t h y l i d i n e p h o s p h i n e s .
130
The m e t a l l o p h o s p h i n e s (79) r e a c t n o r m a l l y w i t h s u l p h u r , b u t on treatment with
iodomethane o r f l u o r o t r i c h l o r o m e t h a n e undergo c l e a v a g e o f t h e metal-phosphorus bond. 3 1 The i m i n o b i s ( p h o s p h i n e s ) ( 8 0 ) undergo a l k y l a t i o n a t p h o s p h o r u s t o form t h e phosphoranimine-
phosphonium s a l t s (811, t h e r e b y p r o v i d i n g t h e f i r s t examples of p r o t o t r o p i s m i n t h i s c l a s s of compound which are i n d u c e d by P - a l k y l a t i o n . 132
T r e a t m e n t of t h e s u l p h u r d i i m i d e s y s t e m (82)
w i t h p o t a s s a m i d e g e n e r a t e s t h e s a l t (83) which, w i t h d i - t - b u t y l ( c h l o r o ) a r s i n e , g i v e s t h e p h o s p h i n o - a r s i n e s y s t e m (84). 133
The
r e a c t i o n of t r i m e t h y l p h o s p h i n e w i t h p e r f l u o r o p r o p e n e g i v e s t h e phosphorane (85) i n h i g h y i e l d , w h e r e a s t h e c o r r e s p o n d i n g 134 r e a c t i o n o f d i m e t h y l p h o s p h i n e g i v e s t h e p h o s p h i n e (86 1. T e t r a m e t h y l d i p h o s p h i n e and t e t r a m e t h y l d i a r s i n e u n d e r g o r a p i d exchange r e a c t i o n s i n s o l u t i o n i n benzene a t 25OC t o g i v e a n e q u i l i b r i u m m i x t u r e which c o n t a i n s t h e p h o s p h i n o a r s i n e (87).
In
c o n t r a s t , no e v i d e n c e of exchange r e a c t i o n s between t e t r a m e t h y l d i p h o s p h i n e and t h e r e l a t e d d i s t i b i n e s o r d i b i s m u t h i n e s h a s been
.
o b t a i n e d 135
P r e v i o u s l y unknown d i p h o s p h i n e c a t i o n r a d i c a l s have
been o b s e r v e d by e . s . r . t e c h n i q u e s on e l e c t r o c h e m i c a l o x i d a t i o n 136 of a series of s t e r i c a l l y crowded t e t r a a r y l d i p h o s p h i n e s .
OrganophosphorusChemistry
16
(73)
Me Si
/-
3
-7 7 P
A But
B Ut
(76 1
(77)
Ph2PR2P-M(CO),
(
N
H
- PR1
80) R 1 =Butor Ph
\
;
,SiMe3
N-C-P\
Ph’
R
( 7 8 ) R = PhCH, or E t
+
Ph2P=N-PRiR2 H ( 81 1 R1=But or Ph
2
( 7 9 ) M=Cr,Mo or W R=CF3 or CN
R = M e or Ph,C
N A N
I
I
But2P
PBu‘,
(82)
Me3P(F)CF=CFCF3
(85)
(83)
=C FCF3
Me2PCF
(86)
Me2P-AsMe2
(87)
PF;
17
I : Phosphines and Phosphonium Salts The e f f e c t s o f g a m m a - i r r a d i a t i o n o n 1,2-bis(diphenylphosphino)e t h a n e have been studied.137
The a c t i o n o f d r y a i r o n p o l y c y c l i c
o r g a n o p o l y p h o s p h i n e s h a s g i v e n t h e f i r s t monoxides o f t h e s e s y s t e m s a s t h e i n i t i a l p r o d u c t s . 13'
Studies of t h e r e a c t i o n s of
t r i f l u o r o m e t h y l p h o s p h i n e s w i t h v a r i o u s n i t r o s o compounds h a v e b e e n 139,140 reported
.
2 H a l o g en o p h o s p h i n es 2.1 Preparation. -
P a t e n t s h a v e a p p e a r e d which claim improved
p r o c e d u r e s f o r t h e s y n t h e s i s of a r y l d i c h l o r o p h o s p h i n e s and d i a r y l c h l o r o p h o s p h i n e s from a r o m a t i c hydrocarbons, phosphorus t r i c h l o r i d e , and a l u m i n i u m c h l o r i d e , t h e i n t e r m e d i a t e c o m p l e x e s b e i n g decomposed by tris(2-chloroethyl)phosphite1*1f 142 o r
bis(2-chloroethyl)vinylphosphonate. 143 High t e m p e r a t u r e e x c h a n g e r e a c t i o n s between t r i o c t y l p h o s p h i n e a n d p h o s p h o r u s t r i b r o m i d e h a v e y i e l d e d o c t y l d i b r o m o p h o s p h i ne a n d d i o c t ylbromop h o s p h i n e
.144
P h e n y l p h o s p h o n i c d i c h l o r i d e i s r e d u c e d by t r i o c t y l p h o s p h i n e a t 50-100°C t o g i v e p h e n y l d i c h l o r o p h o s p h i n e a n d t r i o c t y l p h o s p h i n e o x i d e i n good y i e l d . 145
The d i b e n z o x a s i l i n ( 8 8 ; X = H) is
c o n v e r t e d i n t o t h e c o r r e s p o n d i n g d i c h l o r o p h o s p h i n e ( 8 8 ; X = PC1,) on h e a t i n g w i t h p h o s p h o r u s t r i c h l o r i d e a n d a l u m i n i u m c h l o r i d e a t 65-75OC. 14'
B o t h ( 8 9 ) and ( 9 0 ) are f o r m e d i n t h e r e a c t i o n s of
2,6-di-t-butylphenol
with phosphorus t r i h a l i d e s , t h e latter
.
p r o d u c t p r e d o m i n a t i n g 14'
The s u b s t i t u t e d - v i n y l d i h a l o g e n o -
p h o s p h i n e s ( 9 1 ) are formed i n t h e r e a c t i o n s o f s u b s t i t u t e d - v i n y l e t h e r s w i t h p h o s p h o r u s t r i h a l i d e s i n t h e p r e s e n c e of triethylamine. 14' 14'
The r e a c t i o n o f b e n z a l d i m i n e s w i t h p h o s p h o r u s
t r i c h l o r i d e i n a c e t o n e , i n t h e p r e s e n c e of p y r i d i n e , is c l a i m e d t o proceed with s u b s t i t u t i o n at t h e S c h i f f ' s base carbon t o give t h e d i c h l o r o p h o s p h i n e s ( 9 2 1. 150 P h o t o l y s i s of d i m e t h y l d i a c e t y l e n e i n t h e presence o f phosphorus tribromide y i e l d s t h e u n s a t u r a t e d 151
dibromophosphine ( 9 3 ) .
The p r e p a r a t i o n o f i n t e r m e d i a t e d i a l k y l a m i n o p h o s p h i n e s from t h e c o n t r o l l e d react i o n s of dialkylaminochlorophosphines w i t h o r g a n o m e t a l l i c r e a g e n t s , and t h e subsequent r e a c t i o n of t h e s e i n t e r m e d i a t e s w i t h h y d r o g e n c h l o r i d e , c o n t i n u e s t o b e u s e d as a r o u t e t o less a c c e s s i b l e h a l o g e n o p h o s p h i n e s .
Among compounds
r e c e n t l y p r e p a r e d b y t h i s r o u t e are ( 9 4 ) 1 5 2 a n d ( 9 5 ) . 153 o f new silylaminohalogenophosphines, e . g .
A series
(96), h a s b e e n p r e p a r e d
b y t h e r e a c t i o n s o f bis(trimethylsily1)methyldichlorophosphine w i t h v a r i o u s l i t h i u m s i l y l a m i d e s . 154
The r e a c t i o n of
Organophosphorus Chemistry
18
0-SiCl,
&=J
H:bPX2
X
(88)
X, PC(R' I =c HOR
But (89)X:Cl or Br
C12PC( Ph )=NC,H,R
(90) X = C l or Br
Me(Br)C=C-CC=CMe
I
PBr,
(91) R'= a l k y l or Br 2
( 9 2 ) R = H,Cl or NO2
(93)
R = M e , E t or Bu X = C I or B r
L
(97)
(95)
(96 1
(98) R = B u t or M e s
(99)
X' X2PC(C F3),OS iM e3
(100)
(101 X ' = C I or 6 r 2
X = H or halogen
X P"Jf \
f
(1021X=CI or 6 r
Z=0,S ,NMe or NPX2
I: Phosphines and Phosphonium Salts
19
1,2 - b i s ( p h o s p h i n o ) b e n z e n e w i t h s i x moles o f p h o s g e n e i n d i c h l o r o m e t h a n e s o l u t i o n a t -78OC r e s u l t s i n t h e f o r m a t i o n o f t h e r e l a t e d b i s ( d i c h 1 o r o ) p h o s p h i n e ( 9 7 ) i n 45-55% y i e l d .
Using bulky Grignard o r o r g a n o z i n c r e a g e n t s , t h i s may be p a r t i a l l y s u b s t i t u t e d t o g i v e
( 9 8 1 , which may t h e n b e s u b j e c t e d t o f u r t h e r a l k y l a t i o n r e a c t i o n s . 155 A s i m i l a r s e q u e n t i a l s u b s t i t u t i o n a p p r o a c h h a s b e e n employed i n t h e s y n t h e s i s o f v a r i o u s o p t i c a l l y a c t i v e m e n t h y l 156 halogenop hosph i n e s
.
The r e a c t i o n s of t r i m e t h y l s i l y l h a l i d e s w i t h t r i s ( d i m e t h y l a m i n 0 ) p h o s p h i n e o f f e r a c o n v e n i e n t r o u t e t o bis(dimethy1amino)halogenop h o s p h i n e s . 157
S t e r i c a l l y crowded h a l o g e n o p h o s p h i n e s , e . g .
(99),
h a v e b e e n p r e p a r e d by t h e r e a c t i o n s o f tris(trimethylsily1)silylc h l o r i d e w i t h dialkylarninodichlorophosphines d e r i v e d from bulky s e c o n d a r y a m i n e s . 15'
Treatment of t h e primary phosphine ( 100)
( e a s i l y a c c e s s i b l e from t h e r e a c t i o n of phosphine w i t h hexafluoro-
a c e t o n e , f o l l o w e d by 0 - s i l y l a t i o n ) w i t h N-chlorosuccinimide y i e l d s t h e halogenophosphines
o r N-bromo-
( 1 0 1 ) , which c a n b e
c o n v e r t e d t o t h e c o r r e s p o n d i n g f l u o r o p h o s p h i n e s o n react i o n w i t h a n t i m o n y t r i f l u o r i d e . 15'
V a r i o u s compounds o f t h e g e n e r a l t y p e
( 1 0 2 ) have been p r e p a r e d by t h e r e a c t i o n s o f 2 - d i f u n c t i o n a l
aromatic compounds w i t h p h o s p h o r u s t r i h a l i d e s . 160-164
A mixture
o f (difluoromethy1)iodophosphines i s f o r m e d i n t h e s e a l e d - t u b e r e a c t i o n o f w h i t e p h o s p h o r u s w i t h d i f l u o r o i o d o m e t h a n e a t 190OC.
165
The r e a c t i o n s o f w h i t e p h o s p h o r u s w i t h t e t r a a l k y l a m m o n i u m c y a n i d e s i n t h e p r e s e n c e of a crown e t h e r i n a c e t o n i t r i l e g i v e r i s e t o t h e d i c y a n o p h o s p h i d e i o n , w h i c h is f o u n d t o react w i t h a v a r i e t y of
a n i o n i c phosphorus n u c l e o p h i l e s w i t h displacement of cyanide i o n
t o g e n e r a t e new P-P b o n d e d compounds. 166 2.2 R e a c t i o n s o f Ha1ogenophosphines.-
'
The t r i c y c l i c s y s t e m ( 1 0 3 )
h a s b e e n p r e p a r e d f r o m p h e n y l d i c h l o r o p h o s p h i n e b y t h e McCormack react i o n . 16' The b i c y c l i c s y s t e m ( 1 0 4 ) i s f o r m e d i n t h e r e a c t i o n of a 1,6-diene
or -diketone w i t h methyldichlorophosphine i n t h e a c e t i c a c i d , f o l l o w e d by t r e a t m e n t w i t h water. The presence of b r i d g e d d i c h l o r o t e t r a p h o s p h i n e ( 1 0 5 ) h a s b e e n o b t a i n e d by t h e 170 c a t h o d i c r e d u c t i o n of 1,2-bis(dichlorophosphino)benzene (97). T r e a t m e n t of b u t y l b i s ( t r i m e t h y l s t a n n y l ) amine w i t h p h o s p h o r u s t r i c h l o r i d e l e a d s t o t h e f o r m a t i o n of t h e c h l o r o p h o s p h i n e ( 1 0 6 ) w h i c h decomposes r a p i d l y a t room t e m p e r a t u r e t o g i v e t h e zwitterionic system (107). 1 7 1 N o t s u r p r i s i n g l y , t h e v a s t m a j o r i t y o f r e a c t i o n s of h a l o g e n o phosphines reported over t h e past year involve nucleophilic a t t a c k
Organophosphorus Chemistry
20
a t p h o s p h o r u s w i t h d i s p l a c e m e n t of h a l i d e i o n .
The c h l o r o -
p h o s p h i n e ( 1 0 8 1 , formed i n t h e r e a c t i o n of a p e n t a m e t h y l c y c l o p e n t a d i e n y l i r o n d i c a r b o n y l a n i o n w i t h t -but y l d i c h l o r o p h o s p h i n e n o r m a l l y i n s u b s e q u e n t react i o n s a t p h o s p h o r u s . 172
, behaves
A s t u d y of t h e
r e a c t i o n s o f h a l o g e n o p h o s p h i n e s d e r i v e d from t h e anti-7-phosphanorbornene system (109) w i t h Grignard r e a g e n t s has proved t o be s u r p r i s i n g l y complex.
The d e s i r e d d i s p l a c e m e n t o f c h l o r i n e w i t h
r e t e n t i o n o f c o n f i g u r a t i o n w a s o b s e r v e d i n o n l y one case, t h e g e n e r a l s i t u a t i o n b e i n g c o m p l i c a t e d by l o s s of t h e b r i d g i n g g r o u p a n d h a l o g e n exchange w i t h t h e G r i g n a r d r e a g e n t . 173
A r a n g e o f new ( 1 1 0 ) 1 7 4 h a s been p r e p a r e d by t h e 174-176 r e a c t i o n s o f NH compounds w i t h c h l o r o d i p h e n y l p h o s p h i n e .
c h i r a l aminophosphines e . g .
V a r i o u s p h o s p h i n a t e d c l a y s have been p r e p a r e d by t h e r e a c t i o n s o f chlorodiphenylphosphine with c l a y s under b a s i c c o n d i t i o n s .
Such
m a t e r i a l s have p o t e n t i a l a s l i g a n d s for t h e p r e p a r a t i o n of n o v e l h e t e r o g e n e o u s c a t a l y s t s y s t e m s . 177 The f i r s t d i t e l l u r o p h o s p h i n e ( 1 l l ) h a s been p r e p a r e d b y t h e a c t i o n o f t h e t r i s ( t r i m e t h y l s i l y 1 ) d i t e l l u r i d e a n i o n on di-t-butylchlorophosphine. 178 The r e a c t i o n s of t h e bis(ch1orophosphino)methanes ( 1 1 2 ) w i t h p r i m a r y amines h a v e y i e l d e d t h e bis(aminophosphino)methanes ( 1 1 3 ) , which on t r e a t m e n t w i t h an amine h y d r o c h l o r i d e undergo c y c l i s a t i o n t o form t h e 1,2,4-azadiphosphetidines (114). 17' The e a s i l y a c c e s s i b l e and c r y s t a l l i n e bis(diisopropy1amino)chlorophosphine h a s found u s e i n n u c l e o t i d e s y n t h e s i s . 180 H y d r o l y s i s of c h l o r o p h o s p h i n e s c o o r d i n a t e d t o p a l l a d i u m or p l a t i n u m h a s been s t u d i e d . 18' The r e a c t i o n s o f isobutenyldichlorophosphine w i t h n u c l e o p h i l e s h a v e b e e n e x p l o r e d . 182 Chlorophosphine-borane a d d u c t s u n d e r g o t h e u s u a l n u c l e o p h i l i c d i s p l a c e m e n t react i o n s a t p h o s p h o r u s w i t h o u t d i s r u p t i o n o f t h e phosphorus-boron l i n k . 183 The p h o s p h i n o p h o s p h a z e n e s ( 1 1 5 ) are t h e i n i t i a l p r o d u c t s i n t h e r e a c t i o n s o f N-metallated
aminophosphines w i t h chlorodialkylphosphines.
In the
p r e s e n c e o f v a r i o u s c a t a l y s t s , t h e s e compounds r e a r r a n g e t o form
bi~(dialky1phosphino)amines.~~ H~e t e r o c y c l i c s y s t e m s , e.g. ( 1 1 6 1 , are formed i n t h e r e a c t i o n s of bis(dich1orophosphino)methane w i t h 185,186 N,N' - d i s i l y l u r e a s . Treatment of dichlorophosphines w i t h s i l v e r t h i o c y a n a t e i n d i c h l o r o m e t h a n e s o l u t i o n l e a d s t o t h e f o r m a t i o n of t h e c o r r e s p o n d i n g di(isothiocyanato)phosphines, which are f o u n d t o be thermally unstable.
I socyanatodiorganophosphines u n d e r g o
c y c l i s a t i o n on t r e a t m e n t w i t h a l d e h y d e s t o form o x a z a p h o s p h o l i n e s , e.g. (11.7). 188
1: Phosphines and Phosphoniurn Salts
21
CI
Cl (1031
CIP+N<"
SnMe,
(104)
] 2
(106)
(105)
BUf +/N\-
p\ N But
"Me2C
( 1 07)
oCH=NCH(Me)Ph
( 108)
( Me3SiI3CTeTePBut2
Ph2P (109)
(
R~ PCI ),cH,
[( R2NH)R1P l,CH,
A PR'
R'P
'N' (112 I R'= Pri or O P ~ ;
R,P-
II
NR
2
(113) R = a l k y l
Ph
Me
Me
Ph
PR,
R2
(114)
22
Organophosphorus Chemistry 3 Phosphonium S a l t s
3.1 Preparation.Tetra-isopropylphosphonium s a l t s are d i f f i c u l t t o p r e p a r e by d i r e c t q u a t e r n i z a t i o n o f t r i - i s o p r o p y l p h o s p h i n e . However, a r o u t e t o t h e s e compounds is p r o v i d e d b y q u a t e r n i z a t i o n o f t h e p h o s p h i n e w i t h i o d o e t h a n e , f o l l o w e d by g e n e r a t i o n o f t h e
tri-isopropylethylidenephosphorane, which is t h e n a l k y l a t e d w i t h
.
C o n v e n t i o n a l q u a t e r n i z a t i o n p r o c e d u r e s have b e e n iodomet hane employed i n t h e s y n t h e s i s o f a r a n g e o f 2-acylethylphosphonium
s a l t s , 1'' dialkylaminomethylphosphonium s a l t s , 1 g 1 t h e d i p h o s p h o n i m s a l t ( 1 1 8 ) , l g 2polymer-bound s a l t s which f i n d a p p l i c a t i o n a s phase-
t r a n s f e r cat a1y s t s ,l g 3' l g 4a n d v a r i o u s b e n z y l i c phosphonium s a l t s ,l g 5 - l g 7 a l k a l i n e h y d r o l y s i s of which p r o v i d e s t h e c o r r e s ponding methylarene.
Thus, s e q u e n t i a l c h l o r o m e t h y l a t i o n ,
q u a t e r n i z a t i o n , and a l k a l i n e h y d r o l y s i s s t e p s p r o v i d e a r o u t e f o r 197 t h e i n t r o d u c t i o n of m e t h y l g r o u p s i n t o a r o m a t i c s y s t e m s . Q u a t e r n i z a t i o n of 1,1-bis(dipheny1phosphino)ethene
w i t h iodo-
methane g i v e s t h e b i s ( p h o s p h o n i u m s a l t ) (1191, which r e a d i l y u n d e r g o e s n u c l e o p h i l i c a d d i t i o n t o t h e d o u b l e bond t o form e . g . (120).
I n t h e same s t u d y , i t w a s a l s o shown t h a t t h e r e a c t i o n of
t h e y l i d e ( 1 2 1 ) w i t h c h l o r o d i p h e n y l p h o s p h i n e g i v e s t h e monophosphonium s a l t (1221, which o n t r e a t m e n t w i t h m e t h y l f l u o r o s u l p h o n a t e g i v e s t h e diphosphonium s a l t ( 1 2 3 ) . T h i s s a l t u n d e r g o e s r i n g - o p e n i n g o n t r e a t m e n t w i t h methano1,with c l e a v a g e o f o n e p h o s p h o r u s - c a r b o n bond t o g i v e a p h o s p h i n e o x i d e a n d a 3-met hoxypropylphosphonium s a l t . l g 8 The pyrrolylmethylphosphonium
s a l t s ( 1 2 4 ) are e a s i l y a c c e s s i b l e f r o m t h e r e a c t i o n s o f t r i p h e n y l p h o s p h i n e w i t h t h e a p p r o p r i a t e Mannich- b a s e m e t h i o d i d e s 99 Arylphosphonium s a l t s are formed i n t h e u n c a t a l y s e d r e a c t i o n s o f t r i p h e n y l p h o s p h i n e w i t h 2-bromophenyl k e t o n e s a t 28OOC. 2 0 0 , 2 0 1
!
Cyclisation of t h e y l i d e s (125) with a,B-unsaturated ketones l e a d s
t o a series of phosphonium b e t a i n e s , p r o t o n a t i o n of which g i v e s t h e arylphosphonium s a l t s ( 1 2 6 ) . 2 0 2
Alkylation of t h e s t a b i l i s e d
y l i d e (127) at sulphur has given t h e heteroarylphosphonium s a l t (128). 203
The s u b s t i t u t e d vinylphosphonium s a l t ( 1 2 9 ) is formed
i n t h e react i o n of carboxymet hylme t h y l e n e t r i p h e n y l p h o s p h o r a n e w i t h
a q u a t e r n a r y s a l t d e r i v e d from a ~ e t o n i t r i l e . ~ 'T~r e a t m e n t o f t h e y l i d e ( 1 3 0 ) w i t h p h e n y l s e l e n i u m bromide g i v e s t h e s a l t ( 1 3 1 ) which undergoes o x i d a t i v e d e s e l e n a t i o n t o form t h e cyclobutenylphosphonium s a l t ( 1 3 2 ) . 205
The r e a c t i o n o f isocyanomethyltrimethyl-
s i l a n e w i t h dichlorotriphenylphosphorane phine
(or w i t h triphenylphos-
i n t h e presence of hexach1oroethane)leads t o t h e s a l t (133),
1: Phosphines and Phosphoniurn Salts
23
+
4.
Ph2PMe +>CH2 Ph2PMe
pph32clSPh
Ph3P
(118 1
2X-
(119 1
Ph2PMe +/‘CHCH~OR Ph2PMe
( 1 2 0 ) R = M e or E t
+
ph3b c‘-
Ph,P
2x-
+
g3;-
p h 3 ; x
MePh2P
(122 1
( 123 1
OH + RoCH2bPh3
=C HC0CH
I-
Ph P
2 i D Br-
H (124) R = H or Ph3;CH2
I-
(127 1
2
(126)R’,R =aryl or heteroar yl
+
MPPh3
O+N Ph
ci04-
Ph3P-C=C
I
1
-
BFL
C0,Me ‘NHEt
(129)
Ph3fp---0 Ph3P
Me
+
(128
Ph3b-i=)
(130)
1
(125 1
PhC 0CH2 S
sY-4pPh3
R’
ClOi
24
Organophosphorus Chemistry
which i s a b l e t o c o o r d i n a t e t o metal a c c e p t o r s
a r a n g e o f c a t i o n i c complexes.
c a r b o n t o form
I n a l k a l i n e media, t h e s a l t is
r e a d i l y decomposed t o g i v e m e t h y l i s o c y a n i d e and t r i p h e n y l p h o s p h i n e o x i d e , w h e r e a s under a c i d i c c o n d i t i o n s i t forms t h e formamido 206 derivative (134). The t e l l u r o p h o s p h o n i u m s a l t s ( 1 3 5 ) are formed i n t h e r e a c t i o n s o f p h o s p h i n e t e l l u r i d e s w i t h iodomethane.
Aminop hosp hon ium s a l t s ( 1 3 6 ) have b e e n p r e p a r e d by t h e a c t i o n o f monochloramines w i t h t e r t i a r y p h o s p h i n e s 2 0 8 and tris(dialkylamino)phosphines.20g A v a r i e t y o f p r o d u c t s have been i s o l a t e d i n e a r l i e r s t u d i e s o f t h e p h o s p h o r u s trichloride-tris(dimethy1amino)phosphine-aluminium c h l o r i d e s y s t e m , and a r e i n v e s t i g a t i o n h a s now shown t h a t t h e n a t u r e o f t h e s e p r o d u c t s i s dependent on t h e s e q u e n c e i n which t h e r e a g e n t s are a l l o w e d t o react w i t h e a c h o t h e r . The most i n t e r e s t i n g new compounds o b t a i n e d from t h i s s y s t e m i n d i c h l o r o methane s o l u t i o n are t h e diphosphoniodiphosphirane s a l t ( 1 3 7 ) and t h e diphosphoniocyclotetraphosphine s a l t ( 1 3 8 ) . 210 The r e a c t i o n s o f a l k y l - o r aryl-diaminodifluorophosphoranes w i t h e i t h e r a n oxonium s a l t o r p h o s p h o r u s t r i c h l o r i d e h a v e r e s u l t e d i n f l u o r o phosphonium s a l t s e . g .
The u n u s u a l diphosphonium s y s t e m
( 1 3 9 ) . 211
( 1 4 0 ) , i n which two f o r m a l l y p o s i t i v e p h o s p h o r u s c e n t r e s are d i r e c t l y l i n k e d , h a s been p r e p a r e d . A structural study reveals t h a t t h e phosphorus-phosphorus bond l e n g t h i s n o t u n u s u a l , i m p l y i n g t h a t t h e r e is c o n s i d e r a b l e d e l o c a l i s a t i o n o f t h e p o s i t i v e c h a r g e s . 212
Phosphonium s a l t s h a v i n g a wide r a n g e o f u n u s u a l
c o u n t e r i o n s have been d e s c r i b e d , s y s t e m s , l3
i n c l u d i n g v a r i o u s TCNQ-derived , l 5 '6 [ Sb,Br 3 2-,2 l 7 and
l4 and t h e t r i b r o m i d e
d i c h r o m a t e 2 1 8 i o n s , some of which a r e o f v a l u e a s r e a g e n t s i n synthesis.
e . g.
V a r i o u s h e t e r o a r y l - s u b s t i t u t e d benzylphosphonium s a l t s ,
( 141) have been p r e p a r e d b y e l a b o r a t i o n of r e a c t i v e g r o u p s
present i n simpler functionalised salts. 3.2 R e a c t i o n s o f Phosphonium S a l t s . -
2 19
I n t e r e s t continues i n t h e
e f f e c t s o f s o l v e n t o n t h e r a t e of a l k a l i n e d e c o m p o s i t i o n o f phosphonium s a l t s .
I t h a s now been shown t h a t , i n t h e r e s p e c t i v e
r e a c t i o n s o f h y d r o x i d e i o n and methoxide i o n w i t h t e t r a p h e n y l phosphonium bromide i n m i x t u r e s o f DMSO and m e t h a n o l , t h e rates o f t h e r e a c t i o n s i n c r e a s e as t h e p r o p o r t i o n of t h e d i p o l a r a p r o t i c s o l v e n t i n c r e a s e s , t h e r e a c t i o n w i t h h y d r o x i d e i o n p r o c e e d i n g more r a p i d l y t h a n t h a t w i t h methoxide. 220
The same g r o u p h a s r e p o r t e d a
s t u d y o f t h e k i n e t i c s of a l k a l i n e h y d r o l y s i s of S-bromopropyltriphenylphosphonium bromide i n DMSO-water m i x t u r e s .
The r e a c t i o n
25
I: Phosphines and Phosphonium Salts
Ph36CH2N=C
CL-
P ~ ~ ~ H ~ N H CIC H O
(133 1
[ R3P-TeMeltI-
(135) R = a l k y l or NMe2
(134)
N
A
d 3 6 N R 2 R 3CI-
P, +dP - ‘\+ ( Me2NI3P
+ /p\ 2cL- (Me2Nl3P@P
P(NMe$3
(136) R’=alkyl or R,N R2, R3=H or Me
\P’
P‘kNY,,
;
2c1-
I
NMe, ( 1 38)
(1 37)
0
(139)
pXC6H$Ph),6CH=CH,
m
Br-
( 1 4 2 ) X = H,Me,or n ‘C1ZH25
Ph3&H2CsCCl-$6Ph3 2 1 -
(145)
(141 1
(140)
(143) R ’ = E t ,Pr or Bu
(144)
2
R = E t or Bu X = C L or Br
+
Ph3PCH=CCH2CH26Ph3 21-
I NR’R~
(146)
R’= H or Me 2
R = P h or PhCH2
+
+ Z
( 1 4 7 ) Z=OorNH
26
OrganophosphorusChemistry
f o l l o w s t h e u s u a l t h i r d o r d e r r a t e l a w , and p r o c e e d s a p p r o x i m a t e l y e i g h t y times f a s t e r t h a n t h e c o r r e s p o n d i n g r e a c t i o n of t e t r a p h e n y l phosphonium bromide. The a u t h o r s have a t t r i b u t e d t h e i n c r e a s e d r a t e of h y d r o l y s i s t o t h e presumed g r e a t e r e l e c t r o n - w i t h d r a w i n g c h a r a c t e r of t h e 3-bromopropyl group and t h e consequent g r e a t e r s t a b i l i t y of t h e r e l a t e d c a r b a n i o n compared t o p h e n y l . 221 The a l k a l i n e h y d r o l y s i s of benzyltriphenylphosphonium s a l t s h a s been shown t o be v e r y s t r o n g l y r e t a r d e d by i n c r e a s e i n p r e s s u r e , i n a c c o r d a n c e w i t h a two- or t h r e e - s t e p mechanism i n v o l v i n g f r a g m e n t a t i o n and d e s o l v a t i o n , e a c h of which c o n t r i b u t e s t o an i n c r e a s e i n volume. 222 The c o m p e t i t i v e base-promoted h y d r o l y s i s and h y d r a t i o n of t h e triaryl(viny1)phosphonium s a l t s ( 1 4 2 ) h a s been shown t o be markedly i n f l u e n c e d by t h e f o r m a t i o n of micelles by t h e s a l t h a v i n g a l o n g c h a i n a l k y l s u b s t i t u e n t i n one of t h e a r y l g r o u p s . The f o r m a t i o n o f c a t i o n i c m i c e l l e s l e a d s t o a l o c a l c o n c e n t r a t i o n of hydroxide i o n s and a f f o r d s a much g r e a t e r d e g r e e o f r e g i o s e l e c t i v i t y t h a n is o b s e r v e d for t h e r e a c t i o n s o f t h e nonm i c e l l e - f o r m i n g s a l t s . 2 2 3 Aqueous h y d r o l y s i s of t h e N-indolylphosphonium s a l t s (143) i s r e p o r t e d t o g i v e t h e phosphonic a c i d (144). 224
N u c l e o p h i l i c a d d i t i o n of p r i m a r y and s e c o n d a r y amines
t o t h e 1,4-diphosphonio-but-2-yne (145) l e a d s t o t h e s a l t s (1461, which, on s u b s e q u e n t t r e a t p e n t w i t h e i t h e r e t h y l e n e g l y c o l or e t h y l e n e d i a m i n e , a r e c o n v e r t e d t o t h e s a l t s ( 1 4 7 ) . 225 The l a t t e r s y s t e m (Z = NH) is a l s o formed i n t h e r e a c t i o n of t h e b u t a d i e n y l bisphosphonium s a l t ( 1 4 8 ) w i t h e t h y l e n e d i a m i n e . 226 A d d i t i o n o f r a d i c a l s t o t h e B-carbon o f triphenyl(viny1)phosphonium bromide g e n e r a t e s t h e r a d i c a l c a t i o n s ( 1 4 9 ) which can s u b s e q u e n t l y be t r a p p e d by t h i o p y r i d o n e s t o y i e l d t h e s a l t s ( 1 5 0 ) from which t h e t r i p h e n y l p h o s p h o n i o group i s r e a d i l y c l e a v e d by aqueous a l k a l i t o y i e l d v a r i o u s t h i o a l k y l p y r i d i n e s ?27 A number o f s t u d i e s o f t h e r m a l decomposition of phosphonium s a l t s have been r e p o r t e d . The hydrazonovinylphosphonium s a l t s (151) undergo t h e r m a l rearrangement t o form v i n y l - s u b s t i t u t e d p y r a z o l e s . 228 Substituted-methyl(tripheny1 )phosphonium s a l t s are formed on h e a t i n g t h e alkoxycarbonylmethyl(tripheny1)phosphonium s a l t s (152) i n DMF a t 100°C. 229 A r a n g e o f methyl(pheny1)phosphonium s a l t s ( 1 5 3 ) h a s been s u b j e c t e d t o e x a m i n a t i o n by p y r o l y s i s GC, l e a d i n g t o t h e f o r m a t i o n o f complex m i x t u r e s of p r o d u c t s which i n c l u d e p h o s p h i n e s , h a l o g e n o a r e n e s and b i a r y l s , 230,231 i m p l y i n g t h e involvement of f r e e r a d i c a l p r o c e s s e s . As-Phosphazenes are r e p o r t e d t o be formed i n t h e t h e r m a l
I: Phosphines and Phosphonium
27
Salts
d e c o m p o s i t i o n o f v a r i o u s aminophosphonium s a l t s . 2 3 2 9 2 3 3 Thiaphosphonium s a l t s are i n v o l v e d as i n t e r m e d i a t e s i n t h e development of t h e f i r s t g e n e r a l p r o c e d u r e f o r t h e s t e r e o s p e c i f i c removal of s u l p h u r from c h i r a l c e n t r e s . 234
F u r t h e r work h a s b e e n
r e p o r t e d o n t h e d e v e l o p m e n t o f 2-phosphonioalkoxycarbonyl p r o t e c t i n g groups f o r p e p t i d e s y n t h e s i s . 235
Micelle-forming
phosphonium s a l t s u r f a c t a n t s c a t a l y s e t h e h y d r o l y s i s o f b o t h c a r b o x y l i c a n d p h o s p h a t e e s t e r s . 2 3 6 ' 2 3 7 The a r o y l t h i o r n e t h y l phosphonium s a l t s ( 1 5 4 1 , a c c e s s i b l e by t h e r e a c t i o n s o f t h i o c a r b o x y l a t e s w i t h bromomethyltriphenylphosphoniurn bromide have b e e n employed i n t h e s y n t h e s i s o f a r o y l v i n y l s u l p h i d e s , b e h a v i n g a s t h e s y n t h e t i c e q u i v a l e n t of t h e hydrosulphidornethyl s a l t (
155 1 . 2 3 8
( 156 1 a c t s a s a s o u r c e cyanide ion i n dichloromethane i n t h e s i n g l e phase
The phosphazophosphonium c y a n i d e
o f non-aqueous
c o n v e r s i o n o f r e a c t i v e h a l o g e n o compounds, e.g. trimethylsilyl halides,
a r o y l , a l l y l , and Polymer-
i n t o t h e r e s p e c t i v e n i t r i l e s . 239
bound phosphonium s a l t s h a v e b e e n u s e d f o r a n i o n i c a c t i v a t i o n i n 240 nucleophilic substitution processes. T r i b u t y l ( d o d e c y 1 )phosphonium h a l i d e s , i n t h e m o l t e n s t a t e a t 100°C, p r o m o t e t h e n u c l e o p h i l i c c o n v e r s i o n o f a r y l t o s y l a t e s t o a r y l h a l i d e s . 24 1
Z e o l i t e s c o a t e d w i t h phosphonium s a l t s c a t a l y s e h a l i d e e x c h a n g e between brornoethane a n d d i c h l o r o m e t h a n e a t 160'
and atmospheric
pressure, t h e reaction proceeding i n d e f i n i t e l y without renewal 242
of t h e c a t a l y t i c b e d . C l e a v a g e o f t h e p h o s p h o r u s - p h o s p h o r u s l i n k h a s b e e n shown t o o c c u r i n t h e r e a c t i o n s of b i s q u a t e r n a r y s a l t s d e r i v e d from 243 tetraalkyldiphosphines with a v a r i e t y of nucleophilic reagents. The f l u o r e s c e n c e o f a r a n g e o f p o l y c y c l i c aromatic h y d r o c a r b o n s is found t o b e quenched i n t h e p r e s e n c e of a l k y l t r i p h e n y l e l e c t r o n - t r a n s f e r from t h e h y d r o c a r b o n t o phosphonium s a l t s 244 t h e phosphonium i o n w i t h t h e f o r m a t i o n o f p h o s p h o r a n y l r a d i c a l s .
4 pT-Bonded
P h o s p h o r u s Compounds
T h i s area h a s u n d e r g o n e y e t a n o t h e r y e a r o f r a p i d d e v e l o p m e n t ? with
a s i g n i f i c a n t i n c r e a s e i n t h e volume o f p u b l i s h e d work.
A number
o f g e n e r a l r e v i e w s h a v e a p p e a r e d which c o v e r t h e c y c l o a d d i t i o n
react ions245 and c o o r d i n a t i o n
of pn-bonded p h o s p h o r u s
a n d a r s e n i c compounds, a n d t h e c h e m i s t r y o f t h r e e c o o r d i n a t e - X 5 The t o p i c c o n t i n u e s t o a t t r a c t t h e a t t e n t i o n of t h e t h e o r e t i c i a n s , and molecular o r b i t a l c a l c u l a t i o n s have
phosphoranes. 247
a p p e a r e d which r e l a t e t o n-bond e n e r g i e s o f p h o s p h o r u s a n d s i l i c o n
OrganophosphorusChemistry
28
+
Phm
Ph3&HR' C02R2
N RN
\=/
BF
Ph,Mz-i
X-
6Ph3X-
R'
(151) R'= Me or Ph 2 R = M e or ally1 X = B r or I
Ph36CH2SCOAr Br-
( 1 5 2 ) R'= H or Me 2 R =alkyl
Ph3kH2SH Br-
(153) n z 1 - 4 X = halide or OH
t Ph,P=N=PPh,]
+ CN
But2
R-
P=P-
R
(1 57)
A
ArP-PAr
(158) Ar = 2 ,4, 6
- 8ut3C,H2
ArpvPAr
PCF3
( 1 6 0 ) Ar=2,4,6-Buf3C,H,
(161 1
(159 M = Fe or Ru
R
M(CO l5 ( 1 6 2 ) X=SorNPh
29
I : Phosphines and Phosphonium Salts s y s t e m s , 2 4 8 ’ 2 4 9 and a v a r i e t y of P=N and P=C s y s t e m s 250-255 i n c l u d i n g phospha-alkenes, 253 phosphaketenes ,254 and c a r b o d i 255
phosphenes.
D i p h o s p h e n e s s t a b i l i s e d by b u l k y g r o u p s , e . g . tri-t-butylphenyl),
(157, R = 2,4,6-
can be i s o l a t e d i n high y i e l d from t h e
r e a c t i o n s o f a l k y l - o r aryl-(trichlorogermy1)phosphines e x c e s s o f t h e b a s e DBU. systems, e.g.
w i t h an
The f o r m a t i o n of l e s s s t e r i c a l l y crowded
(157, R = t - b u t y l ) ,
i s a l s o p o s s i b l e by t h i s r o u t e ,
t h e p r o d u c t s b e i n g c h a r a c t e r i s e d by c y c l o a d d i t i o n w i t h 1 , 3 d i e n e s . 256
The d i p h o s p h e n e ( 1 5 7 , R = 2,4,6-tri-t-butylphenyl)
i s a l s o f o r m e d , t o g e t h e r w i t h t h e three-membered
r i n g system (158)
and o t h e r p r o d u c t s , i n t h e r e a c t i o n s of d i - t - b u t y l d i i o d o s i l a n e w i t h an e x c e s s o f l i t h i u m n a p h t h a l e n i d e , f o l l o w e d by t r e a t m e n t Diphosphenes
w i t h 2,4,6-tri-t-butylphenyldichlorophosphine.
b e a r i n g a complexed t r a n s i t i o n m e t a l a s one of t h e p h o s p h o r u s substituents, e.g.
( 1 5 9 1 , a r e formed i n t h e r e a c t i o n s o f complexed-
metallobis(trimethylsi1yl)phosphines w i t h 2,4,6-tri-t-butylphenyld i c h l o r o p h o s p h i n e . 2 5 8 The less s t a b l e d i p h o s p h e n e s ( 1 5 7 , 259 p h e n y l ,260 o r t r i m e t h y l s i l y 1 2 6 1 ) h a v e b e e n R = t-butyl, c h a r a c t e r i s e d as 7-complexes of v a r i o u s t r a n s i t i o n m e t a l a c c e p t o r s .
A n o v e l mode of c o o r d i n a t i o n o f d i p h o s p h e n e s is s e e n i n t h e l i g a n d 262 behaviourof di(t-buty1)diphosphene i n a trichromium c l u s t e r . Complexes of di(2,4,6-tri-t-butylphenyl)diphosphene t h e a r y l s u b s t i t u e n t s are i n v o l v e d i n 7 - c o o r d i n a t i o n
i n which o n l y t o a chromium
a c c e p t o r have a l s o been d e s c r i b e d . 2 6 3 The r e a c t i o n s of chromium a n d t u n g s t e n c a r b o n y l complexes o f (-)menthyldibromophosphine w i t h magnesium i n THF y i e l d t h e d i p h o s p h e n e ( 1 5 7 , R = ( - ) - m e n t h y l ) i n t h e form o f complexes i n which b o t h p h o s p h o r u s atoms are 264
a-bonded t o a metal c a r b o n y l a c c e p t o r .
A new r o u t e t o s t a b l e d i p h o s p h i r a n e s , e . g .
(160),
is offered
by t h e r e a c t i o n o f t h e t r a n s - i s o m e r o f ( 1 5 7 ; R = 2 , 4 , 6 - t r i - t b u t y l p h e n y l ) w i t h diazomethane. 265 chemical c i s - t r a n s been r e v i e w e d . 266
The o x i d a t i o n and p h o t o -
isomerism of t h e l a t t e r d i p h o s p h e n e h a v e a l s o An e l e c t r o c h e m i c a l s t u d y o f t h e r e d o x
b e h a v i o u r of ( 1 5 7 , R = tris(trimethylsily1)methyl) h a s e n a b l e d
267 t h e spectroscopic c h a r a c t e r i s a t i o n of t h e r e l a t e d r a d i c a l anion.
The h i g h l y r e a c t i v e d i p h o s p h e n e ( 1 5 7 , R
=
trifluoromethyl),
a c c e s s i b l e from t h e r e a c t i o n o f trifluoromethyldiiodophosphine w i t h s t a n n o u s c h l o r i d e , h a s been t r a p p e d
w i t h t h e a i d of
1 , 3 - d i e n e s t o form D i e l s - A l d e r a d d u c t s e . g .
(161). 268
Diphos-
p h e n e s i n which b o t h p h o s p h o r u s a t o m s , t o g e t h e r w i t h t h e 7-system
Organophosphorus Chemistry
30
o f t h e d o u b l e bond, a r e i n v o l v e d i n c o o r d i n a t i o n t o metal c a r b o n y l a c c e p t o r s , a l s o u n d e r g o a d d i t i o n react i o n s a t t h e phosphorus-phosphorus
d o u b l e bond t o g i v e D i e l s - A l d e r
adduct s
and three-membered r i n g s y s t e m s , e.g. 269,270 ( w i t h s u l p h u r or p h e n y l a z i d e )
(with 1,3-dienes)
.
(1621,
The t o p i c of v a l e n c e isomerism i n v o l v i n g t h e p a r t i c i p a t i o n o f p h o s p h a - a l k e n e s h a s b e e n r e v i e w e d . 271
The k e t o p h o s p h a - a l k e n e (163) formed i n t h e r e a c t i o n o f 2,4,6-tri-t-butylbenzoyl c h l o r i d e w i t h l i t h i u m b i s ( trimethylsilyl)phosphide,
is converted during
chromatography on s i l i c a t o t h e e n o l i c form ( 1 6 4 ) o f a
.
dibenzoylphosphine 272
The E,Z_-isomers o f t h e phospha-alkene
(165)
have b e e n s e p a r a t e d by f r a c t i o n a l c r y s t a l l i s a t i o n and HPLC, and t h e i r s t r u c t u r e s s t u d i e d by X-ray s t u d i e s o f o t h e r phospha-alkene
diffraction.2739274 Structural 275 s y s t e m s have a l s o b e e n r e p o r t e d .
G a s p h a s e p y r o l y s i s of d i m e t h y l c h l o r o p h o s p h i n e l e a d s t o t h e f o r m a t i o n o f t h e r e a c t i v e phospha-alkene ( 1 6 6 1 , which h a s t h e e x p e c t e d b e n t s t r u c t u r e , p h o t o e l e c t r o n s p e c t r o s c o p y i n d i c a t i n g no i n v o l v e m e n t of p h o s p h o r u s 3d o r b i t a l s . 276 Two methods f o r t h e g e n e r a t i o n of t h e p e r f l u o r o p h o s p h a - a l k e n e ( 1 6 7 ) have b e e n d e s c r i b e d , one i n v o l v i n g t h e dehydrof l u o r i n a t i o n o f g a s e o u s
277
bis(trifluoromethy1)phosphine on p o t a s s i u m h y d r o x i d e p e l l e t s and t h e o t h e r t h e r e a c t i o n s of bis(trifluoromethy1)trimethylstannylphosphine with 1,3-dienes,
which r e s u l t i n t h e D i e l s - A l d e r
adducts (168). 278 P y r o l y s i s of t h e latter r e g e n e r a t e s t h e p h o s p h a - a l k e n e , 279 which r e a d i l y u n d e r g o e s a d d i t i o n r e a c t i o n s t o t h e d o u b l e bond t o g i v e t h e s e c o n d a r y p h o s p h i n e s ( 1 6 9 ) and t h e phosphinous a c i d d e r i v a t i v e s and t h e n a t u r e of t h e addend.
o r a l c o h o l s is pH-dependent.
(
170), depending on t h e c o n d i t i o n s The d i r e c t i o n o f a d d i t i o n of water Subsequent b a s e - i n d u c e d e l i m i n a t i o n
from t h e s e c o n d a r y p h o s p h i n e s ( 1 6 9 ) l e a d s t o new p h o s p h a - a l k e n e s ( 1 7 1 ) , which are found t o b e s u r p r i s i n g l y s t a b l e . 280 Dehydroh a l o g e n a t i o n r o u t e s have a l s o b e e n a p p l i e d f o r t h e p r e p a r a t i o n o f t h e new p h o s p h a - a l k e n e s
( 1 7 2 > 2 8 1 a n d ( 1 7 3 ) . 282
The b i s p h o s p h a -
a l k e n e ( 1 7 4 ) i s formed i n t h e r e a c t i o n of a s i l y l a t e d 1,2diphosphinobenzene w i t h diphenylcarbodiimide. Phospha-alkenes b e a r i n g a t r a n s i t i o n metal complex fragment a s a s u b s t i t u e n t a t
e it h e r p h o s p h o r u s 284-289 o r c a r b o n 290-291 have a l s o b e e n d e s c r i b e d . (175) h a s b e e n c h a r a c t e r i s e d i n s o l u t i o n as a complex i n v o l v i n g .rr-donation from t h e d o u b l e bond t o a t u n g s t e n c a r b o n y l a c c e p t o r . T h i s complex r e a c t s w i t h 1,3d i e n e s t o g i v e a d d u c t s e . g . ( 1 7 6 ) , i n which t h e p h o s p h o r u s atom
The u n h i n d e r e d phospha-alkene
I : Phosphines and Phosphonium Salts
/o
0
Me3Si
31
0,
(163 1 A r = 2,4 ,6- But3C6H2
MeNP*CH
\
.-0
H-
(164)
(165)
2
( 1 6 8 ) R = H ,Meor Ph
(166)
(167)
F3CP(H )CF2 X
F3CP( X )CF2H
(169) X=OH,OR,NR,
or PMe2
But-
P=C
/SR
\
( 1 7 0 ) X = C I , B r , SMe, SeMe or AsMe,
@-p=c(
\
X
( 17 1 1X= OR, N R2 or PMe2
X
( 1 7 3 ) X - C L or Br
PCI
(175)
F,CP=C
SR
(172) R = M e or Bus
CH2=
H
( 17 4 )
Me3Si
(176)
-
P=C
(177)
/Osi Me3
\
But
32
OrganophosphorusChemistry
is now a - c o o r d i n a t e d t o t h e m e t a l . 2 9 2 A d d i t i o n s t o t h e d o u b l e bond o f p h o s p h a - a l k e n e s c o n t i n u e t o b e explored.
The r e a c t i o n s o f ( 1 7 7 ) w i t h a l i p h a t i c d i a z o compounds
a n d w i t h n i t r i l e o x i d e s have g i v e n 1 , 2 , 4 - d i a z a p h o s p h o l e s and -oxazaphospholes, phospha-alkene
r e s p e c t i v e l y . 293
The a l k y n y l - s u b s t i t u t e d
( 1 7 8 ) u n d e r g o e s a wide r a n g e o f a d d i t i o n r e a c t i o n s
e x c l u s i v e l y a t t h e P=C c e n t r e , g i v i n g , e . g . ( 1 7 9 1 , o n t r e a t m e n t w i t h s u l p h u r , s e l e n i u m or diphenyldiazornethane. 2 9 4 V a r i o u s a d d i t i o n s t o t h e silylaminophospha-alkene ( 180
have been
r e p o r t e d , i n c l u d i n g a [2+21 c y c l o a d d i t i o n w i t h a r e a c t i v e s i l a a l k e n e t o g i v e t h e four-membered r i n g s y s t e m ( 1 8 1 ) . 295,296 R e a c t i o n s l e a d i n g t o s u b s t i t u t i o n a t t h e p h o s p h o r u s atom o f p h o s p h a - a l k e n e s have a l s o r e c e i v e d f u r t h e r s t u d y . phospha-alkene
The c h l o r o -
( 1 8 2 ; X = C 1 ) u n d e r g o e s halogen-exchange o n
t r e a t m e n t w i t h s i l v e r f l u o r i d e o r t r i r n e t h y l s i l y l bromide o r i o d i d e t o g i v e ( 1 8 2 ; X = F , Br o r I ) , r e s p e c t i v e l y . 2 9 7 The r e a c t i o n o f (182; X = C l ) w i t h sterically-crowded
lithiophosphide reagents has
g i v e n t h e phosphinophospha-alkene s y s t e m ( 1 8 3 ) which is r e p o r t e d t o i s o m e r i s e t o form t h e diphosphene ( 1 8 4 ) . 2 9 8 The a r y l phosphaa l k e n e ( 1 8 5 ) i s formed i n t h e r e a c t i o n of t h e c o r r e s p o n d i n g
-
chlorophospha-alkene w i t h t h e p-(t-buty1)phenyl Grignard r e a g e n t . D i e l s - A l d e r a d d u c t s o f b o t h g- and Z-isomers of ( 1 8 5 ) have b e e n i s o l a t e d from t h e i r r e a c t i o n s w i t h c y c l o p e n t a d i e n e . 2 9 9
The
e l e c t r o n - r i c h s i l y l - s u b s t i t u t e d phospha-alkenes (186; X
=
SiR,)
u n d e r g o exchange r e a c t i o n s a t p h o s p h o r u s w i t h o t h e r s i l y l h a l i d e s , a n d a l s o w i t h t r i p h e n y l g e r m y l - and t r i p h e n y l s t a n n y l h a l i d e s t o g i v e e . g . ( 1 8 6 ; X = SnPh,). 300 With t r i e t h y l s i l a n o l , ( 1 8 6 ; X = H )
is formed,301 a n d t h e r e l a t e d r e a c t i o n w i t h c h l o r o d i - t - b u t y l p h o s p h i n e g i v e s t h e phosphinophospha-alkene ( 1 8 6 ; X = PButz 1. 302 I t h a s a l s o b e e n shown t h a t e l e c t r o n - r i c h phospha-alkenes ( 1 8 6 ; X = Ph) ( a n d r e l a t e d p h o s p h a - a l l y 1
e.g.
c a t i o n s ) t a k e up two
e q u i v a l e n t s o f oxygen a t p h o s p h o r u s when t r e a t e d w i t h ozone a t room t e m p e r a t u r e t o g i v e z w i t t e r i o n i c s y s t e m s , e . g . ( 187 1. 303 The r e a c t i o n of t h e phospha-ally1
c a t i o n ( 1 8 8 ) w i t h iodomethane r e s u l t s
i n t h e f o r m a t i o n o f t h e p h o s p h i n e ( 1 8 9 ) which b e a r s two c a t i o n i c substituents.
An X-ray s t u d y of ( 1 8 9 ) h a s shown t h a t t h e geometry
a b o u t p h o s p h o r u s is p y r a m i d a l . 304
Two r o u t e s f o r t h e s y n t h e s i s of
t h e de l o c a l i s e d 2 -p hosp hon io-sub st it u t ed- 1-p ho s p h a - a l k e n e s y s t e m (190) have b e e n r e p o r t e d . 305 A number o f n o v e l c o o r d i n a t i o n complexes o f p h o s p h a - a l k e n e s have b e e n c h a r a c t e r i s e d by A p p e l ' s 3 0 6-308
group.
I : Phosphines and Phosphonium Salts
33
Me3SiC-CP
Me Si CECP=C(Si MeJ2 3
/x\
-C(Si
Me,)
( 1 7 9 ) X = S , Se or Ph2C
( 1 78)
(Me3SiI2NP-CHSi
I
(Me3Si),NP=CHSiMe3
I
8utCH2CH-Si
(180)
Me3 ( Me3SiI2C =PX
Me,
(182)
(181)
-@
P= P
, Ph
S ‘
Ph ( R, N
I
I
( 1 88)
=PX
i Mej
I
o=p-c
/
I
NMe2
0- \;Me2 ( 1 8 6 ) R = M e or Et
(185)
NMe2 NMe,
-cr61me312
(187)
NMe2 NMe2 I
(1 89)
(190)
34
Organophosphorus Chemistry Two a p p r o a c h e s f o r t h e s y n t h e s i s o f d i p h o s p h a d i e n e s y s t e m s
have been d e s c r i b e d .
The r e a c t i o n o f t h e p h o s p h a k e t e n e ( 1 9 1 )
w i t h t h e phospha-alkene lY3-diphosphabutadiene
( 1 9 2 ) has given t h e f i r s t s t a b l e a c y c l i c ( 193 1.
309
Nucleophilic displacement o f
c h l o r i n e from t h e chlorophosphino-substituted phospha-alkene
( 194)
by a n i o n i c metal c a r b o n y l complexes r e s u l t s i n t h e f o r m a t i o n o f t h e 4-metalla-1,3-diphosphadiene
s y s t e m ( 1 9 5 ) . 310
The complex
( 1 9 6 ) h a s b e e n i s o l a t e d from t h e r e a c t i o n o f t h e p h o s p h a k e t e n e ( 1 9 1 ) w i t h Fe,(CO)q. 311 and d i p h o s p h a - a l l e n e s
The f i r s t complexes o f 1 - p h o s p h a - a l l e n e s 312,313
have b e e n c h a r a c t e r i s e d .
The c h e m i s t r y of t h r e e c o o r d i n a t e p e n t a c o v a l e n t p h o s p h o r u s systems c o n t i n u e s t o develop.
Various r o u t e s t o t h e t h r e e
c o o r d i n a t e p h o s p h o r a n e s ( 1 9 7 ) have been d e s c r i b e d .
A s a result of
s e v e r e s t e r i c crowding, t h e s e m o l e c u l e s a d o p t a c h i r a l , nonp l a n a r s t r u c t u r e . 314-316
The f i r s t example of a t r i ( m e t h y 1 e n e ) -
p h o s p h a t e i o n (1981, i n which t h e c e n t r a l PC, u n i t is almost p l a n a r , h a s been p r e p a r e d by t h e a c t i o n o f f l u o r e n y l l i t h i u m on ( 1 9 7 ; R = C l ) . 317
The dialkylaminothiophosphoranes ( 199 1 u n d e r g o
c y c l o a d d i t i o n r e a c t i o n s i n v o l v i n g t h e P=C bond on t r e a t m e n t w i t h d i a z o a l k a n e s t o form A s - d i a z a p h o s p h o l e s . 318
The X5a3-phospha-
a l k y n e (200) is r e p o r t e d t o d i m e r i s e , w i t h a p h o s p h o r u s t o oxygen 319 r e a r r a n g e m e n t , t o form t h e X5-diphosphete s y s t e m ( 2 0 1 ) . The p r e p a r a t i o n , s t r u c t u r e and p r o p e r t i e s of p h o s p h a - a l k y n e s have been r e v i e w e d . 320 A g e n e r a l r o u t e t o phospha-alkynes a p p e a r s t o be offered i n the reactions of acid chlorides with tris(trimethylsily1)phosphine. phospha-alkenes
I n some c a s e s , t h i s l e a d s i n i t i a l l y t o t h e
( 2 0 2 1 which u n d e r g o b a s e - i n d u c e d
elimination of
h e x a m e t h y l d i s i l o x a n e u n d e r r e d u c e d p r e s s u r e t o form t h e phosphaa l k v n e s (. 2 0. 3 1 . ~ ~ I ~n 9o t ~h e~r ~cases. t h e l a t t e r are i s o l a t e d d i r e c t l y from t h e i n i t i a l r e a c t i o n . 3 2 i y324 Using t h i s a p p r o a c h , t h e f i r s t s t a b l e c r y s t a l l i n e phospha-alkynes
(203;
R = 1-
a d a m a n t ~ lor~ ~9 -~t r i p t y c y l 323) have b e e n i s o l a t e d . The phosphaa l k y n e s r e a d i l y undergo c y c l o a d d i t i o n r e a c t i o n s w i t h d i a z o m e t h a n e , a z i d e s and n i t r i l e o x i d e s t o form d i a z a - ,
t r i a z a - and oxazaphos-
A similar a p p r o a c h h a s b e e n u s e d i n t h e s y n t h e s i s of t h e f i r s t a r s a - a l k y n e (204), i s o l a t e d as a p a l e y e l l o w c r y s t a l l i n e s o l i d . 325 The c y c l o a d d i t i o n r e a c t i o n s of
pholes,
p h o s p h a - a l k y n e s w i t h s t e r i c a l l y crowded c y c l o b u t a d i e n e s l e a d t o t h e f i r s t D e w a r phosphabenzenes e . g . ( 2 0 5 ) , which are f o u n d t o b e s u r p r i s i n g l y s t a b l e t o h e a t a n d t o d i o x y g e n . 26 Not s u r p r i s i n g l y , t h e c o o r d i n a t i o n c h e m i s t r y o f phospha-alkynes
continues t o attract
I : Phosphines and Phosphonium Salts
+
P=C=O
35
,OSiMz
@
Me3Si-P=C
,OSiMe,
P=C,
,0SiMe3 P=c
‘But
\
But
( 194) R
(195) M = Mo or W
= 2 4 6- BUt3C6H2
-
-
L
( 197) R: alkyl ,a r y I
(196)
(1 98 1
,
CI, NMe2 or SPh 0
0
S
1
I/
R2N - P
‘;ti
, II
1 1 2 3
R2P-CPR
R
R
II
(200)R’=Ph or NPr’2 R2= Ph R’= Ph or OMc
Me3Si-P=C
/ OSi Me3
0 (201 1
RCEP
R‘
(202)
(203)
(204)
36
OrganophosphorusChemistry interest. 327y328
The phospha-alkyne
t ( 2 0 3 ; R = Bu ) u n d e r g o e s
c y c l o d i m e r i s a t i o n i n t h e c o o r d i n a t i o n s p h e r e of c e r t a i n t r a n s i t i o n
metal complexes t o form t h e 1,3-diphosphacyclobutadiene s y s t e m ( 2 0 6 1 , i s o l a t e d as a metal complex. 3 2 9 Raman s p e c t r o s c o p i c d a t a f o r t h e s i m p l e s t phospha-alkyne t h e m o l e c u l e e x h i b i t i n g v(C-H) 3 30 respectively.
(203;
R
=
H) h a v e b e e n r e c o r d e d ,
and v(C5P) a t 3218 a n d 1 2 7 7 cm’l,
The c h e m i s t r y of compounds i n v o l v i n g two c o o r d i n a t e p h o s p h o r u s i n N-P=N s y s t e m s a l s o c o n t i n u e s t o be e ~ p l o r e d , ~ ~ and l - f ~u r~t h~e r p r o g r e s s h a s b e e n r e p o r t e d i n t h e area of t h r e e c o o r d i n a t e p e n t a c o v a l e n t phosphorus-nitrogen unknown b o r a p h o s p h e n e s , R-B=P-R,
s y s t e m s . 337 y 3 3 8 The a s y e t may b e i n v o l v e d a s t r a n s i e n t
i n t e r m e d i a t e s i n t h e r e a c t i o n s o f s t e r i c a l l y crowded d i a l k y l a m i n o d i c h l o r o b o r a n e s w i t h a m i x t u r e of mono- and d i - l i t h i a t e d m e s i t y l p h o s p h i d e s , which l e a d t o t h e d i m e r i c s y s t e m ( 2 0 7 ) . 339 The t w o c o o r d i n a t e t h i o p h o s p h e n o u s a c i d d e r i v a t i v e s , X-P=S (X = RO o r
R, N)
, have
b e e n c h a r a c t e r i s e d i n t r a p p i n g e x p e r i m e n t s , 340 and t h e
c h e m i s t r y of t h e t h r e e c o o r d i n a t e a r y l d i t h i o p h o s p h o r a n e ( 2 0 8 ) h a s b e e n reviewed.341
C o n s i d e r a b l e i n t e r e s t h a s been shown i n t h e
c h e m i s t r y of t e r m i n a l p h o s p h i n i d e n e -complexes which i n v o l v e t h e R-P=MLn s k e l e t o n , where MLn r e p r e s e n t s a complexed t r a n s i t i o n 342-349 a n d t h e g e n e r a l area h a s been metal Tragment , r e v i e w e d . 350’351 M a t h e y ’ s g r o u p h a s c o n t i n u e d t o s t u d y t h e g e n e r a t i o n o f s u c h complexes by t h e t h e r m a l d e c o m p o s i t i o n of
7-phosphanorbornadiene s y s t e m s ,342-344 and o f p a r t i c u l a r i n t e r e s t i s t h e i r o b s e r v a t i o n t h a t t h e 1-pentenylphosphinidene-tungsten
p e n t a c a r b o n y l complex u n d e r g o e s an i n t r a m o l e c u l a r s e l f - i n s e r t i o n p r o c e s s t o form t h e complexed b i c y c l i c p h o s p h i r a n e ( 2 0 9 ) . 344 The f i r s t s t a b l e s t a n n a p h o s p h e n e ( 2 1 0 ) h a s been i s o l a t e d as a r e d , c r y s t a l l i n e s o l i d , from t h e r e a c t i o n o f a fluorosilyl(ary1)phosphine w i t h t - b u t y l l i t h i u m . T h i s compound is
air-sensitive,
r e p o r t e d t o b e s t a b l e a t room t e m p e r a t u r e f o r a b o u t o n e week, and r e a d i l y u n d e r g o e s a d d i t i o n s t o t h e d o u b l e bond, t h e d i r e c t i o n o f which i n d i c a t e s t h a t , as e x p e c t e d , t h e t i n atom i s t h e more 352 positive partner. The c h e m i s t r y of phosphenium i o n s , R,P+, ( c a t i o n i c s y s t e m s which i n v o l v e two c o o r d i n a t e p h o s p h o r u s ) a l s o c o n t i n u e s t o d e v e l o p , a n d h a s b e e n t h e s u b j e c t o f a major r e v i e w . 353 Full d e t a i l s of t h e r e a c t i o n s o f phosphenium i o n s w i t h d i e n e s have now a p p e a r e d . 354
I n a n e x t e n s i o n of t h i s s t u d y , it h a s been shown
t h a t t h e 9 - p h o s p h a b a r b a r a l a n e d e r i v a t i v e ( 2 1 1 ) i s formed i n t h e
I: Phosphines and Phosphonium Salts
37
P-CBut
tll
Bu c-P (205) R = 1-adamantyl
II
MesP-
B N R,
F$NB-
PMes
I
(206)
I
(207)
L?
W(CO),
(208)
(209)
[ R3P--P-PR31+AlCI~
( 2 1 0 1 Ar = 2,4,6-B~*~%H,
[ R13&
PTPR,] + l 2AlC1, R
(211 1
R2vR3 P.
R' ( 21 4)
( 2 1 5 ) R ' = M e , B u t o r Ph R 2 , R 3 = E t or Ph
(216)
\ / P h l C0l5 P-P
( R3P)zM
(217) R'=Ph R 2 = E t or Ph M = Cr or Mo
P -LW ( Ph
( 2 1 8 ) M = Pd or Pt
P R
(219)
38
Organophosphorus Chemistry
r e a c t i o n of a phosphenium i o n w i t h c y c l o o c t a t e t r a e n e .
An X-ray
s t u d y of ( 2 1 1 ) r e v e a l s t h a t i t s geometry i n t h e s o l i d s t a t e c l o s e l y a p p r o a c h e s t h a t o f t h e t r a n s i t i o n s t a t e f o r a Cope r e a r r a n g e m e n t , which o c c u r s i n s o l u t i o r a c c o r d i n g t o n.m.r. d a t a . 355
The r e a c t i o n s of t r i p h o s p h e n i u m s a l t s ( 2 1 2 ) have a l s o
a t t r a c t e d some a t t e n t i o n . -3 Selecti v e intramolecular exchange r e a c t i o n s i n v o l v i n g t h e o u t e r p h o s p h o r u s l i g a n d s have been o b s e r v e d , s u c h r e a c t i o n s i n v o l v i n g t h e u s e of c h e l a t i n g diphosphines having given a range of h e t e r o c y c l i c triphosphenium
s a l t s . 357
T r e a t m e n t of t r i p h o s p h e n i u m s a l t s w i t h a l k y l - o r a r y l -
h a l i d e s i n t h e p r e s e n c e of aluminium c h l o r i d e r e s u l t s i n t h e d i c a t i o n i c t r i p h o s p h o r u s s y s t e m ( 2 1 3 ) which is e f f e c t i v e l y a t e r t i a r y p h o s p h i n e b e a r i n g two c a t i o n i c s u b s t i t u e n t s .
Consistent
w i t h t h i s view, t h e e x p e c t e d p y r a m i d a l geometry a t t h e c e n t r a l 358 p h o s p h o r u s is o b s e r v e d . 5 P h o s p h i r e n e s , P h o s p h o l e s and P h o s p h o r i n s
The c h e m i s t r y of t h e p h o s p h i r e n e s y s t e m is a t t r a c t i n g i n c r e a s i n g a t t e n t i o n , w i t h t h e e v e n t u a l g o a l of p r e p a r i n g t h e p o t e n t i a l l y a r o m a t i c Huckel s y s t e m ( 2 1 4 ) .
A s i m p l e p r e p a r a t i o n of t e r v a l e n t
p h o s p h i r e n e s ( 2 1 5 ) i s a f f o r d e d by t h e r e a c t i o n s o f d i c h l o r o p h o s p h i n e s w i t h a l k y n e s i n t h e presence of aluminium c h l o r i d e , f o l l o w e d by r e d u c t i o n o f t h e i n t e r m e d i a t e c h l o r o p h o s p h i r e n i u m
s a l t s w i t h t r i b u t y l p h ~ s p h i n e . ~A ~new ~ r o u t e t o t h e complexed c h l o r o p h o s p h i r e n e ( 2 1 6 ) h a s been d e s c r i b e d . 360 M a t h e y ' s g r o u p h a s a l s o d e v e l o p e d a new one-pot c o n v e r s i o n of complexed p h o s p h o l e s t o t h e r e l a t e d complexed p h o s p h i r e n e s , which i n v o l v e s t h e r e a c t i o n of t h e p h o s p h o l e complex w i t h d i m e t h y l a c e t y l e n e d i c a r b o x y l a t e and a second d i s u b s t i t u t e d a l k y n e . 361 Upon t r e a t m e n t w i t h aluminium c h l o r i d e , l-B-chloroethylphosphirene-tungsten p e n t a c a r b o n y l complexes l o s e e t h y l e n e t o y i e l d t h e c o r r e s p o n d i n g complex o f t h e l-chlorophosphirene. 362
T e r v a l e n t p h o s p h i r e n e s seem t o behave
normally i n t h e i r r e a c t i o n s w i t h e l e c t r o p h i l i c r e a g e n t s , undergoing t h e u s u a l r e a c t i o n s a t phosphorus.
However, n u c l e o p h i l i c r e a g e n t s
a t t a c k complexed p h o s p h i r e n e s a t e i t h e r phosphorus d e p e n d i n g on t h e n a t u r e o f t h e r e a g e n t .
or
carbon,
The f r e e p h o s p h i r e n e s c a n
r e a d i l y b e l i b e r z t e d from t h e i r metal complexes o n t r e a t m e n t w i t h i o d i n e i n t h e p r e s e n c e of N-methylimidazole.
Complexed
p h o s p h i r e n e s undergo i n s e r t i o n r e a c t i o n s on h e a t i n g w i t h c a r b o n monoxide u n d e r p r e s s u r e t o g i v e complexes of p h o s p h o r u s a n a l o g u e s
of u n s a t u r a t e d B-lactams ( 2 1 7 ) . 363
A r e l a t e d i n s e r t i o n of zero-
39
1: Phosphines and Phosphonium Salts v a l e n t metal-phosphine
f r a g m e n t s h a s a l s o been r e p o r t e d , g i v i n g
( 2 1 8 1 %364 The t r i p h o s p h i r e n e s y s t e m ( 2 1 9 ) h a s been c h a r a c t e r i s e d 365 i n t h e form of a metal complex. The r e a c t i o n s o f p h o s p h o l e s w i t h a c i d s l e a d t o a v a r i e t y of r e a r r a n g e m e n t and d i m e r i s a t i o n p r o c e s s e s . Thus, e . g . , t r e a t m e n t o f l-phenyl-3-methylphosphole a t - 9 O O C w i t h hydrogen c h l o r i d e r e s u l t s i n i t i a l l y i.n p r o t o n a t i o n a t p h o s p h o r u s , b u t , o n r a i s i n g t h e t e m p e r a t u r e , t h e la-phospholium c h l o r i d e r e a r r a n g e s r a p i d l y t o g i v e t h e l-chloro-2,5-dihydrophospholium
salt (220).
r e a c t i o n of l-phenyl-3,4-dimethylphosphole
P a l l a d i u m ( 11) complexes o f
r e s u l t s i n thedimeric system ( 2 2 1 ) . 366
l-phenyl-3,4-dimethylphosphole
In contrast, the
w i t h hydrogen c h l o r i d e
r e a d i l y undergo D i e l s - A l d e r
a d d i t i o n s w i t h palladium(I1)-complexed
v i n y l p h o s p h i n e s t o form
complexes o f t h e u n s y m m e t r i c a l d i p h o s p h i n e s ( 2 2 2 1 , from which t h e 367 f r e e l i g a n d s c a n be o b t a i n e d by t r e a t m e n t w i t h c y a n i d e i o n . T r e a t m e n t of t h e B - c h l o r o e t h y l p h o s p h o l e
complex ( 2 2 3 ) w i t h
aluminium c h l o r i d e i n d i c h l o r o m e t h a n e s o l u t i o n l e a d s t o t h e 6,7-dihydrophosphepin
complex ( 2 2 4 ) which e x h i b i t s t h e e x p e c t e d The t h e r m a l
h a l o g e n o p h o s p h o r u s r e a c t i v i t y t o w a r d s n u c l e o p h i l e s . 368 d e g r a d a t i o n of phosphole dimers, e . g .
(225) in toluene solution
h a s been shown t o b e v e r y dependent o n c o n c e n t r a t i o n .
At
c o n c e n t r a t i o n s lower t h a n 0.04 M , i n t h e t e m p e r a t u r e r a n g e
--
120-130°, t h e p a r e n t p h o s p h o l e s a r e p r o d u c e d , w h e r e a s a t concentrations g r e a t e r than 1 . 0 M,
intermolecular reactions
p r e d o m i n a t e , l e a d i n g t o l o s s of t h e b r i d g i n g p h o s p h o r u s from t h e 7-phosphanorbornene m o i e t y t o g i v e d i h y d r o p h o s p h i n d o l e s , e . g . ( 2 2 6 ) . 369
P h o s p h o l e dimers h a v i n g
or anti-configuration at
t h e b r i d g i n g p h o s p h o r u s have been shown t o react w i t h Fe,(CO)S w i t h complete r e t e n t i o n of c o n f i g u r a t i o n at each phosphorus.
Both
isomers of t h e 9-phenylbicyclo[4,2, llnonatriene system ( 2 2 7 ) a l s o u n d e r g o c o m p l e x a t i o n w i t h c o m p l e t e r e t e n t i o n of c o n f i g u r a t i o n , 370 r a t h e r t h a n w i t h r e a r r a n g e m e n t a s h a s been s u g g e s t e d by o t h e r w o r k e r s . 371
F u l l d e t a i l s have now been r e p o r t e d o f t h e m e t a l -
c a t a l y s e d t h e r m a l d i m e r i s a t i o n of p h o s p h o l e s t o complexed 2 , 2 ' biphospholenes. 372
-
A n e w r o u t e t o monophosphaferrocenes ( 2 2 8 ) h a s
been d e v e l o p e d , which i n v o l v e s t h e r e a c t i o n o f a p h o s p h o l i d e a n i o n w i t h a f e r r i c i n i u m s a l t . 373
E l e c t r o c h e m i c a l s t u d i e s o f phospha374
f e r r o c e n e s have a l s o been r e p o r t e d .
F u l l d e t a i l s o f t h e s y n t h e s i s of b e n z o x a-p h o s-p h o l e s ( 2 2 9 ) have now a p p e a r e d . 375 The r e a c t i v i t y of t h e 1 , 2 - t h i a p h o s p h o l e - 2 s u l p h i d e ( 2 3 0 ) t o w a r d s n u c l e o p h i l e s h a s been e x p l o r e d . 376
The
Organ0rororororororororororororororororo osphoms Chemistry
40
Ph
CI >&=&DMe
Ph
2 CI-
Ph'
PR2 Me
Me
(222)
(221 1
(220 1
Ph ALCL 3
b
*
'P
l
4 P Ph
CICH2CH2
(224)
( 223)
225)
(
& Ph
Ph
a
.
(228)
(227)
(226)
R
ArqR
S=P,
S
(2301
( 2 2 9 ) R = a l k y l or aryl
Rc3C02Me
R p ' Ph'
Me0 ( 2 3 2 ) X = C0,Me or COPh
C02Me
'Ph
(233)
e
41
1: Phosphines and Phosphonium Salts p r e v i o u s l y unknown 1 H - 1 , 2 - a z a p h o s p h o l e s
( 2 3 1 ) a r e a c c e s s i b l e by
t h e regioselective addition of various acetylenes t o 1,3,2-
diazaphosphole-4-carbonitriles, a n d are f o u n d t o be r e m a r k a b l y i n s e n s i t i v e t o water a n d t o o x i d a t i o n . 3 7 7
I n t e r e s t i n t h e synthe-
sis a n d r e a c t i v i t y of o t h e r a z a p h o s p h o l e s y s t e m s h a s
c o n t i n ~ e d . ~ ~ ~ - ~ ~ ~ A s t r u c t u r a l s t u d y o f a molybdenum c a r b o n y l complex o f p h o s p h a b e n z e n e h a s shown t h a t t h e p h o s p h o r u s i s o-bonded t o t h e
m e t a l , a n d t h a t t h e g e o m e t r y of t h e l i g a n d c l o s e l y resembles t h a t o f t h e f r e e s y s t e m . 384 A d d i t i o n react i o n s of v a r i o u s p h o s p h a z e n e s w i t h a c e t y l e n e s have l e d t o 1,2X5-azaphosphorins 1,4X5-azaphosphorins
(233) y386 r e s p e c t i v e l y .
s u b s t i t u t e d As-phosphatriazines
(232>385 and
The p e r f l u o r o a l k y l -
(234) have been p r e p a r e d from t h e
r e a c t i o n s o f an imidoylamidine w i t h e i t h e r phosphorus p e n t a 387 c h l o r i d e o r phenyltetrachlorophosphorane. References
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6 7 8 9 10 11
12 13 14 15
16 17
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43
I : Phosphines and Phosphonium Salts 64 65 66 67 68 69
70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85
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103 104 105 106 107
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216.
284 285
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M.Frebe1, R.Boese, and M.Polk, J-Organomet. Chem., 1986, and M.Frebe1, Chem. Ber., 1986, 119, 1857. W-Malisch, U.Hofmocke1, S-Quashie,A.H.Cowley, and M.Dartmann, J.Chem. SOC., Chem. Commun. , 1985, 1687. A.M.Arif , A.H.Cowley, and S.Quashie, Organometallics,
288
L.Weber, K.Reizig, D.Gudat, E.Niecke, A.M.Arif, B.Krebs, D.Gudat, E.Niecke,
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D.S.Bohle, C.E.F.Rickard, and W.R.Roper, J.Chem. SOC., Chem. Commun., 1985,
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292 29 3 294
5,
593.
49
I: Phosphines and Phosphonium Salts 295
R.R.Ford, B.-L.Li, R.H.Neilson and R.J.Thoma, Inorg. Chem., 1985,
24,
1993.
305
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309
R.Appe1, P.Fb'lling, W.Schuhn, and
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1661.
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310
H.H.Karsch, H.-U.Reisacher, B.Huber, G.Mhler, W.Malisch, and K. Jgrg,
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306, 39.
T.Allspach, M.Regitz, G-Becker, and W-Becker, Synthesis, 1986, 31. G.t&rkl and H-Sejpka, Tetrahedron Lett. , 1985, 26, 5507. G.M&kl and H-Sejpka, Tetrahedron Lett., 1986, 27, 171. G.&kl and H.Sejpka, Angew. Chem., Int. Ed. En-i., 1986, 25, 264. J.Fink, W. R&ch , V. -J.Vogelbacherw, eg-a Chem. , Int. Ed. Engl. , 1986, 2, 280. M.F.Meidine, C.J.Meir, S.bbrton, and J.F.Nixon, J.Organomet. Chem. , 1985,
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255.
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V.F.Kalasinsky and S.Pechsiri, J. Raman Spectrosc., 1985, 16, 190. L.N.Markovskii, V.D.Romanenko, E.O.Kelbanskii, A.N.Chernega, M.Yu.Antipin, Yu.T.Struchkov, and I.E.Boldesku1, Zh. Obshch. Khim. , 1985, 55, 219 (Chem. Abstr., 1985, 103, 87 966). M.R.Marre-Mazibres, M x c h e z , R.Wolf , and J.Bellan, Nouv. J. Be Chim. ,
3 33
M.R.Mazieres, M.Sanchez, J.Bellan, and R.Wolf, phosphorus Sulfur, 1986,
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26, -
2,
97.
605.
Organophosphorus Chemistry
50 3 34 3 35
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O.J.Scherer, R.Walter, and W.S.Sheldrick, Angew. Chem., Int. Ed. Engl.,
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1985, 337
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342
A.Marinetti, C.Charrier, F.Mathey, and J.Fischer, Organometallics, 1985, 2134.
34 3 344 345 346 347
4,
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1986, 26, 25. 35 1 A.H.Cowley, Phosphorus Sulfur, 1986, 26, 31. 352 C.Couret, J.Escudie, J.Satge, A.Raharinirina, and J.D.Andriamizaka, J.Am. Chem. SOC., 1985, 8280. 353 A.H.Cowley and R.A.Kemp, Chem. Rev., 1985, 85, 367. 354 A.H. Cowley, R.A.Kemp, J.G.Lasch, N.C.Norman , C.A. Stewart, B.R. Whittlesey, and T.C.Wright, Inorg. Chem., 1986, 25, 740. 355 S.A.Weissman, S.G.Baxter, A.M.Arif, and A.H.Cowley, J.Am. Chem. SOC., 1986, 108, 529. 356 S.Lochschmidt , G. Mhler , B. H&er , and A. Schmidpeter, Z-Naturforsch., B: Anorg. Chem., Org. Chem., 1986, 41, 444. 357 S.Lochschmidt and A. Schmidpeter, Chem. , 1985, 40, 765. 358 A.Schmidpeter, S.Lochschmidt, K.Karaghiosoff, and W.S.Sheldrick, J. Chem. SOC. , Chem. Commun. , 1985, 1447. 359 S.Lochschmidt, F.Mathey, and A.Schmidpeter, Tetrahedron Lett., 1986, 27, 2635. 360 F.Mercier and F.Mathey, Tetrahedron Lett., 1986, 27, 1323. 361 A.Marinetti and F.Mathey, J.Am. Chem. SOC., 1985, 4700. 362 B. Deschamps and F.Mathey, 363 A.Marinetti, J.Fischer, and F-Mathey,J.Am. Chem. SOC., 1985, 5001. 364 D.Carmichae1, P.B.Hitchcock, J.F.Nixon, F.Mathey,and A.Pidcock, J.Chem. SOC., Chem. Commun., 1986, 762. 365 M-Peruzzini and P.Stoppioni, J.Organomet. Chem. , 1985, 288, C44. 366 L.D.Quin, S.E.Belmnt, F.Mathey, and C.Charrier, J.Chem. SOC. , Perkin Trans. 11, 1986, 629. 367 M.S.Holt, J.H.Nelson, P.Savignac, and N.W.Alcock, J.Am. Chem. SOC. , '1985, 107, 6396. 368 Geschamps and F.Mathey, Tetrahedron Lett. , 1985, 26, 3461. 369 L.D.Quin and K.C.Caster, Phosphorus Sulfur, 1985, 25, 117. 889. 370 A.L.Crumbliss, R.J.Topping, and L.D.Quin, Tetrahedron Lett., 1986, 371 W.J.Richter, Tetrahedron Lett. , 1985, 26, 1039.
107,
~
~~
107,
-
107,
27,
I : Phosphines and Phosphoniurn Salts 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387
51
F.Mercier, F.Mathey, J-Fischer, and J.H.Nelson, Inorg. Chem. , 1985, 24, 4141. 171. R.M.G.Roberts and A.S.Wells, Inorg. Chim. Acta, 1986, P.Lemoine, M.Gross, P.Braunstein, F.Mathey, B.Deschamps, and J.H.Nelson, J.0rganomet. Chem., 1985, 295, 189. J.Heinicke and A.Tzschach, Phosphorus Sulfur, 1985, 25, 345. H.Tanaka, T.Saito,and S.Motoki, Bull. Chem. SOC. Jpn., 1986, 59, 59. K.Karaghiosoff, H.Klehr, and A.Schmidpeter, Chem. Ber., 1986, 119,410. O.Diallo, M.T.Boisdon, L.Lopez, C-Malavaud,and J.Barrass, Tetrahedron Lett., 1986, 27, 2971. Y.Y.C.Yeung Lam KO, R.Carri6, L.Toupet, and F.De Sarlo, Bull. SOC. Chim. Fr., 1986, 115. B.A.Arbuzov, E.N. Dianova, I.Z-Galeeva,I .A.Litvinov, Yu.T. Struchkov, A.N.Chernov, and A.V.IYyasov, Zh. Obshch. Khim., 1985, 55, 3 (Chem. Abstr., 1385, 103,22 651). B.A.Arbuzov, E.N.Dianova, and E.Ya.Zabotina, Zh. Obshch. Khim., 1985, 55, 1471 (Chem. Abstr. , 1986, 104,207 3 5 3 ) . B.A.Arbuzov, E. N.Dianova, E. Ya. Zabotina, Yu. Ya.Efremv, R.L .Korshunov, 1464 (Chem. Abstr. , 1986, 104, and R.Z.Musin, Zh. Obshch. Khim., 1985, 2, 224 960). Z.Jinglin and C.Zhisong, Synthesis, 1985, 1067. A.J.Ashe 111, W.Butler, J.C.Colburn, S.Abu-Orabi, J.Organomet. Chem., 1985, 282, 233. T.Kobayashi and M.Nitta, Chem. Lett., 1985, 1459. 3-Barluenga,F.Lopez, and F.Palacios, J.Chem. SOC., Chem. Commun., 1985, 1681 K.J.L.Paciorek, J.H.Nakahara, M.E.Smythe, D.H.Harris, and R.H.Kratzer, 3.Fluorine Chem., 1985, 28, 441.
112,
2
Pentaco-ordinated and Hexaco-ordinated Compounds BY C. D. HALL 1. I n t r o d u c t i o n : - Once a g a i n t h e y e a r has p r o d u c e d a s t e a d y f l o w of p u b l i c a t i o n s i n t h e realm o f h y p e r v a l e n t p h o s p h o r u s c h e m i s t r y
w i t h t h e e m p h a s i s o n b i c y c l i c p h o s p h o r a n e s c o n t a i n i n g small ( f o u r -
or five-membered) r i n g s .
An e x c e l l e n t r e v i e w on t h e r e a c t i v i t y o f
A5-l,3,2-diheterophosphacyclanes d e a l s w i t h t h e P ( I 1 I ) s P ( V ) e q u i l i b r i u m i n hydrophosphoranes and t h e phosphate-phosphorane phosphimide-phosphorane
and
e q u i l i b r i a i n h y d r o x y p h o s p h o r a n e s a n d amino-
phosphoranes respectively'. In addition it d e a l s with o t h e r tautomeric t r a n s f o r m a t i o n s o f p h o s p h o r a n e s , t h e t h e r m o l y s i s o f p h o s p h o r a n e s and n u c l e o p h i l i c s u b s t i t u t i o n a t p e n t a c o - o r d i n a t e phosphorus. The l a t t e r t o p i c i s c o m p l i m e n t e d by a n a r t i c l e which d i s c u s s e s t h e d i s p l a c e m e n t of halogen from f o u r - and f i v e - c o o r d i n a t e phosphorus by a r a n g e o f p o l a r i s a b l e n u c l e o p h i l e s 2 a n d a number of p e n t a c o o r d i n a t e d e r i v a t i v e s of p h o s p h o r u s are m e n t i o n e d i n a g e n e r a l a r t i c l e o n t h e c o o r d i n a t i o n c h e m i s t r y o f e l e m e n t s o f Group V 3 . I t is i n t e r e s t i n g t o n o t e t h a t many of t h e t e c h n i q u e s d e v e l o p d i n p h o s p h o r u s c h e m i s t r y are now b e i n g r o u t i n e l y a p p l i e d t o h y p e r v a l e n t molecules of o t h e r e l e m e n t s .
For i n s t a n c e , Martin
et g .
h a v e s t u d i e d t h e p s e u d o r o t a t i o n a l ( B e r r y ) mechanism f o r t h e i n v e r s i o n of 1 0 - S i - 5 - s i l i c o n a t e s
(1) by 1 9 F n . m . r .
and demonstrated a
l i n e a r c o r r e l a t i o n between nGh f o r i n v e r s i o n a t s i l i c o n and t h e 5*
v a l u e s of t h e v a r i a b l e l i g a n d , Y 4
The e n e r g y b a r r i e r s f o r
p s e u d o r o t a t i o n are s i g n i f i c a n t l y lower t h a n t h o s e f o r t h e p h o s p h o r u s analogues.
Likewise C o r r i u
et g .
have a p p l i e d n.m.r.
techniques
t o a s t u d y of l i g a n d r e o r g a n i s a t i o n a t p e n t a c o - o r d i n a t e s i l i c o n 5 a n d t w o p r e l i m i n a r y r e p o r t s h a v e a p p e a r e d on t h e mechanism o f nucl e o p h i l i c d i s p l a c e m e n t r e a c t i o n s a t p e n t a c o - o r d i n a t e d 6 a n d hexacoordinated silicon7.
F u r t h e r m o r e , h y p e r v a l e n t compounds o f a n t i -
mony* a n d b i s m u t h g h a v e been e x a m i n e d as m o l e c u l e s o f i n t e r e s t i n t h e i r own r i g h t a n d as u s e f u l s y n t h e t i c t o o l s . 2.
S t r u c t u r e , Bonding and Ligand R e o r g a n i s a t i o n .
-
An X-ray
a n a l y s i s o f t h e m o n o c y c l i c p h o s p h o r a n e (2) r e v e a l s a t b p s t r u c t u r e w i t h t h e h y d r o g e n i n an a x i a l p o s i t i o n a n d an H-P bond l e n g t h o f
2: Pentaco-ordinated and Hexaco-ordinated Compounds
53
H
& F:3
Si -Y
Ph\ Ph'
(
3a)R = p - XC,HL
(3b)
or Me
(4)Z=Me (5
1 Z = CF3
i
Organophosphorus Chemistry
54
HF, e
R ,PO
Me3Si OSi Me3
(RFl3PF2
(R,=),PO
~
HF
C 6)
;/NEt2
Ph-
P
I
F
'
NEt,
-[ Et3dBF;
(9)
+
PhP(NEt2I2
4-
BF4-
EtF
Ph
+
Ph3P(OEtI2
Y
(11)
''Y
&
Et20
t
Ph,PO
Ph
(13)
voH OH
(14)
+
(10)
HO -OH
]
\
Ph3P(OEt l3
(1 6 )
/
+
Ph,PO
2: pen taco-ordinated and Hexaco-ordinated Compounds
55
127 pm”. An analysis of the Fourier Transform i.r. spectrum of PFg around 946 cm-’ gave rise to nine spectroscopic constants for the band and five f o r the v 3 + u 7 - ~ d 7 band which ailowed calculation of the wavenumbers of the v 3 band with a precision of 1 x cm-l . i 1 v3
A theoretical study of model apically-substituted and equatorially-substituted acyclic phosphoranes, H4PX, revealed a ligand CECH > H > CH3 > OH > apicophilicity in the order, Ci? CN > F O - > S - > NHZ 3 B H 2 ” . Apicophilicity is enhanced by ligand electronegativity and diminished by a-donation and is broadly in line with Trippett’s experimental apicophilicity scale13. A significant discrepancy, however, occurs in the relative ranking of fluorine and chlorine. This was attributed to the fact that in previous systems the ligands other than X around phosphorus were T-donating and were thus not well represented by the model hydrogens of the theoretical study. On the experimental front, ‘JPc values have been used to estimate the relative apicophilicities of aryl groups or methyl groups v e r s u s phenyl groups in the monocyclic phosphoranes ( 3 ) 1 4 . The aryl groups show a decrease in apicophilicity in the order, X = CF3 > Br > H > Me > Me0 > MeZN as expected from a combination of electronegativity and availability of e-type lone pairs. The methyl and phenyl groups have similar apicophilicities in agreement with earlier work on trigonal bipyramidal phosphoranes15. It has also been shown by 3 1 P n.m.r., that pseudorotation of the oxyphosphoranes ( 4 ) and ( 5 ) involves intermediate structures with a diequatorial disposition of the dioxaphospholene ring, thus v i o lating the ring-strain rule16. 3 . _Acyclic phosphoranes. - A number of difluorotris(perf1uoroalky1)phosphoranes (7) have been prepared by electrochemical fluorination of trialkylphosphine oxides (6) in anhydrous H F 1 7 . The phosphoranes are conveniently converted into the perfluoroalkylphosphine oxides (8) by reaction with hexamethyldisiloxane and the phosphoranes are regenerated by treatment of ( 8 ) with HF. The formation of alkyl or aryldiaminofluorophosphonium salts (3. 10) from the corresponding difluorophosphoranes ( e . g . 9 ) has been described18 using BFy.0Et2, Et30+ B F 4 - , PCa3 or SbF5 to cleave a phosphorus-fluorine bond. The compounds were characterised by a combination of ’H, 13C, 3 1 P and 19F n.m.r. together with their i.r. spectra. ->
Organophosphorus Chemistry
56
phWPr"
Ph P-0
n
PrAPh
H
H
Z
(17) Ph,P=C
H Pr
+
PhCHO
(+Li Br at - 7 8
OC)
+
Ph
WH APr" H E
(18)
Ph,P=CHPr"
base
nph#oH Pr H
____)
!
Ph
PhCHO
Ph (21) X =
0-
NMe,
( 2 2 ) X = p- NMez
PhCHO
(1 8)
PP h3Br( 20)
+
-
!
Ph
+
Ph
PhCH=CH Ph
Z+E
57
2: pen taco-ordinated and Hexaco-ordinated Compounds
(25) Et3N
Me
,
Me2 P (01CH C( CF, ),OH
Me’
I
MJ e -!C , F3 Me/
CI
I
K+6PrIF
-C(C02Me)=CH(C02Me)
OMe
(30)Z / E
120H
(28)
(26)
P
OCH(CF3
\ I P-CH,C(CF,
Me,
Me’
pSI P
(CF,
I
OMe
I
- CHC02Mc
C02Me (311
58
Organophosphorus Chemistry The p i o n e e r i n g work of Denney
et g i 9
on t h e s y n t h e t i c
u t i l i t y o f oxyphosphoranes h a s been t h o r o u g h l y e x p l o i t e d by Evans
et al.
i n d e m o n s t r a t i n g t h a t diethoxytriphenylphosphorane p r o m o t e s (e.g.1 1 ) t o c y c l i c
m i l d and e f f i c i e n t c y c l o d e h y d r a t i o n of d i o l s
1 3 ) v i a t h e c y c l i c phosphorane ( 1 2 ) 2 0 , 2 1 . e t h e r s (3.
Simple
1 , 2 - , 1 , 4 - , and 1 , 5 - d i o l s a f f o r d good y i e l d s of t h e c y c l i c e t h e r s b u t 1 , 3 - p r o p a n e d i o l and 1 , 6 - h e x a n d i o l g i v e m a i n l y 3-ethoxy-1-prop a n o l and 6-ethoxy-1-hexanol
r e s p e c t i v e l y whereas t r i - and t e t r a -
s u b s t i t u t e d l , 2 - d i o l s a f f o r d t h e r e l a t i v e l y s t a b l e 1,3,2- dioxphospholanes.
I n some i n s t a n c e s
(e.g.1 4 ) ,
ketones
(3. 16)
are formed by a s y n c h r o n o u s 1 , Z - h y d r i d e s h i f t w i t h i n ( 1 5 ) .
The
s y n t h e t i c u t i l i t y h a s been e x t e n d e d t o d i e t h o x y p h o s p h o r a n e s s u p p o r t e d on a p o l y s t y r e n e b a c k b o n e z 2 . A c y c l i c p h o s p h o r a n e s , ArnP(OR)5-n w i t h
n
=
shown t o h y d r o l y s e by an SN1(G) mechanism f o r 11.
0
-
=
1, 2 and 3 b u t
3 have been
by an S 2 ( P ) o r a d d i t i o n - e l i m i n a t i o n mechanism f o r g = 023. T h i s N d u a l i t y o f mechanism i s a n a l o g o u s t o t h e c l a s s i c a l SN1 v s S 2 N mechanisms o b s e r v e d f o r s o l v o l y s i s r e a c t i o n s a t t e t r a h e d r a l c a r b o n . 4.
Ring C o n t a i n i n g P h o s p h o r a n e s .
4 . 1 Monocyclic P h o s p h o r a n e s .
-
F u r t h e r s t u d i e s on t h e mechanism
and s t e r e o c h e m i s t r y of t h e W i t t i g r e a c t i o n have been c o n d u c t e d by
a c o m b i n a t i o n of lH, I 3 C and 3 1 P n . m . r . 2 4 , 2 5 . T h e results show t h a t a t -18OC b o t h c i s and t r a n s d i a s t e r e o m e r i c o x a p h o s p h e t a n s ( e . g . 1 7 and 1 8 ) may be o b s e r v e d and t h e i r d e c o m p o s i t i o n t o a l k e n e s m o n i t o r e d by n . m . r . Evidence w a s p r e s e n t e d t o su g g e st t h a t d u r i n g
-
t h i s p r o c e s s oxaphosphetan e q u i l i b r a t i o n i n v o l v i n g t h e s i p h o n i n g o f (17) i n t o (18) occurred i n competition with alkene formation. T h i s a c c o u n t s f o r t h e c o n s i d e r a b l e d i s c r e p a n c y between t h e a l k e n e Z / E r a t i o found on work-up and t h e i n i t i a l oxaphosphetan c - i s l t r a n s ratio.
By a p p r o a c h i n g t h e problem from t h e s t a r t i n g p o i n t of t h e
d i a s t e r e o m e r i c phosphonium s a l t s ( 1 9 ) and ( 2 0 ) , d e p r o t o n a t i o n s t u d i e s and c r o s s o v e r e x p e r i m e n t s showed t h a t t h e r e t r o - W i t t i g r e a c t i o n was o n l y d e t e c t a b l e w i t h t h e e r y t h r e o isomer ( 1 9 ) v i a t h e F u r t h e r m o r e , i t w a s shown t h a t u n d e r
cis-oxaphosphetan
(17).
lithium-salt-free
c o n d i t i o n s , m i x t u r e s of ( 1 9 ) and ( 2 0 ) e x h i b i t e d
s t e r e o c h e m i c a l d r i f t b e c a u s e of a s y n e r g i s t i c e f f e c t ( o f u n d e f i n e d mechanism) between t h e o x a p h o s p h e t a n s ( 1 7 ) and ( 1 8 ) d u r i n g t h e i r decomposition t o a l k enes.
I n a s i m i l a r s t u d y McEwen h a s shown t h a t d u r i n g t h e r e a c t i o n of b e n z a l d e h y d e w i t h t h e s e m i - s t a b i l i s e d y l i d s ( 2 1 ) and ( 2 2 ) , t h e i n t e r m e d i a t e o x a p h o s p h e t a n s ( 2 3 and 2 4 ) are n o t d e t e c t a b l e by n . m . r .
59
2: Pentaco-ordinated and Hexaco-ordinated Compounds
\I
Z
-P-c( /
.
(37)
A = RO R
RR’P(X)O
NU= S C N , N~ , CN X = 0 , S or Se
RR’P(X)O
R)=CHCOR‘
OrganophosphorusChemistry
60 I
0
z
+
ru
0
n
2: pen taco-ordinated and Hexaco-ordinated Compounds
61
do' POCH*CF3
(40)
I
C F3C H20SP h
@I-
0C H2C F,
S
x
0
OCH2CF,
OCH2CS13
OCH2CF3
(41)
(42)
Ph,P
+
Pr'O,CN=NCO,Pr'
,O-CH2
I + Ph P
Pri02CNH P?O,CNH
3 \
\
(CH,),
/
O-CH2
(43)
[ 'ph36.
Pr'02CN- Nco, Pr
'
1
Pr 0,CN
I
Ph,P
-NH C0,Pr'
-OC H2(CH,),,CH,OH J a,b)
Organophosphorus Chemistry
62
Tne u s u a l c r o s s o v e r e x p e r i m e n t a l p r o b e a l s o showed t h a t t h e f o r m a t i o n of ( 2 3 ) and ( 2 4 ) w a s n o t d e t e c t a b l y r e v e r s i b l e , presumably b e c a u s e t h e r a t e of f o r m a t i o n of t h e s t i l b e n e p r o d u c t s w a s c o n s i d erably f a s t e r than the r e v e r s a l t o reagentsL6. H y d r o l y s i s of t h e oxaphosphetan ( 2 5 ) gave t h e p h o s p h i n e o x i d e ( 2 6 ) which was c o n v e r t e d i n t o ( 2 7 ) by t r e a t m e n t w i t h a m i x t u r e of t h i o n y l c h l o r i d e and p y r i d i n e . caused r i n g opening t o triethylamine.
T r e a t m e n t of ( 2 5 ) w i t h HCa a l s o
( 2 8 ) which w a s r e v e r s e d
011
treatment with
The c h l o r o p h o s p h o r a n e ( 2 a ) l o s t n e x a I l u o r o i s o -
p r o p a n o l on h e a t i n g t o g i v e ( 2 7 ) which w a s f l u o r i c a t e d t o g i v e (29)27.
A l l t h e compounds were c h a r a c t e r i s e d ~y l H , I9F and 3 1 P
n.m.r. I n a c o n t i n u a t i o n of t h e i r work on t h e i n t e r a c t i o n of t r i c o o r d i n a t e d p h o s p h o r u s compounds w i t h a c t i v a t e d a l k y n e s , Burgada
et al.
have p r o v i d e d a d e t a i l e d d e s c r i p t i o n of t h e s y n t h e s i s of
-
-
p h o s p h o r z n e s ( e . g . 3 0 ) , t h e i r e q u i l i b r a t i o n w i t h y l i d s ( e . g . 31) and t h e mechanism of f o r m a t i o n of b o t h sets of p r o d u c t s from
a c e t y l e n i c . e ~ t e r s ~ * ,T~h i~s .s t u d y h a s been e x t e n d e d t o i n c l u d e a l k y n e - o n e s and a l k y n e - d i o n e s as s u b s t r a t e s and i n t h e p r e s e n c e o f p r o t i c r e a g e n t s ( H Z ) t h e u n d e t e c t e d i n t e r m e d i a t e s ( g e n e r a l i s e d by 32) were t r a p p e d as v i n y l i c p h o s p h o r a n e s ( 3 3 ) , c y c l i c 3 h o s p h o r a n e s ( 3 4 ) o r y l i d s ( 3 5 ) 3 0 . The c h l o r i n e l i g a n d s of p h o s p h o r a n e s ( 3 6 ) and (37) may b e exchanged by n u c l e o p h i l e s u n d e r v e r y m i l d c o n d i t i o n s 3 1 and t h e r e a c t i o n s w i t h n u c l e o p h i l e s s u c h a s organophosphorus a c i d s and t h i o c y a n a t e s are p a r t i c u l a r l y i n t e r e s t i n g s i n c e t h e y p r o v i d e a s o u r c e of p h o s p h o r a n e s which have c o n s i d e r a b l e s y n t h e t i c u t i l i t y . Although r e l e v a n t t o p e n t a c o - o r d i n a t e phosphorus s p e c i e s as i n t e r m e d i a t e s r a t h e r t h a n i s o l a b l e compounds, t h e o r i g i n of e x o c g c l i c c l e a v a g e i n t h e a l k a l i n e h y d r o l y s i s of m e t h y l e t h y l e n e p h o s p h a t e i s s t i l l a s o u r c e of major c o n t r o v e r s y and hence i s worthy of comment. i n t h i s section. Two p a p e r s by Kluger and T h a t ~ h e r claim ~ ~ , ~ ~ t h a t , i n c o n t r a s t t o r e p o r t s from t h e a d v o c a t e s of t h e stereoe l e c t r o n i c t h e o r y 3 4 , t h e p r o d u c t s of e x o c y c l i c c l e a v a g e , m e t h a n o l In and e t h y l e n e p h o s p h a t e , are produced i n t h e i n i t i a l r e a c t i o n , t h e s e c o n d p a p e r from K l u g e r , t h e h y d r o l y s i s of m e t h y l e t h y l e n e p h o s p h a t e was c a r r i e d o u t i n D 2 0 c o n t a i n i n g D 2 1 9 0 a n d t h e p a t t e r n o f i s o t o p i c a l l y s h i f t e d p h o s p h o r u s n . m . r . p e a k s of e t h y l e n e phosp h a t e and i t s h y d r o l y s i s p r o d u c t r u l e d o u t t h e involvement of h e x a c o - o r d i n a t e phosphorus i n t e r m e d i a t e s . I n s t e a d , a mechanism (Scheme 1) i n v o l v i n g a d i a n i o n i c i n t e r m e d i a t e ( 3 8 a h ) w a s p r o p o s e d w i t h P-OMe bond c l e a v a g e from an a p i c a l p o s i t i o n ( 3 8 b ) .
Since t h e
63
2: Pentaco-ordinated and Hexaco-ordinated Compounds
(45)a)R 1 , R 2 = Ph;
b ) R'=Ph , R2= PhO, E t O ;
(47)
(46)
c ) R ' , R 2 = PhO, E t O .
-e. bR
0 Ph-
R
(48)a)R = H b) R = M e
0
(54)
0
I1
64
Organophosphorus Chemistry
Et3NH +
o
?:$
Ho
(56)
(55)
I
LiOCH(CF3I2
(59)
CF3
D
H- 7 ; . 0
' 5 CF3
i
(CF3 I 2 C 0
2: Pentaco-ordinatedand Hexaco-ordinated Compounds
65
stereoelectronic theory requires exclusive endocyclic cleavage from (38b), the finding that exocyclic phosphorus-oxygen bond cleavage does invcive a pentaco-ordinate intermediate means that the orbital interactions inherent in the stereoelectronic picture, must play a secondary r o l e . The sulphur-bridged pentaoxyphosphorane (41) has been prepared by the route shown and its ground state structure studied by a combination of ‘ H , ‘-’F,3 1 P and 13C n.m.1.. spectroscopy35. The l 9 F n.m.r. data indica-te that at - 6 5 O C (where three 1 9 F triplets are observed) the pkicsphorane exists as structure (42) whereas at 26OC the spectrum (two I9F triplets, ratio 2 : l ) is consistent with conventional pseudorotation in a monocyclic system; at llOOC the three trifluoroethoxy groups become equivalent. The use of azodicarboxglates as a route to dioxaphosphoranes continues to attract attention. In the most recent contribution, triphenylphosphinc and di-iso-propyl azodicarboxylate ( 4 3 ) are shown to react with prcpane-1,3-diol and butane-l,4-diol in THF at OOC under h i g h t i o 7 : COY,, to give the expected sixand seven-membered-ring phosphoranes (44 ab)36. In more concentrated solution however, cyclic oligomers are formed. Substituted and ccnformationally restricted 1,3- and 1,4-diols form the ’
expected cyclic; phosphoranes without recourse to high dilution techniques. In a study of the reactions 01 acyclic o-methoxyphenylp h o s p h i n i t e s ( 4 5 a ) , phosphonltes (45b) and phosphites (45c) with halogens,the intermediate halogenophosphonium salts (46) are stabilised either b y ligand exchange with starting material (not shown) or by elimination of methyl halides to form cyclic phosphoranes i4 7 ) -3 ; . 4.2 Bi.cyclic and Tricyclic Phosphoranes. - In an extension of
earlier w o r k , McClelland 5 g . have studied the kinetics and rcechanism of hydrolysis of spirophosphoranes (48 ab) containing six-membered rings”. Despite the structural similarities, considerabie differences are observed in comparison with the
hydrolysis of the analogous five-membered spirophosphoranes, the most notable being that the phosphonicm ion intermediates ( 4 9 ab) are observable below pH9. Kinetic and spectral analyses show that the hydrolysis mechanism involves reversible formatim of these phosphonium ions with IC1 = [48a] [ H + ] /[49a] = 3 x fbllowed by rate-limiting addition of water to the phosphonium ion and at high p H , rate limiting addition of thc hydroxide ion. This
66
OrganophosphorusChemistry
(56)
X + . -
H
0
(60al X = C L
2 ( CF3 12C0
(60b)
I MeS
h v , Me2S
-
X = MeS
+
(64)
MeO-
(65)
2: Pentaco-ordinated and Hexaco-ordinated Compounds
67
(66)
(68)
I
ButO*
(701
9
&I-
(711
0
0%- 1
Cl
+
Mg(SiMe,)2.DME
(731
&i-siMe3
4
9 0-.. I 0
(72) ( 7 4 ) 63'P, -132.6
Organophosphorus Chemistry
68
( 7 6 ) a,R= H b , R = Me
(75) a,R=H b , R = Me Ph
Ph
Ph
(>P-OPh
+
.o
09
2: Pentaco-ordinated and Hexaco-ordinated Compounds m e c h a n i s m h a s i m p l i c a t i o n s f o r t h e m e c h a n i s m o f h y d r o l y s i s of a c y c l i c p h o s p h o n i u m s a l t s w h i c h , i t is a r g u e d , i n v o l v e s r a t e l i m i t i n g f o r m a t i o n cf a h y d r o x y p h o s p h o r a n e i n t e r m e d i a t e " .
A
q u a n t i t a t i v e st,udy o f t h e e q u i l i b r i u m c o n s t a n t s and rate c o n s t a n t s f o r t h e t r a n s f o r m a t i o n s o f a s p i r o c y c l i c hydroxyphosphorane (52) i n a q u e o u s s o l u t i o n h a s a l s o b e e n a ~ c o m p l i s h e d ~ ~ T. h e p h o s p h o r a n e e q u i l i b r a t e s w i t h t h e isomeric p h o s p h i n a t e ( 5 3 ) a n d i n b a s e f o r m s
is e s t i m a t e d t c l i e i n
t h e p h o s p h o r a n o x i d e i o n ( 5 4 ) f o r w h i c h pK
-2
A s t u d y of t h e k i n e t i c s a n d m e c h a n i s m of t h e
t h e r a n g e 9-10,
h y d r o l y s i s o f ( 5 4 ) is a l s o r e p o r t e d i n t h i s p a p e r . The tetraoxahydrospirophosphorane ( 5 7 ) h a s b e e n i s o l a t e d i n
66% y i e l d f r o m t h e r e a c t i o n of ( 5 5 ) w i t h t r i e t h y l a r n m o n i u m p e r f l u o r opinacolate (56).
H e x a f l u o r o a c e t o n e i n s e r t s i n t o t h e P-H b o n d of
( 5 7 ) t o f o r m ( 5 8 ) w h i c h may a l s o b e o b t a i n e d f r o m ( 5 9 ) as s h o w n ' l . T h e 'H a n d "F
n.1n.r.
s p e c t r a of t h e p h o s p h o r a n e s r e v e a l r a p i d
pseudorotati.ona1 processes and a time-averaged f l a t t e n e d c h a i r f o r t h e six-membered
conformation o f a
rings.
In a r e l a t e d paper, r e a c t i o n of(60a) with (56) gave t h e h y d r o s p i r o p h o s p h o r a n e ( 6 1 ) w hi c h upon ~ 1 . v . i r r a d i a t i o n i n t h e p r e s e n c e o f d i m e t h y l d i s u l p h i d e gave t h e m e t h y l t h i o d e r i v a t i v e ( 6 2 ) which w a s also prepared b y t h e r e a c t i o n of(60b) with hexafluoroI n c o n t r a s t , t h e reaction of (63) w i t h h e x a f l u o r o a c e t o n e f u r n i s h e d a i : l m i x t u r e of t h e 1,,3,2-l5- and 1,3.4-A5dioxapllospholanes (64) and ( 6 5 ) . F u r t h e r i n v e s t i g a t i o n s f o r t h e r a d i c a l i s o m e r i s a t i o n of hydros p i r o p h o s p h o r a n e s h a v e shown t h a t o n h e a t i n g w i t h d i - t - b u t y l p e r o x i d e i n benzene, phosphoranes ( 6 6 ) and ( 6 7 ) are t r a n s f o r m e d The p r o p o s e d mechanism, as
i n t o (68) and (69) respectively".
w r i t t e n for ( 6 7 ) , p r o c e e d s t h r o u g h t h e phospho ra n y l r a d i c a l ( 7 0 ) which r e a r r a n g e s t o (71) which i n t u r n reacts w i t h ( 6 7 ) t o form
(69) and ( 7 0 ; i n t h e propagation s t e p . T h e f i r s t p h o s p h o r a n e (74) w i t h a ; , " - p h o s p h o r u s - s i l i c o n h a s been prepared ( a l b e i t
bond
i n l o w , 2 0 ' R o , y i e l d ) by t h e r e a c t i o n o f
( 7 2 ) w i t h bis(trimethylsily1)magnesium
(73)44.
I t h a s a n un-
u s u a l l y h i g h p h o s p h o r u s c h e m i c a l s h i f t b u t n o &-ray
d a t a a r e , as
yet, available. An e x t e n s i v e p a p e r by B u r g a d a
5 g.
reports the reactions
of c y c l i c p h o s p h i t e s ( 7 5 a b ) a n d c y c l i c p h o s p h o r a m i d i t e s ( 7 6 a b ) w i t h trans-1,2-dibenzoylethene, m e t h y l f u m a r a t e , b e n z a l a c e t o n e (PhCH=CH C O M e ) , methyl-4-keto-pent-2-enoate (MeCO.CH=CH.CO2Mej a n d b e n z a l a c e t o p h e n o n e (PhCH=CHCOPh)L5. ylids
( s7. 7)
or spirophosphoranes
These r e a c t i o n s l e a d t o
(e.g. 78
a b ) a n d i n some
70
OrganophosphorusChemistry
(83)
P-OMe
(85)X=Me,Ph
+
Me
(86)
- xyxx Y
(85) X=Me, Ph
Me0
Me
O
(84)Y=H,Me
x
(87)
R
( 8 9 a-d 1
( 88a- d 1
a ) R = PrjO ; R‘=Pri b ) R = Pr’O ; R’= But c ) R =Pr’NH,R‘= P r ’
d ) R = Bu‘NH ,R‘= But
(Et0)2PNHC,H,X
(X=pNO,, H , p -Me)
(90)
+
(92) 6”PJX=pNO2= + 3 . 8 , - 2 9 . 8
71
2: Pentaco-ordinated and Hexaco-ordinatedCompounds
(92)
(93)
6 31 P, X = H ,+ 137. 2 , - 27.9 b3'P, X=pMe,+135.0,-32.0
Et,N
PhCH=NSiMe3
+
- NCH,Ph
(91) 31
( 94)
(9616 P=-25.9
NzCHPh
( 9 5 ) 631P,- 24.7,-28.6
Organophosphorus Chemistry
72
(97)
CL
I
tx2
( 106)
tx2
R = CH F2C F2C H
[
( R0)2P-N=C=0
]
P=N,
I
c-0
I
CN
,c=o
]
2: Pentaco-ordinatedand Hexaco-ordinated Compounds
73
cases t h e s p i r o p h o s p h o r a n e s u n d e r g o r i n g e x p a n s i o n t o g e n e r a t e spirophosphoranes of type (79).
-
S e v e r a l new s p i r o p h o s p h o r a n e s ( e . g . 82) h a v e b e e n d e r i v e d f r o m a f u r t h e r s t u d y o f t h e r e a c t i o n s o f p h o s p h i t e s ( e . g . 80) w i t h i s a t i n (81)46. The compounds were c h a r a c t e r i s e d by a n a l y s i s , i . r . and 31P n . m . r . s p e c t r a and t h e c o u r s e and rates o f r e a c t i o n depend s u b s t a n t i a l l y o n t h e s t e r i c a n d e l e c t r o n i c e f f e c t s of t h e s u b s t i t u e n t s on phosphorus. Two s e r i e s of p h o s p h o r a n e s ( 8 6 o r 8 7 ) c o n t a i n i n g a d i o x a p h o s pholene r i n g and a 2-phospholene s y n t h e s i s e d from t r i c o - o r d i n a t e 1,2-dicarbonyl by a n a l y s i s ,
or 3-phospholene
r i n g have been
p h o s p h o l e n e s (83) o r (84) a n d
compounds ( 8 5 ) 4 7 . The compounds were c h a r a c t e r i s e d a n d , i n c o n t r a s t t o e a r l i e r work$8
IH and j l P n . m . r .
were f o u n d t o b e s t a b l e t o w a r d s t h e r e t r o d i e n e f r a g m e n t a t i o n . The r e a c t i o n of o n e e q u i v a l e n t o f d i a c e t y l w i t h t h e a z a d i p h o s p h e t i d i n e s (88 a-d) gave t h e corresponding spirophosphoranes (89 a - d ) 4 9 . With t w o e q u i v a l e n t s o f b i a c e t y l , p o l y m e r i c p r o d u c t s were f o r m e d a n d i t w a s n o t e d t h a t (89 a , b ) h a d j l P n . m . r . s i g n a l s a t -24 a n d -32 p . p . m . r e s p e c t i v e l y , w h e r e a s ( 8 9 c , d ) h a d j l P n . m . r . s i g n a l s a t about + 20 p.p.m. The r e a c t i o n of p h o s p h o r a m i d i t e s ( 9 0 ) w i t h t h e c h l o r o p h o s p h o r a n e s ( 9 1 ) p r o d u c e d t h e n o v e l i m i d o p h o s p h a t e s (92) c o n t a i n i n g b o t h t e t r a c o - o r d i n a t e and p e n t a c o - o r d i n a t e
p h o s p h o r ~ s ~ ~ P. h o s -
p h o r o t r o p i c m i g r a t i o n t o f o r m (93) o c c u r s f o r X
=
H o r Me.
The s y n a n d a n t i f o r m s of b e n z y l i d e n e a m i n o p h o s p h o r a n e s (95) h a v e b e e n p r e p a r e d b y r e a c t i o n of N-trimethylsilylbenzaldimines ( 9 4 ) w i t h ( 9 1 ) a n d r e a c t i o n of (95) w i t h d i e t h y l a m i n e g a v e ( 9 6 ) 5 1 . T h e same r e a c t i o n w i t h t h e t r i c h l o r o p h o s p h o r a n e ( 9 7 ) h o w e v e r , g a v e t h e d i a z a d i p h o s p h e t i d i n e (100) v i a ( 9 8 ) a n d ( 9 9 ) . D i a z a d i p h o s p h e t i d i n e s ( 1 0 6 ) o r ( 1 0 7 ) are a l s o p r o d u c e d b y t h e r e a c t i o n o f bis(2,2,3,3-tetrafluoropropyl)phosphoroisocyanatidite (101) w i t h e i t h e r b e n z o y l c y a n i d e (102) o r c h l o r a l ( 1 0 3 ) r e s p e c t i v e -
lp2.
The mechanism, as shown f o r t h e f o r m a t i o n o f ( 1 0 6 ) , p r e s -
umably i n v o l v e s t h e u n s t a b l e b e t a i n e ( 1 0 4 ) a n d t h e c y c l i c i m i n o y l i d (105). An i n t e r e s t i n g r e a c t i o n b e t w e e n 2,4,6-tri-t-butylphenylphosphine (108) and d i e t h y l a z o d i c a r b o x y l a t e (109) r e s u l t s i n t h e formation of t h e di-imidophosphorane
(l12)53.
The a u t h o r s p r o p o s e
(110) a n d ( 1 1 1 ) a s i n t e r m e d i a t e s i n t h i s r e a c t i o n a n d r e p o r t t h a t thermal decomposition of (112) l e a d s f i r s t t o t h e diazadiphospheti d i n e ( 1 1 3 ) a n d t h e n , a f t e r s e v e r a l h o u r s a t IlOOC, t o (114).
Organophosphorus Chemistry
74
(98)
+
____,
CI3CCHO
(103)
ArPH,
+
6NC0, E t Ar , P NC0,Et
EtO2CN=NCO2Et
Ar=
-)-@
,NCO,Et
(1091
ArP,
(110)
I
NC02Et (111)
CO,
Et
2 (112)
/
(114) Z= C02Et
C02Et I
CO2Et (113)
63’P,+57.2, + 4 2 . 6
2: Pentaco-ordinatedand Hexaco-ordinatedCompounds
75
0 MeN'NMe \ /
MeN,
Ph3P
/ P-N3 \
N2
+
MeNKNMe 0
,NMe P- N=PPh,
/ \
MeNHNMe 0
(115)
(116)
0
0
K
K
MeN
NMe MeN, ,NMe
p \-' / \ MeNKNMe
MeN
i
\
NMe / P-Cl
/ \
0-P MeNyNMe /\
0
0
+
MeN\ /NMe P-OSi Me3 / \
MeNKNMe 0 MeNKNMe 0 (117)
(118)
0 ( 120)
R2
1
*P-N
R3
R = H , P h , pMeOC,H,, 2 R = H , Ph 3 R = H , Me
Organophosphorus Chemistry
76
( 1 2 2 ) R = H , Me
-P-N
/\
\'
(126) A = BH,, BF,
+ + , CH, ,H
(123) R = H , M e
77
2: Pentaco-ordinated and Hexaco-ordinated Compounds The s p i r o p h o s p h o r a n e ( 1 1 5 ) h a s b e e n f o u n d t o react w i t h triphenylphosphine by a conventional Staudinger r e a c t i o n t o p r o d u c e ( 1 1 6 ) w i t h t h e n o v e l i 5 P-N-;4P
g r o u p i n g ; X-ray
d a t a are
available for t h e latterT4. I n a r e l a t e d s t u d y , t h e r e a c t i o n of (117) w i t h (118) f a i l e d
t o g i v e t h e expected bis-spirophosphorane (119) b u t i n s t e a d gave a n isomer ( 1 2 0 ) w i t h t w o N , N 1 - d i m e t h y l u r e a b r i d g e s a c r o s s a A 5 P-0-
5P bond s y s t e m .
crystal s-ray
T h e p r o d u c t was c h a r a c t e r i s e d b y m . s . ,
and its s t r u c t u r e w a s d e t e r m i n e d by a s i n g l e
i . r . and n.m.r.
diffraction studyc5.
T h e 1 3 C a n d P-C
coupling c o n s t a n t s o f a range of b i c y c l i c -
p h o s p h o r a n e s of t y p e ( 1 2 1 ) - some w i t h c h i r a l p h o s p h o r u s a t o m s , B i c y c l i c p h o s p h o r a n e s of t y p e
have been described i n (122) with R
=
H h a v e b e e n shown t o r e a c t w i t h G r o u p
171
a n d Group
V l l l metal c o m p l e x e s w i t h f o r m a t i o n o f a d d u c t s o f t h e g e n e r i c ligand (123)57.
T h u s r e a c t i o n o f bis(2-methylallylchloro-
p a l l a d i u m ) - ( 1 2 4 ) w i t h t w o e q u i v a l e n t s of ( 1 2 2 , R m o n o n u c l e a r complex ( 1 2 5 ) .
=
Me) g a v e t h e
C a t i o n i c s p e c i e s derived from t h e s e
complexes c a t a l y s e t h e o l i g o m e r i s a t i o n o f b u t a d i e n e t o a f f o r d m a i n l y t r i m e r s a n d tetramers. phosphorus-nitrogen
The c o o r d i n a t i o n c h e m i s t r y o f t h e
e n t i t y is d i s c u s s e d i n a p a p e r b y Riess5* which
p o i n t s o u t t h a t n i t r o g e n atoms a p i c a l l y b o n d e d t o f i v e - c o o r d i n a t e d , formally pentavalent phosphorus atoms, d i s p l a y d e f i n i t e b a s i c i t y . S t r u c t u r e s o f t y p e (126) and (127) are i n c l u d e d i n t h e d i s c u s s i o n . Finally i n t h i s section,
a s e r i e s o f n e u t r a l a n d c a t i o n i c 10-
P-5 s p e c i e s ( 1 2 9 - 1 3 1 ) h a v e b e e n o b t a i n e d f r o m t h e r e a c t i o n of ( 1 2 8 ) BF3 a n d E t 3 S i + ) 5 q . w i t h L e w i s a c i d s (3.
5.
H e x a c o - o r d i n a t e d P h o s p h o r u s Compounds. - T h e r e a c t i o n of PCL5
w i t h alkylammonium f l u o r i d e s i n t h e p r e s e n c e o f s e c o n d a r y a m i n e s g i v e s PF5-amine
adducts (132)6G.
The a d d i t i o n a l p r e s e n c e o f
a l c o h o l s o r phenols l e a d s t o t h e formation of alkoxy- or aroxypentaf l u o r o p h o s p h a t e s , ROPF5-.
T h e PF5-amine
a d d u c t s may a l s o b e
c o n v e r t e d i n t o ROPF5- b y t r e a t m e n t w i t h a l c o h o l s o r i n t o ArNHPF5by treatment with primary arylamines.
An n . m . r . s t u d y of t h e p e r m u t a t i o n a l i s o m e r i s a t i o n s w i t h i n a series of a m i d i u m f l u o r o p h o s p h a t e s ( 1 3 3 ) h a s r e v e a l e d a n i r r e g u l a r m e c h a n i s m w i t h d i s s o c i a t i o n of t h e P-N a n d a l s o t h e P-0 b o n d s o f t h e b i d e n t a t e l i g a n d s a n d t h e f o r m a t i o n of f i v e - c o o r d i n a t e i n t e r mediates (134)61.
Reversible i n t r a m o l e c u l a r m i g r a t i o n s o f pentaco-
o r d i n a t e p h o s p h o r u s i n t h e N-C-N
-
t r i a d of amidines ( e . g .
135,
136,
1 3 7 ) were s t u d i e d f o r t h e f i r s t t i m e i n t h e s e s y s t e m s .
In a r e l a t e d p a p e r , t h e permutational i s om e r is a tio n s of N,N-
78
Organophosphorus Chemistry
(129) O3'P, -18.1
0
?SiEt3
II
(128)
(130)
63'P, -18.7
631P,-6.6
E t,S<
+
,
Si Et
0
( 131)
63'P, - 25.6
2: Pen taco-ordinated and Hexaco- ordinated Cornpou n ds
+
PCI,
13 / 3 H N E t 2
5/3Et3N.3HF
79
+
PF.HNEt2 5
5/3Et36Hfi
+ 1013 Et2NH2CI
(132) Me
I
R3
It
R2
Me
(133)
R ’ = Ph , CF,
(134)
,CCI,
;
R1: Ph ; R2=Me ; R 3 = F ; R d = Ph
R 2 = Me, E t , Pri , B u ’; R 3 = F , Ph ; RG= F , Ph ; R3-
RL= 0
I
Me \
R*N-
0
I
F
R*NMe
F,I
F
N-P
;)\Ph
M/e
NMe
LF \ IF Ph
(137)
R = CF3 or CCI,
J
Me
80
Organophosphorus Chemistry
Me
(139)
(140)
2: Pen taco-ordinated and Hexaco - ordinated Compounds
81
di alky 1 ami din ium - b 1s (, 2-;3 hen y len e d i ox a ) p h o s p h a t e s ( 138) were examined by dynamic n.m.r.6'.
T h e phosphates exist in equilib-
rium with t h e phosphoranes (139 and 1 4 0 ) and the position of t h e equilibrium depends upon the nature of t h e substituents in t h e
N-C-N triad, the polarity of the solvents used and t h e temperature. In this system. permutational isomerisation within (138) again o c c u r s uicr a dissociative mechanism but involving opening of t h e dioxaphospholene ring at the P-0 bond with formation of squarepyramidal intermediates. References --__
1 2 3 4 5 6
7 8 9 10
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
-.
P o l e z h a e v a and R.A. Cherkasov, Chem. Rev., 1Y85, 54, 1126. Timokhin, Russ. Chem. Rev., 1 9 8 5 , 54, 1201. M.F.A. Dove and D . B . Sowerby, C o o r d i n a t i o n Chem. R e v . , 1 9 8 5 , 66, 290. W.H. S t e v e n s o n 111, S . Wilson, J . C . M a r t i n , and W.B. Farnham, J . Am. Chem. S O C . , 1 9 8 5 , 6340. R.J.P. C o r r i u , M. Mazhar, M. P o i r i e r , and G. Royo, J . Organornet. Chem., 1986, 306, C5-C9. A . Boudin, G. C e r v e a u , C . C h u i t , R..J.P. C o r r i u , and C.Reye, Angew. Chem., Lnt. Ed. E n g l . , 1 9 8 6 , 25, 473. A. Boudin, G . C e r v e a u , C . C h u i t , R . J . P . C o r r i u , and C . Reye, Angew. Chem., I n t . Ed. E n g l . , 1 9 8 6 , 25, 474. O.S. Morschheuser and H. P. L a t s c h a , Z an.ogr. a l l g . Chem., 1 9 8 5 , 525, 29. D . H . R . B a r t o n , N . Y . B h a t n a g a r , J . - P . F i n e t , and W.B. M o t h e r w e l l , T e t r a h e d r o n , 1 9 8 6 , 42, 3111. G.-V. R o s c h e n t h a l e r , R. Bohlen, and D . Schomburg, Z . N a t u r f o r s c h . , 1985, 40b, 1 5 9 3 . V. Dana, 3. Bord6, L . H . V a l e n t i n , and A . V a l e n t i n , J . Mol. S p e c t r o s c . , 42. 1985, I&, R.S. McDowell and A . S r r e i t w e i s e r J r . , J . Am. Chem. S O C . , 1 9 8 5 , 107,5849. S. T r i p p e t t , P u r e Appl. Chem., 1 9 7 4 , 40, 595. P.B. Kay and S . T r i p p e t t , J . €hem. R e s . , ( 3 , 1 9 8 6 , 6 2 . S . A . Bone, S. T r i p p e t t , a n d P . J . W h i t t l e , J . Chem. S O C . , P e r k i n 1, 1 9 7 7 , 437. L . H . Koole, W i l . J.M. van d e r H o f s t a d , and H . M . Buck, J . Org. Chem., 1 9 8 5 , 50, 4383. V.Ya. S e m e n i i , V . A . S t e p a n o v , N . V . L g n a t ' e v , G . G . F u r i n , and L.M. 1 9 8 5 , 55, 2415. Y a g u p o l ' s k i i , J . Gen. Chem., USSR , E n g l . t r a n s l . , J . S v a r a and E. F l u c k , Z . a n o r g . a l l g . Chem., 1 9 8 5 , 529, 1 3 7 . D. B. Denney, D. Z. Denney, a n d J . J . G i g a n t i n o , J . Org. Chem. , 1 9 8 4 , 2831 and p a p e r s q u o t e d t h e r e i n . P. L. Robinson, C . N . B a r r y , J . W. K e l l y , a n d S . A . Evans J r . , J. Am. Chem. __ SOC., 1 9 8 5 , 5210. P.L. Robinson, J . W . K e l l y , a n d S.A. Evans J r . , P h o s p h o r u s S u l f u r , 1 9 8 6 , 26, 1 5 . J . W . K e l l y , P.L. Robinson, and S . A . Evans J r . , J . Org. Chem., 1 9 8 5 , 50, 5007. N . Lowther and C . D . H a l l , J . Chem. SOC., Chem. Commun., 1 9 8 5 , 1303. B.E. Maryanoff and A . B . R e i t z , P h o s p h o r u s S u l f u r , 1 9 8 6 , 167. B.E. Maryanoff a n d A.B. R e i t z , T e t r a h e d r o n L e t t . , 1 9 8 5 , 2, 4587. S.M. C a i r n s and W.E. McEwen, T e t r a h e d r o n L e t t . , 1986, 1541. H. K i s c h k e l and G.-V. Rtjschenthaler, Phosphorus S u l f u r , 1986, 371. R. Burgada, Y . O . E l Khoshnieh, and Y . L e r o u x , T e t r a h e d r o n , 1 9 8 5 , 41, 1207. R. Burgada, Y . O . E l Khoshnieh, and Y. Leroux, T e t r a h e d r o n , 1 9 8 5 , 41, 1 2 2 3 . D . E l Manouni, Y. L e r o u x , and R. Burgada, T e t r a h e d r o n , 1 9 8 6 , 2435. k1.A. B.V.
107,
2,
107,
27, 27,
27,
42,
82 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50
51 52 53 54
55 56 57 58 59 60 61 62
OrganophosphorusChemistry A. Skowronska, J , B u r s k i , E . Krawczyk, and M . P a k u l s k i , Phosphorus S u l f u r , 1986, 27, 119. R. Kluger and G . R . J . T h a t c h e r , J . Am. Chem. SOC., 1985, 107, 6006. R. Kluger and G . R . J . T h a t c h e r , J . Org. Chem., 1986, 51, 207. K . T a i r a , T . Fanni, and D . G . G o r e n s t e i n , J . Am. Chem. SOC., 1984, 106, 1521. W. M. Abdou and M.R. Mahran, Phosphorus S u l f u r , 1986, 26, 119. M. von I t s z t e i n and I . D . J e n k i n s , J . Chem. S o t . , P e r k i n 1, 1986, 437. J . Gloede, B. C o s t i s e l l a , and H . G r o s s , Z . anorg. a l l g . Chem., 1986, 535, 221. G.H. McGall and R.A. McClelland, J . Am. Chem. SOC., 1985, 107,5198. R.A. McClelland, G . H . McGall, and G . P a t e l , J . Am. Chem. SOC., 1985, 107, 5204. R.A. McClelland, D.A. Cramn, and G.H. McGall, J . Am. Chem. SOC., 1986, 108, 2416. R. Bohlen, H. H a c k l i n , J . Heine, W. Offermann, and G.-V. R t i s c h e n t h a l e r , Phosphorus S u l f u r , 1986, 27, 321. R. Bohlen, J . Heine, W . Kuhn, W . Offermann, J . S t e l t e n , G . V . Rtischenthaler, and W.G. Bentrude, Phosphorus S u l f u r , 1986, 27, 313. F.M. Akhmetkhanova, L . Z . R o l ' n i k , E . V . Pastushenko, M.V. P r o s k u r n i n a , S.S. Z l o t - s k i i , and D.L. Rakhmankulov, J . Gen. Chem., USSR (Engl. t r a n s l . ) 1985, 55, 1810. U.Starke, L . Rijsch, and R . Schmutzler, Phosphorus S u l f u r , 1986, 27, 297. D.E1. Manouni, Y . Leroux,and R. Burgada, Phosphorus S u l f u r , 1985, 25, 319. Kh. I. R i s s a l u , V.V. V a s i l ' e v , and B . I . I o n i n , J . Gen. Chem. USSR,(Engl. t r a n s l . ) 1985, 55, 1986. B. A. Arbuzov, A.O. V i z e l ' , L . I . Shchukina, O.V. Vakulenko, T.A. Zyablikova, V.K. Krupnov, and L . I . Zyryanova, J . Gen. Chem. USSR, (Engl. t r a n s l . ) 1985, 55, 1514. P . J . Hammond, J . R . Lloyd,and C . D . H a l l , Phosphorus S u l f u r , 1981, 10,47. E.A. Monin, Z.S. Novikova, M.M. Kabachnik, A . I . Lutsenko, and I . F . Lutsenko, J . G e n . Chem. USSR, ( E n g l . t r a n s l . ) , 1985, 2327. S.K. Tupchienko, T.N. Dudchenko, and A . D . S i n i t s a , J . Gen. Chem. USSR, (Engl. t r a n s l . ) , 1985, 55, 1063. L . I . Nesterova and A.D. S i n i t s a , J . Gen. Chem. USSR, (Engl. t r a n s l . ) , 1985, 55, 2333. I . V . Konovalova, L.A. Burnaeva, E.K. Khusnutdinova, G . S . Khafizova, and A.N. Pudovik, J . Gen. Chem. USSR (Engl. t r a n s l . ) , 1985, 55, 1943. J . Naveck and M. Revel, T e t r a h e d r o n L e t t . , 1986, 27, 2863. D. Schomburg, U. Wermuth, and R. Schmutzler, Phosphorus S u l f u r , 1986, 26, 193. D. Schomburg, U. Wermuth, and R. S c h m u t z l e r , Z . N a t u r f o r s c h , 1986, 207. J . M . A . A l - R a w i , N . Ayed, and F.H. Osman, Magn. Resonance i n Chem., 1986, 24, 263. S . Agbossou, M.C. Bonnet, and I . T a u t c h e n k o , Nouv. J . Chimie, 1985, 9 , 310. J . G , Riess, Phosphorus S u l f u r , 1986, 27, 93. L.E. C a r p e n t e r I1 and J . G . Verkade, J . Am. Chem. SOC., 1985, 107,7084. L . R i e s e 1 and M. Kant, Z . anorg. a l l g . Chem., 1985, 530, 207. V.V. N e g r e b e t s k i i , V . I . Kal'chenko, R.B. Rudyi, and L.M. M a r k o v s k i i , J . Gen. Chem. USSR (Engl. t r a n s l . ) , 1985, 55, 236. V . V . N e g r e b e t s k i i , V . I . Kal'chenko, R.B. Rudyi, and L. N . Markovskii, J . Gen. Chem. USSR ( E n g l . t r a n s l . ! , 1985, 55, 1761.
2,
e,
3
Phosphine Oxides and Related Compounds BY B. J. WALKER
1
Introduction.
Phosphine oxide-based olefin synthesis is being increasingly used a n d is the method of choice in a number of recent syntheses of
natural products and related compounds.
2
Preparation of Acyclic Phosphine Oxides
Bis(trimethylsily1)peroxide
(1) can be used to produce phosphine
oxides stereospecifically from either phosphines (with retention) o r phosphine sulphides (with inversion).
A variety of organoelement
substituted pentadienes, including the phosphine oxides
(2)
and ( 3 ) .
have been prepared by the reaction o f the appropriate organoelement halide with pentadienyllithium.’
The anion of ( 3 ) reacts with
ketones to give trienes and ( 3 ) forms complexes with P d , Fe and Ni.3 Both the mono-(l) and di-(5) phosphine oxides are formed in reactions of sodium glycolates with dimethyl(chloromethy1)phosphine oxides, the proportions of the products depending on the reaction conditions.4
The allene(tetraph0sphine) chalcogenides (6) have been
prepared from the corresponding phosphine.
3
Preparation of Cyclic Phosphine Oxides
Attempts to prepare the oxide (7) of 1.2.3-triphenylphosphirene were unsuccessful, €I although the corresponding sulphide ( 8 ) was prepared
by reaction o f the phosphirene with sulphur and N-methylimidazole. a3
Organophosphorus Chemistty
84
Me,SiOOSi Me, ( 1 )
*
PhP L
Li
L
+
Ph2P
SiMt,
II
0
It
(Ph,P(X 1 I2C=C=C(
Mc2P CH,O ( CH, InO R2
( 6 ) X = 0 , S , Se
( 4 )$ = H ( 5 ) R = CH,P(O)Me,
n
s
P(X)Ph2I2
2-6
Ph
Ph (7)X= 0 (SIX= S
3: Phosphine Oxides and Related Compounds
85
The phosphine oxide (10). the first reported example of a phosphorus analogue of an unsaturated 6-lactam, has been obtained from the complexed phosphine ( 9 ) .
'
Z-Phenylphospholino[ 3,4-d] tropone-2-oxide
(12) has been synthesized using the McCormack reaction of the diene
(11) to generate the basic carbon skeleton (Scheme 1).8
A number of
novel phosphine oxide structures (313) . have been prepared during the synthesis of 1 , 1 , 6 , 6 - t e t r a m e t h y l d i b e n z o [ b , e ] p h o s p h a ~ u l o l ~ d e n e (14) *
9
The compounds (16) and (18) have been obtained by air oxidation of (15) and (17). respectively, and provide the first isolated examples of polycyclophosphine oxides.lo
4
Structure and Physical Aspects
The mechanism of the reaction of dialkylphosphine oxides (19) with carbon tetrachloride has been investigated using 31P n.m.r. spectroscopy."
The reaction pathway is complex, but a key step is
the disproportionation of (19) to give dialkylphosphinic acid and dialkylphosphine, this reaction is catalyzed by acid chlorides which are the initially formed products. In an attempt to estimate the value for the anomeric effect contributing to the axial preference for the diphenylphosphinoyl group in
(20).
the conformational preference of the phosphinoyl
group in a variety of cyclohexyldiphenylphosphine oxides
( 21)12
and
in the oxides (22) and ( ~ 3 have ) ~ been ~ investigated by n.m.r. spectroscopy.
The anomeric effect of 3.74 kcal mol-I obtained is
the largest yet measured.
Consideration of X-ray structural data
for (22) and (20) and a study of solvent effects on the axial-equatorial equilibrium for (20) do not provide a clear picture of why the axial isomer predominates, although a number of different factors are certainly operating. l3 The fluorescence properties of a range of diarylalkylphosphine
86
Organophosphorus Chemistry
I
...
Ill
H
I v
R e a g e n t s : i PhPCL2
Cu ( 1 1 1 s t e a r a t e
, , H'a p C p h 0
Br
hexane ; ii , H20 ; i t i
~
'
Cl
Scheme 1
(13) X = O (14) X = lone pair
'
3; i v~, T F A
87
3: Phosphine Oxides and Related Compounds
But
+
+
I
PBu'
I
But (18)
0
II
+
2 R,PH
R,PH
(191
O* PPh, I
R b i PPh,
Organophosphorus Chemistry
88
oxides have been investigated.l4
These compounds exhibit only weak
fluorescence unless one of the phosphorus substituents is itself fluorescent,and even in these cases (except that of the biphenyl substituent) the quantum yield of fluorescence in the phosphine oxide is less than that of the substituent hydrocarbon.
X-ray
diffraction studies have been reported for the stable 1:l
adduct of triphenylphosphine oxide with pentaf luorophenol15 and for two modifications of triphenylphosphine oxide itself.
Careful
analysis of the latter data indicates that appreciable internal rotations of the phenyl groups occur even in the crystal form.
The
gas-phase basicity of a variety of trialkylphosphine oxides has been investigated both experimentally (by ion cyclotron resonance spectroscopy) and theoreti~a1ly.l~
5
Reactions at Phosphorus
Phosphine oxides are reduced to phosphines in excellent yield under mild conditions by a 3:l mixture of LiA1H4 with CeC13.18
The
reagent is claimed to be far superior to LiAlH4 alone and is especially useful for sterically hindered oxides.
Unfortunately the
one optically active phosphine oxide investigated gave a predominantly racemic product.
The addition of sodium borohydride
to the LiA1H4-CeC13 reagent provided a convenient synthesis of phosphine bOKaneS ( 2 4 ) from the corresponding phosphine oxides. The 1-hydroxyalkylphosphine oxides (25) and (26) have been obtained by reaction of diphenylphosphine oxide with diacetyl and ethyl pyruvate, respectively.2 o
Even in the presence of excess phosphine
oxide,addition to the second carbonyl group of diacetyl does not occur. Interest in p-rr bonded phosphorus continues and studies involving phosphine oxides include the dimerization of the
89
3: Phosphine Oxides and Related Compounds
0
Ph-
II
LIAIHL, NaBH4,
I
CeCI3
P -R2
R’
0
*
YH3
Ph-P-R
2
i
R’
0
It
IJ
Ph2PC( 0 H 1 COO H Me
Ph,PC( OH )COMe Me
R\ 2 ,,P=C-PR2R3
R
0
II
-
(27)
0
s+p//s
Organophosphorus Chemistry
90
phosphaalkyne (27) to give (29).21
The stcucture of (29) was
confirmed by X--ray crystallography and its formation obviously involves P-P oxygen transfer (probably via (28)) rather than simple The chemistry of the sterically-stabilized dithiometaphosphonate analogue (30) has been reported.22 dimerization.
6
Reactions at the Side-Chain
The chemistry and synthetic applications of phosphono carbanions have been reviewed.23 The [4+2]-cycloaddition reactions of thioxo-(31, X = S ) and seleno-(31, X=Se) phospholes with triazolindiones and maleic anhydride derivatives have been i n v e ~ t i g a t e d . ~The ~ presence of water in the reactions with triazolindiones leads to the exclusive formation of phosphine oxide adducts from both (31, X = S ) and (31, x=se).
Thermolysis of the adducts (32) and photolysis of the
adducts (33) leads to [4+l]-cycloreversion in each case to give, respectively, PhP=S and PhP=Se as shown by alcohol-trapping reactions.
The cycloaddition of 2-azaallyl anions (e.9. 34) to
diphenylvinylphosphine oxide to give, e.g. (35) and (36) has been ~eported.'~ Intramolecular reaction of the carbene (37) (generated from the corresponding diazoalkane) gives mainly the cyclooctatetraene ( 3 8 ) together with a small amount of the semibullvalene (39). 26
Phosphine tellurides are readily methylated
at the tellurium atom to give the cations ( 4 0 ) . which form phosphine and dimethyltelluride on treatment with methyllithi~m.'~ The extensive use synthesis continues.
of phosphine oxide carbanions in alkene
Full details of stereoselective routes to the
erthro- and threo-2-hydroxyalkylphosphine oxide precursors of alkenes, their conversion to the corresponding
(z)-
and (E)-alkenes
and explanations of the stereoselectivities have appeared. 28 Similarly,'a full report of the synthesis of ( E ) - and
91
3: Phosphine Oxides and Related Compounds
Ph
p//
Se
0
It
Me
PPh,
(33)
PhQPh
0
II
+
Ph,PCH=CH,
e-
ph
Li..A N Ph
(34)
(35)
H
+
o II
yPPh
Ph
NCH,Ph H
+ .C'
(37)
PPh,
It
0
92
Organophosphorus Chemistry
(g)-y,h-unsaturated ketals (41) using this method has been published.29
A
potentially general route to (Z)-unsaturated
carboxylic acids is provided by the highly stereoselective reaction of ethyldiphenylphosphine oxide anion with cyclohexene oxide to give (42) almost exclusively.30
Oxidation of the ketone (43) followed by
Baeyer-Villiger rearrangement gave the lactone (44) regioselectively, hydrolysis of which gave the acid (45) directly (Scheme 2).
All four racemic diastereomers of the substituted
3-alkyl-4-hydroxybutenes ( L g . 47) have been prepared by decomposition of the appropriate 2-hydroxyalkylphosphine oxide diastereomer ( L g . 46).31
New routes are available to
(E)-homoallylic alcohols (50). y-hydroxyketones (52) and cyclopropylketones (53) from the key phosphine oxide intermediate (48) .32
Reduction of (48) to the 2-hydroxyalkylphosphine oxide ( 4 9 )
followed by base treatment gives (50). with base gives (51)
Direct treatment of (48)
Ph2P(0) transfer from carbon to oxygen
followed by formation of either (52) o r (53) depending on the reaction conditions (Scheme 3 ) .
The route involving reduction of
2-ketoalkylphosphine oxides has also been used to synthesise the (E)-alkene (54) .33
During this investigation the sensitivity of the
stereochemistry of reduction (and hence of the olefin formed) to the nature of the reducing agent was noted.
The intermediates (55)
(erythro, leading to (g)-alkene) and (57) (threo, leading to (E)-alkene) are respectively generated selectively by direct reaction of alkyldiphenylphosphine oxide anion with aldehydes and by reduction of 2-ketoalkylphosphine oxides (56). 34
The reduction
route to threo-(57) is frequently more stereoselective than the direct route to erythro-(55).
Warren has now shown that replacement
of the diphenylphosphinyl group by dibenzophosphole in the 2-ketoalkylphosphine oxides allows highly stereoselective generation of erythro-2-hydroxyalkylphosphine oxides by reduction of (58) with
93
3: Phosphine Oxides and Related Compounds
Me1
R3P=Te
+
-
I
R3P-TeMe
(40)
H
0
II
Ph,PCH,CH,
-+ H'
Me
Me
(L2I
(43)
H
Me
(44)
Reagents:
i
BuLi ;
i i J
00 j
i i i , NaOCl A c O H ;
Scheme 2
IV
RCOOOH
Organophosphorus Chemistry
94
(46)
(48)
I
(47)
(491
(50)
... Ill
(52)
(51)
oc
Reagents:
i , NaBH,& , M e O H ; i i , N a H , T H F ; i i i , K O R ; i v , K O H , H 2 0 , E t O H ; v , B u t O K , B ~ ~ O H
Scheme 3
95
3: Phosphine Oxides and Related Compounds
NaBH4-CeC13,as well as generation of the threo-isomer through the use of borohydride alone.
A
convenient alternative and
stereospecific route to diastereomeric 2-hydroxyalkylphosphine oxides is available from the reaction o f diphenylphosphide with each pure isomer of the appropriate epoxide followed by oxidation. Unfortunately in many cases base-catalyzed decomposition of the pure erythro-phosphine oxide leads not to pure (Z)-alkene, but to a mixture with (E)-alkene probably due to equillibration of ervthro& with threo-phosphine oxide y (59).
dissociation to aldehyde and anion
It is now reported35 that the similar decomposition of
ervthro-2-hydroxyalkylphosphine oxide ( 6 0 ) . derived from dibenzophosphole, is much more stereoselective and the use of DBU in dimethyl sulphoxide solution as the base gives an excellent yield of >99% (Z)-stilbene; presumably because the "small-ring" effect
increases the rate of oxaphosphetan formation to the extent that reversion to aldehyde cannot compete. Phosphine oxide-based olefination has been increasingly used as a synthetic method.
The phosphine oxide ( 6 2 ) . required f o r a
synthesis of B-milbemycin (64). has been prepared as a mixture of isomers by an SN2' reaction of the lactone ( 6 1 ) with diphenylphosphide anion followed by oxidation. 3 6
of the olefination reaction of ( E J - ( 6 2 ) ,
An investigation
under a variety of
conditions,revealed that the required (E)-stereochemistry and highest yield were provided by generation of the anion using NaN(TMS)2
followed by reaction with aldehyde ( 6 3 ) (Scheme 4).
A
milbemycin-avermectin hybrid has been synthesized by coupling the intact northern segment ( 6 5 ) with a southern segment using phosphine oxide-based olef ination, followed by cyclization. 3 7
cis-crotyldiphenylphosphine oxide
The anion o f
( 6 6 ) has been used to introduce
the (B,Z)-diene system stereospecifically in synthesis of the
goldinonolactone fragment ( 6 7 ) of the elfamycin
antibiotic^.^^
The
Organophosphorus Chemistry
96
Ar
OMe
Me
0
0
'"Y
0
II
II
R'
HOAR2
(55)
0
11
Ph
4-Ph
ph2p+
-' H
(56)
(57)
0
0
II-
Ph2PCHPh
11
+
PhCHO
Ph
-oA-
Ph2P\fiH H Ph
3: Phosphine Oxides and Related Compounds
97
aYH p”/o
HO
,P h
4--
DEU
Me2S0
Ph
H
%
0
II
Ph,PCH,
+
Me
(61)
OMe
(Z)-isomer
(62)
OH (64)
Reagents :
I,
Ph2P-;
11,
H202;
III
, CH2N2 ; I V , NaN(TMS13 ; v ,
d
t ,cycliration
v
CHO
OTBS
(63)
Scheme 4
Organophosphorus Chemistry
98
-
OT BS
0 Me-CH
,b’,h,
0 It -
Ph,PCHOMe
Me
&
ZH { 0 Me)2
Me H
99
3: Phosphine Oxides and Related Compounds reaction of the ketone (68) with (methoxymethy1)diphenylphosphine oxide anion is highly stereoselective to give (Z)-alkene (69). 39 25-Ketovitamin D3 has been synthesized by the olefination of (70) with the phosphine oxide anion (71).40
The reactions o f 2-[1,3]dithianyldiphenylphosphine oxide (72) and sulphide (73) anions with carbonyl compounds have been i n ~ e s t i g a t e d . ~The ~ phosphine oxide anions (72) react with both aldehydes and ketones to give alkenes, while phosphine sulphide anions (73) do not react with ketones and give only poor yields of alkenes with aldehydes.
This difference in reactivity is explained
in terms of the oxaphosphetane and thiaphosphetane intermediates involved.
It is worth noting that diarylalkylphosphine imides (74)
can be metallated in a similar way to their phosphine oxide analogues. 42
The anions of (74) can be alkylated regioselectively
at carbon to give (75) (the best yields are obtained in the presence
of N,N,N,'N'-tetramethylenediamine) and react with aryl nitriles to give the enamines (76) which in turn can be hydrolysed to the B-ketophosphine oxides' (77) (Scheme 5).
7
Phosphine Oxide Complexes and Extractants
Platinum complexes
(Lg.
78) containing diphenylphosphine oxide
ligands are reported to be effective as hydroformulation catalysts.43
Unlike their 0, S and Se analogues,transition metal
complexes of phosphine tellurides are unknown.
The photolysis of
the chromium group metal hexacarbonyls in the presence of phosphine tellurides is reported to give (79) as the first examples of these complexes,44 The cycloadditions of oxetanes with isocyanates to give oxazin-2-ones (80) are catalyzed by the tin halide-phosphine oxide complex ( 8 1 ) .45
Th.e synthesis of
(82),
a new type of uranium
100
OrganophosphorusChemistry
O* PPh,
1
(72) X = O (73) x - s
(751
(7 7) R e a g e n t s : i, L D A , T H F J - 3 O 0 C ; i i J R 2 X , - 7 O 0 C ; i i i , A r C N , - 7 O 0 C ; i v , H O ; 2
Scheme 5
v , H30+
101
3: Phosphine Oxides and Related Compounds
,o-P
’
Ph Ph PLO,
*
\ /
Ph2
M(CO),
+
I
Et
R,P=Te
% M(CO)S(R3PTel (79)
MrCr,Mo,W;
R=But
PYR
Bu2Sn12. Ph,PO
O ~ N R ’
(81 1
0 (801
UI,(
Ph ,PO l2 (821
Organophosphorus Chemistry
102
tetraiodide complex, has been reported.46 REFERENCES 1. L. Wozniak, J. Kowalski, and J. Chojnowski, Tetrahedron Lett., 1985, 26, 4965. 2. T. Kauffmann and K7R. Gaydoul, Tetrahedron Lett., 1985, 2 6 , 4065. T. Kauffmann and K-rR. Gaydoul, Tetrahedron Letr., 1985, 26, 3. 4071. S. Varbanov, 1. Dencheva, G. Nedecheva, and G. Borisov, 4. Phosphorus Sulfur, 1985, 25, 307. 5. H. Schmidbaur and T. Pollock, Angew. Chem., Int. Ed. EnRl., 1986, 25, 348. A. Marinetti and F. Mathey. J. Am. Chem. SOC., 1985, 107, 4700. 6. 7. A. Marinetti, J. Fischer, and F. Hathey, J. Am. Chem. SOC., 1985, 107, 5001. 8. H. Kato, S. Nomura, H. Kobayashi, and T. Hiwa, Chem. Lett., 1986, 281. 9. C.H. Chen, J.J. Doney, J.L. Fox, and H.R. Luss, J. OrR. Chem., 1985, S O , 2914. 10. M. Baudler, M. Hichels, H. Pieroth, and J. Hahn, Angew. Chem., Int. Ed. Engl., 1986, 471. 11. G. Aksnes and P. Majewski, Phosphorus Sulfur, 1986, 26, 261. 12. E. Juaristi, 8.A. L%pez-Ni%ez, R.S. Glass, A. Petson, R.O. Hutchins, and J.P. Stercho, J. O w . Chem., 1986, 5 l , 1357. 13. E. Juaristi, L. Valle, B.A. Valenzuela, and H.A. Aguilar, JAm. Chem. SOC., 1986, 108, 2000. 14. J. Bourson and L. Oliveros, Phosphorus Sulfur, 1986, 26, 75. 15. T. Gramstad, S. Husebye, and K. Maartmann-Hoe, Acta Chem. 26. Scand., 1986, 16. C.P. Brook, W.B. Schweizer, and J.D. Dunitz, J. Am. Chem. SOC., 1985, 107. 6964. 17. J.C. Bollinger, R. Houriet, C.W. Kern, D. Perret, J. Weber, and T. Yvernault, J. Am. Chem. Soc., 1985, 107, 5352. 18. T. Imamoto, T. Takeyama, and T. Kusumoto, Chem. Lett., 1985, 1491. 19. T. Imamoto, T. Kusumoto, N. Suzuki, and K. Sato, J. Am. Chem. 1985, 107, 5301. 20 * J.A. Mukroyannidis, Phosphorus Sulfur , 1985, 2 5 , 39. 21 * H. Keller, G. Maas, and H. Regitz, Tetrahedron Lett., 1986, 27, 1903. 22 * J. Navech, H. Revel, R. Kraemer, and S. Hathieu, Phosphorus Sulfur, 1986, 26, 83. 23. 2. Liu, Huaxue Shiji, 1985, L, 84 (Chem. Abstr., 1985, 103, 196132). 24. R. Hussong, H. Heydt, and M. Regitz, Phosphorus Sulfur, 1986, 25, 201. Kuffmann, H. Ahlers, KrJ. Echsler, H. Schulz, and HrJ. 25. Tilhard, Chem. Ber., 1985, 118, 4496. 26. M. Bohshar, H. Heydt, and M. Regitz, Tetrahedron, 1986, 4 2 , 1815. 27. 8. Kuhn and H. Schumann, Phosphorus Sulfur, 1986, 26, 199. 28. A.D. Buss and S. Warren, J. Chem. SOC.. Perkin Trans.1, 1985, 2307. 29. C.A. Cornish and S. Warrkn, J. Chem. S O C . , Perkin Trans.1, 1985, 2585. 30. D. Levin and S. Warren, Tetrahedron Lett., 1986, 27, 2265. 31, A.B. HcElroy and S. Warren, Tetrahedron Lett., 1985, 26, 5709. 32. P. Wallace' and S. Warren, Tetrahedron Lett., 1985, 26, 5713.
a,
m.
e.,
3: Phosphine Oxides and Related Compounds 33.
J. Kallmerten and M.D. Wittman, Tetrahedron L e B . , 1986, 22, 2443.
34. 35. 36.
37. 38. 39. 40. 41. 42.
J. Elliot and S. Warren, Tetrahedron Lett., 1986, 27, 645. T.G. Roberts and G. Whitham, J. Chem. SOC., Perkin Trans.1, 1985, 1953. S.R. Schow, J.D. Bloom, A . S . Thompson, K.N. Winzenberg, and A . B . Smith, 111, J. Am. Chem. SOC., 1986, 108. 2662. A . B . Smith, 111 and A . S . Thompson, Tetrahedron Lett., 1985, &, 4283. R.E. Dolle and K.C. Nicolaou, J. Chem. SOC.. Chem. Comun., 1985, 1016. M.P. Bosch, F. Camps, J. Coll, A . Guerro, T. Tatsuoka, and J. Meinwald, J. Org. Chem., 1986, 5 l , 773.
J.L. WascareEas, A. Mouri”n, and L. Castedo, J. Org. Chem.,
1986, 51, 1269. E. Juaristi, B. Gordillo, and L. Valle, Tetrahedron, 1986, 42. 1963. J. Barluenga, F. Lopez, and F. Palacios, J. Chem. Res.(S), 1985, 211; (MI 2541.
P.W.N.M. Van Leeuwen, C.F. Roobeek, R.L. Wife, and J.H.G. Frijns, J. Chem. S a c . . Chem. Cormrmn., 1986, 31. 44. N. Kuhn, H. Schumann, and G. Wolmershauser, J. Chem. SOC., Chem. Comun.. 1985, 1595. 45. A . Baba, I. Shibata, M. Fujiwara, and H. Matsuda, Tetrahedron 1985, 26, 5167. 46. J.G.H. du Preez and B. Zeelie, J. Chem. SOC., Chem. Commun., 43.
m.,
1986, 743.
103
Tervalent Phosphorus Acids BY 0.DAHL
1 Introduction
Useful reviews on areas of relevance for this chapter are one by Cowley and Kemp on the synthesis and reactions of phosphenium ions,1 one by Arbuzov and Dianova on cycloaddition reactions of tervalent P=C, P=N, and P=P compounds,2 and one by Riess on the coordination chemistry of P-N compounds. Proceedings from the 2nd International Conference on Synthetic Oligonucleotides in Molecular Biology, Upp4 sala 1 9 8 5 , have been published. 2 Nucleophilic Reactions 2.1 Attack on Saturated Carbon.- Dialkyl 2-oxoalkanephosphonates (1) and diphenyl-2-oxoalkylphosphine oxides (2), which are useful reactants in Horner-Wittig reactions, are obtained in fair yields by Arbuzov reactions, provided the 0x0 group is protected by conversion to the hydrazone ( 3 ) 4-Chlorophenyloxymethyl ethers (4) are recommended instead of chloromethyl ethers for preparation of diethyl or diphenyl alkoxymethylphosphonates ( 5 ) ; the reactions proceed via phosphonium ions (6) and exchange of the leaving 4-chlorophenolate with the R 2 0 groups is observed at higher temperatures.6 Arbuzov reactions on di(deoxyribonuc1eoside) methyl phosphites (7) have been investigated as a route to dinucleoside alkylphosphonates (8);7 the yields however were low (9-15%). ( 9 ) has been Neopentyl N,N,N’,N’-tetramethylphosphorodiamidite treated with methyl halides to give fairly stable phosphonium salts (10).8 Methyl iodide gave pure (10), but methyl chloride gave a 83:17% mixture of ( 1 0 ) and (11); the formation of (11) indicates that alkylation on nitrogen occurred to some extent with the harder alkylating agent. The iminobisphosphines ( 1 2 ) upon alkylation gave the rearranged products ( 13 ) Quaternization of bis (dialkylamino)I-indolylphosphines (14) with alkyl halides followed by acid hydrolysis gave rearranged indole-3-phosphonic acids ( 1 5) ! Dialkyl (dialkoxymethy1)phosphonites (16) are obtained in fair
.’
.
’’
104
4: TervalentPhosphorus Acids
105
( 1 )R3=OMe,0Et
(3)
( 2)R3=Ph
DMTCl
0,
Meoyp-og2 0-@
(7) Me
I
ROP? NMe,), ROP(NMe,l,
+ MeX
(9) R = (CH,),CCH, X = CI ,B t , I
X-
110)
\
y e 2 ROP-fiMe3+
NMe2
I
ROP-X
X-
+
(11)
Ph2P-NH-PPh,
4- RX
Y
RI +
4 Ph,P=N-PPh,
(12) R X =CF3S03Me or Ph3CfPF6-
(13)
X-
Me3N
Organophosphorus Chemistry
106
+m R2X
CIQ
I N~ P(
'
~
1
R2-
~
(14) 0
H2POR
i ) HC(OR),/
R'=PhCH,
0
II
i)
H2POH
(151
R2= Et, Pr, B u
0
II
H
PI+( NR\),X-
,
"
I )
( ROhPH
II -% (R0)2PCH(OR)2~ROP(CH(OR)2)Z (16)
BF,*Et,O,r.t.
R2=Me,Et
O
D
do
0
(17)
(18)
2 P+(OMe13
Br
+ (Me,SiO),P
Ni2+or N i o 160 - 180
P(O)(OSi Me3$+ Me,SiB
OC
R
R (21)
(20)
e Iec t rochem.
R
oxidation
(221
4: Tervalent Phosphorus Acids
107
yields as shown if the catalyst, boron trifluoride etherate, is removed before isolation; otherwise further reactions with the orthoformate give (1 7) A short and efficient route to 1 -glycosylphosphonates, e.g. (18), has been published. l 2 The phosphonates obtained are predominantly 1 , 2 - ~ - i s o m e r sregardless of either the anomeric configuration of the starting material, or whether it is a pyranose or a furanose. The high stereoselectivity is explained by stabilisation of one of the phosphonium ion intermediates, e.g. (19), by coordination to the neighbouring alkoxy group.
.
2.2 Attack on Unsaturated Carbon.- Several bis(trimethylsily1) arylphosphonates (20) have been prepared by the Ni catalysed coupling of aryl bromides with tris (trimethylsilyl) phosphite (211 . The use of (21) instead of trialkyl phosphites is advantageous when the aryl group contains easily alkylated substituents ( g . R = N H 2 ) . Another route to substituted arylphosphonates (22), g . oxidative phosphorylation of arenes with triethyl phosphite, has been explored. l 4 The products however are usually mixtures of isomers. The reactions of 1,3,2-dioxaphospholans (23)-(26) with five acceptor alkenes (27)-(31), and of trimethyl phosphite, tris(dimethylamino)phosphine, (25) and ( 2 6 ) with three acceptor alkynes (32)( 3 4 ) in the presence of proton donors, have been investigated.15' The products are ylids or phosphoranes. Bis(trimethylsily1oxy)phosphine (35) with acid chlorides gave (36) uhich could be hydrolysed to l-hydroxyalkane-1,l-diphosphonous acid salts (37). Tetrafluoropropanal and dipropyl phosphorochloridite Similarly 1 ,4 ,2-diazaphosgave the 1 ,4,2-dioxaphospholan (38). pholans (39) were obtained from dialkyl phosphoriodidites and imines. Both (38) and (39) are mixtures of diastereoisomers. V-Silylaminophosphines (40) with carbon disulphide gave dipolar com?ounds (41) which did not rearrange to insertion products like other 20 3minophosphine carbon disulphide adducts.
1.3 Attack on Nitrogen, Chalcogen, or Halogen.- The new N-vinyliminoximethoxyphosphorane (42) has been prepared and used for [4+2] 21 :ycloaddition reactions to give 1 ,2-h5-azaphosphorines. Bis(trimethylsily1) peroxide (43) has been recommended as a vers%tile oxidation agent.22 It oxidises 3. phosphorochloridites with :lean retention. Two papers describe reactions of trialkyl phos)bites with dialkyl aroylphosphonates ( 4 4 ) . 23r24 The reactions are .nitiated by attack of the phosphite on carbonyl oxygen to give (451,
Organophosphorus Chemistry
108
0 I g P - x
ti
X-CHZCH-Y
(231 X = OMe (24)X = NMe2
( 2 5 )X = OMe
PhC-CEC-X
(27) X = Y = COPh ( 2 8 ) X = Y = COOMe ( 2 9 1 X = Ph,Y=COMe
(261X=NMe2
(32)X = Ph (33) X = COPh
(%)X=COOk
( 3 0 ) X = Ph,Y=COPh ( 3 1 ) X = COMe, Y = COOMe
P(0s i Me,),
HPOONa
I
RCOCI
+
21M5SiO)2PH
I
I
MeONa
+R-C-OSiMe,
I
I * R-C--OH
I
H POONa
P(OSiMe,)2 (35)
( 37)
(36)
C F2CHF2
(38)
R2
q<:3
R’ 2RCH=NR 1 2 4-
(R3OI2PI
2
I
R2/
R’
( 3 9)
Me3Si
Me Si 3
\
/ R
N-PMe,
+
( 4 0 ) R = Me, Me3Si
CS2
*
\
R’
Me
I+
N -P -CS<
1
Me (41)
MeSi
-f+
3 \
R’
fI
N- C-S-PMc,
109
4: Tervalent Phosphorus Acids
Me0
I421
OMe
Me3SiO-OSi Me3 (L3)
A
E-
l 3
- ( R ~ o ) PO
P ( 0)( OR2),
R’
R’ = 2-MeX*
( 5 0 ) X = O , CH2
d (49)
2 ArCHO+
2 RP(OEt12
+ ArCH=CHAr
(52) R = Bu ,CH,P(OEt),
+ 2 RP(O)(OEt),
R P(0)OEt I
I
ArCHOEt
Organophosphorus Chemistry
110
the fate of which depends on the conditions. In the presence of a proton donor (46) is the normal product, although (47) was obtained in one case.23 When 4-nitrobenzoyl chloride is present (48) is obtained, which explains why (44, R1 = 4-N02, R2 = Me) can not be made from 4-nitrobenzoyl chloride and trimethyl phosphite.23 In the ab3 sence of electrophiles (45) eliminates (R OI3PO on heating to give ylids (49) or, with certain aroylphosphonates (45, R1 = 2-Et or 2-Me0) , cyclic phosphonates (50).24 The formation of (50) is strong evidence for the involvement of carbenes (51). Diethyl alkylphosphonites (52) deoxygenate aromatic aldehydes upon heating; only small amounts of the a-ethoxybenzylphosphinate (531, which is analogous to products obtained from trialkyl phosphites and aromatic aldehydes, are formed.25 The kinetics of the reaction of trialkyl phosphites, dialkyl arylphosphonites, alkyl diarylphosphinites, and triarylphosphines with S8 has been studied;26 the effects of structural changes on the rate (Ph2POR > PhP(OR)2 > P ( O R ) 3 > Ph3P) and on the Hammett p values are interpreted with respect to the mechanism. A general method to displace mercapto groups from carbon with clean inversion includes treatment of an in situ generated sulphenyl chloride with tris(dimethylamino)phosphine to give the salt (54) 27 The 1 ,3,2-dioxaphosphorinane (55) reacts stereoselectively with bis(trifluoromethy1) disulphide to give (56).2 8 Unsymmetrical, chiral cystine derivatives (57) and lanthionine derivatives (58) have been prepared using 29 tris(diethy1amino)phosphine as shown. The reaction of diethyl methylphosphonite (59) with methyl N-chloroacetimide has been studied.30 Besides the normal Arbuzov product (60) large amounts of dialkyl methylphosphonates ( 6 1 ) and (62) are formed, presumably as a result of initial halogen attack. Whether (60) is formed directly (N-attack) or y & (63) has not yet been clarified. A simple method to prepare N,O,O’-trialkyl phosphoramidates (64) from trialkyl phosphites (65) involves initial chlorination with e.g. C C 1 4 . 31
.
3 ElectroDhilic Reactions
3.1 Preparation.- A full paper has appeared on the preparation of three primary aminophosphines (66) and some metal carbonyl complexes. 32 Several new secondary aminophosphines (67) and (68) have been prepared.33 With hydrogen fluoride one amino group is eliminated to give ( 6 9 ) . The synthesis of bis(trimethylsily1oxy)phosphine (bis(trimethylsilyl) hypophosphite)(70) has been improved, and many of
4: TervalentPhosphorus Acids
111
to/ 0
OMe
'P'
-k
CF3SSCF3
to;(? +
0
(561
(55)
NHCOOC H,P h
HsYcooB N HCOOB U*
B~OOCNH
NHCOO CH ?Ph
B~OOCNH
II
7 MeP(OEtI2
+ CI-N=C,
yMe
\
/
I
?t
OEt
I+
McP -CI
I
OEt (63)
J. II
MeP(OEt)2 (61)
0
4-
II
MeP(OMe)(OEt) (62)
Me
N=c\OMe OEt (60)
OMe
(59)
0
MeSCF,
SCF3
"=.:"'I OMe
OrganophosphorusChemistry
112
RN , PH,
= Pr',N,
( 6 6 ) R,N
R'( Me3Si1N
\
R' R~N,
PH
F\
PH
t/
Bu
R N:' 2
1
Cy,N
R ' = B " ~ R,=H ,
R' 0 ,
RO
'
(Me,SiO),PH
( 6 9 ) R = But, ( Me,Si I2N
( 6 8 ) R'=R2= Pr'
(671 R =Mc3Si, R = E t JP r i R1=Buf , R2=p,i
PH
PH
Me,S i0 / (70)
(RS),PH
N R ,', (72 1
(71)
0 II
( 731
NH:
-k
2 Mc3SiNEt2
+
R'(Me3Si)N-P=NR2
+
(Me,Si)2Hg
+
RO-
P-0I
PH
R'
ROP(0Si Me,),
R'( Me,Si I N R? Me3Si )N
\
/
P-
(75)
R'
R'
-k R' 1
Ph3SiLi
__+
I
R'
( 7 6)
SiMc,
4: Tervalent Phosphorus Acids
113
its reactions studied.3 4 Mixed secondary alkoxy (trimethylsilyloxy)phosphines (71) ,35 alkoxy (dialkylamino)phosphines (72),35 and di(alkylthio)phosphines (73) 36 have been prepared and characterised. Alkyl bis (trimethylsilyl) phosphites (74) are easily purified when prepared from hexamethyldisilazane or trimethylsilyldiethylamine instead of trimethylsilyl chloride.3 7 New aminophosphines containing P-silyl groups, (75) 38 and (76)139 have been prepared as shown. A series of alkyl phosphorodiamidites (77) has been prepared using standard methods. Their potential as coupling reagents in oligonucleotide svnthesis was hampered by their propensity to rearrange to (78) unless R1 or R2 was bulky; a mechanism for the rearrangement is proposed!’ Dichlorophenylphosphine and isopropylamine gave a mixture of (79) and (80); the latter is formed mainly as the meso-isomer which could be obtained pure by recrystallisation.41 Some benzyl- and (trimethylsilylmethy1)aminophosphines (81) have been prepared and reactions of the ambient anions (82) towards electrophiles studied.4 2 Chlorosilanes reacted exclusively at carbon, whereas halophosphines gave products derived from attack at either center. The tris(ch1orophosphine) (83), which is obtained as a byproduct from a synthesis of methylenebis(dichlorophosphine), was used to prepare the tridentate ligand (84). 4 3 Phosphinites (85) have been prepared from phosphonites (86) in up to 95% diastereomeric excess when R2 is bulky.4 4 Chlorodialkylphosphines with aminodialkylphosphines, in the presence of butyllithium, give diphosphine imides (87) initially, but these rearrange to iminobisphosphines (88) unless R 3 is an electron acceptor (3. Me3Si) 45 (Diethylamino)divinylphosphine (89) has been used for preparation of Il4-diphosphorinanes (90)-(92).46
.
Indole-3-thiol (93) reacts with diethyl phosphorochloridite or ethyl N,N,N’,N’-tetraethylphosphorodiamidite at both N and S . 4 7 From the temperature dependence of the ratio between (94) and (95) it was estimated that the barrier for N attack is about 3 3 kJmol-I higher than that for S attack. Mercaptoacetic ester (96) and phosphorus trichloride gave (97) which on heating cyclised to ( 9 8 ) .48 Thioacetic acid and phosphorus trichloride gave (99) which is surprisingly stable in contrast to the oxygen analogue, and to the thioanhydride ( 100 1 which spontaneously rearrange to ( 101 ) 49 Thioacetamide and
.
diethyl phosphorochloridite gave (102) which decomposed on attempted distillation.50 The thioacetimidoyl group is an excellent leaving group as seen by the easy formation of ( 1 0 3 ) .
114
Organophosphorus Chemistry
0
.+*
R'O-PINR;),
II
R1-
P(NR?$,
(77 1
(78 1
R1= CH,CH,CN R2= E t
EtOH
C I P(CH,PCI,),
, CH MeCH2CN,CMe,CH2CN,CH,CH2S0,Me
, Pri
EtOP(CH,P(OEtI,),
(83)
R ~ M
Ph- P---OR1
(84)
Ph-P---R2
O ' R' 1
(86) R bornyl,
( 8 5 ) R 2 =Pri,
B u t , Cy
ment hy I R:PCI
+
R:PNHR3
Bu L i
R:P-PR2*
R\P-N-PR22
T *
I
II
N (87) Et2N-P
F
k
(89)
H
(93)
+
H2P-SiMe3
AIB N
R3 (88)
'R3
Et2N-P
n
up-
!jiMe3
(90)
115
4: Tervalent Phosphorus Acids
+
PCI,
HSCH2COOEt
-+ CI,P-SCH,COOEt
a
Cl-P
s o II II
0
II
-I- 3 CH,COSH
PCI,
(CH3C- S-),P
Ph,P-
S - C C H 3 e Ph,P-CCH, r.t.
(991
NH
+
(EtO),PCI
CH,CSNH,
(101)
(100) S
n
11
+ (EtO),P-S-CCH,
II
+ CH,CN
(EtO),PH
(1021
4-
(EtO),P-X
CH,CSNH,
( 1 0 3 ) X = NEt,
I
OEt ,CI R2
CI
NHR,
CL
1 1
R-P-CH2-P-R
1
(104) R’ = Pr Ph
1
+ 4RzNH2+R1-
I
NHR*
I
I
P-CH2-
P-
R’
A’NH~CI-
, Pr’O I
I
PhZNH
Ph,N---P,
N ,P7NPh2 N
/ \
I
I
Rk;
R2
P-OR~
H
Ph
Ph (106)
1
/ \
(105)
Ph
N a m p ( )P-cI N
N R -PVP-R 1
(108) R ’ , R ~H , ~ e
(1071
R3=E t ,Ph 7x2
cJ;>p-x (109) X = C I OR, S R j NR2
&,i\ H
(112) X = C I (113) X = NEt,
(110) X Z O ,
s
I px2
( 1 1 1 ) X=CI,OEt ,NEt,
X (114) x = C I (115) X = N E t 2
(116) X = O E t , OBu, NEt2
116
Organophosphorus Chemistry
A number of methylenebis(aminophosphines) (104) have been prepared.” These can be isolated by distillation if amine hydrochlorides are removed; otherwise they cyclise to 1,2,4-azadiphosphetans (105). A synthesis of (105, R1 = C 1 ) has also appeared.52 The =-I ,3,2,4diazadiphosphetan (106) with diphenylamine gave trans-(107); both structures were proven by X-ray ~rystallography.~~ A full paper has been published on the preparation and properties of 1,3,2-diazaphosphorinanes ( 108) unsubstituted at the nitrogen atoms.54 Several benzo-I ,3,2-oxathiaphospholens (109) ,55 benzo-I ,3 ,2-oxa (thia)azaphospholens ( 1 10),56 and benzo-I ,3,2-diazaphospholens ( 1 1 1 ) 57 have been prepared, and (111, X = NEt 2 characterised by X-ray crystallography.58 Anthranilic acid, or salicyl amide , with phosphorus trichloride gave the benzo-I ,3,2-oxazaphosphorinanes (112) 59 or (114), 6 0 respectively. Both were converted to the amides (1 13) or (115) with diethylamine. Similar reactions with 2-hydroxyacetophenone gave the benzo-I ,3,2-dioxaphosphorinanes ( 1 1 6) . The expected product from 3-acetylpentan-2,4-dione and alkyl phosphorodichloridites (1 17) was unstable and rearranged to (118).62 From 3,3-dichloropentan-2,4-dione and phosphorus trichloride the stable If3,2-dioxa63 phosphorinane (119) was obtained. Diethyl phosphoroazolides (1201, which are reactive phosphitylating reagents, have been prepared in high yields by the method shown.64 A new route to glycosyl phosphates begins with phosphitylation of a carbohydrate, e.g. (1211, with 2-cyanoethyl diisopropylphosphoramidochloridite ( 122) .65 The product gives phosphites with. alcohols and phosphates after mild oxidation and hydrolysis. A similar phosphoramidochloridite (123) has been used to obtain (124) which are useful precursors €or glycerophospholipid analogues, 3 . ( 125) 6 6 Crosslinked polyacryl amide has been treated with dialkyl phosphorchloridites and the resulting N-acyl phosphoramidites used 67 as condensing agents for peptide synthesis.
.
3.2 Mechanistic Studies.- The kinetics and mechanism of alcoholysis of some cyclic phosphoramidites (126)-(129) has been studied in detail.68 In general, the reactions were first order in phosphoramidite, alcohol, and catalyst up to at least 40% conversion, but the kinetics was complicated by (assumed) association of the reactants in unpolar solvents. The stereochemistry found for uncatalysed reactions was predominantly retention, but since isomerisation of both phosphoramidite and phosphite was observed a conclusion on the stereochemistry of the actual substitution step could not be drawn.
117
4: Tervalent Phosphorus Acids
(119)
/
+
/
CI-P,
OCH,CH,C N
OC H,CH ,CN
B
N Pr‘, RO
RO (1211 R = PhCH,
(122)
R’O
+
0Me
/
CI-P,
.
NPr‘,
OH
R’O
+R
, OMe
’ O I
.
s 11
0-P-OR
0-P,
NPr’,
-1
0
(123)
(125)
[ 1241
R’
R’
(126) R1=R2=H,R 3 = E t 1
2
3
2
3
(127) R = M e , R = H , R = E t
(120) R’=Me, R = H , R =Ph 1
2
3
(129) R = H , R : M e , R = E t
2
OrganophosphorusChemistry
118
+ Et2NH;
>P-NEt2
>P-NEt2*H2NEt: k-1
+
>P-NEt;H2NEt:
MeOH
-% k
+ MeCOOH
>P-NEt2
+ Et2NH 4-
>P-OMe
Et2NH:
>P-OCOMe
+
>P-OMe+
MeCOOH
Et2NH
k-1
I- MeOH
>P-OCOMe
-%
Scheme 1
+
R~P? I
2 R N :
R2=Mc E t ,Bu
R1: Me E t
DMTou DMToPB 1
0.
0,
'P-N-CH2-@
I
MeO'
MeO'
Et
+
I
vN
HX
+
(RIS),PX
R2,NH
X=OR,SR
(133)
+
,NZN
(132)
(131)
(R1S),PNR2,
EtSP(NEt2I2
P-N
\o/
ZnC12
-+
Et-bP(NEt,),
I 1
EtSCH2C?OP(NEt,),
C H2CH20-
(134)
(135)
(136)
RS02CH2CH20- P
NC'
PhS02CH2CH20-P
.0
NMc2
" i 0
W
(137) R=Me Pri I But PhCH,, L-O,NC,H,CH, j Ph
c1 ,
" " ' O V
( 1381
O\ P-NR22
R' SO,CH,C
3 0 '
( 139)
4: Tervalent Phosphorus Acids
119
The reactions were catalysed by acids (amine hydrochlorides or LiC1). The “mechanisms” propoacetic acid) but not by anions (3. sed are given in Scheme 1 . The function of the acidic catalyst in alcoholysis reactions of phosphoramidites has not been elucidated yet, but low reactivity of a series of alkylphosphinylenebis(trialky1ammonium) iodides (130) towards water and alcohols 69 points against protonation at nitrogen as the way of activation. Tetrazole has been shown not to act solely as a proton donor when used as a catalyst for nucleoside phosphoramidite couplings.7 0 This follows from experiments with polyrnersupported nucleoside phosphoramidites (1311, from which compounds fully activated for reaction with nucleosides are liberated upon treatment of (131) with a solution of tetrazole in acetonitrile. Whether the active compounds are nucleoside phosphortetrazolides (132) or subsequent products was not clarified. Dithiophosphoramidites (133) react with alcohols, phenol, or R2N is a alkanethiols by displacement of the amino group,7 1 better leaving group than RS in these systems. Similar compounds, 3. (1341, react with ethylene oxide, catalysed by zinc chloride, (136), to give (135). 7 2 The reaction probably proceeds R2S+ is a better leaving group than R 2 N .
e.
e.
3.3 Use for Nucleotide Synthesis.- Several new tervalent phosphorus reagents have been proposed to introduce phosphorus at 3’- or 5’-OH groups in nucleosides These ipclude the 2-sulphonylethyl phosphoramidochloridites ( 1 37) 73 and ( 1 38) ,7 4 which gave deoxyribonucleoside-3’ phosphoramidites (139) containing O-alkyl groups easily removable after DNA synthesis by B-elimination; di(2,2,2-trifluoroethyl) trimethylsilyl phosphite ( 140) , which gave high yields of deoxyribonucleoside-3’ phosphates (141); and dialkyl diisopropylphosphoramidites (142), 7 6 which were used as the last cycle reagents in automated DNA synthesis to give 5’-phosphorylated oligonucleotides. Diisopropylphosphorodichloridite (143) has been applied for the preparation of several deoxyribonucleotide-3’ phosphoramidites (144), including N and S analogues.7 7 In a similar approach, tetraisopropylphosphorodiamidochloridite (145) was used to obtain deoxyribonucleoside-3’ phosphoramidites ( 1 4 6 ) 7 8 To prepare deoxyribonucleoside-3 hydrogenphosphonates (1471, which are promising alternatives to phosphoramidites for DNA synthesis,79 the reagents (148) and (149) ,80 or (150),81 may be profitably used. A new reagent, ( 1 5 1 1 , has been used to prepare deoxyribonucleoside-3’phosphoramidites ( 146 , R = CM2CH2CN) in situ;82 the solutions of
.
’’
.
120
Organophosphorus Chemistry
DMTopB
(CF3Ct$O),P-OSiMc,
i)(l&o)/Py
ii) peracid iii)Et3N / H20
(140)
OH
R'O
0, CF~CH~O'
,
40
P
'0 -
(141 1
,P-NPrI2 RO (I4 21
R' = ~ ec H , ~ H,C C N
c H,CH,
No2
R'= CH~CH'CN CH,CH~--@~,
+ Pr',NPCl,
+
D M T O ~ T D M T O ~ T
B
~ ~
D M T DMTO-,@
I
(143)
O
~
~
I
OH
cl/PO\
Rxy
DMTov
NPrip
,O
P-NR'2 RX' I1441 R X Z MeO, NCCH,CH,O ,CCl3CH20 CC13CMc20,PhCH20, 2-Cl-C,HLOJ P h S , PhNH
(Pr',N),PCI (145)
+
Et N
.
I
0 -PIN Pr ;),
OH
p 2 0 r o l e
DMToPB
+
,0 ,PNPr', RO (146) R =CH2CH2CN CH?CH=CHZ CH2-C6HL- 2 NO2
-
OCOPh
4: TervalentPhosphorus Acids
121
0- P(NEt,),
NCCH2CH20P(NPrip)2 I
ar4
I
\
\ 1311
,O
I
Oib Oib
OR
NCCH,C%O-P,
(153) i b =PriCO
NPr',
(152) R
C H T CHCH2OP( NMe, 1,
0
, ButMezSi
MMTold bSi ButMe2 (155)
B = T , AbZ
Organophosphorus Chemistry
122
(146) were applied successfully on an automated DNA synthesizer. The same reagent was used to prepare ribonucleoside-3’phosphoramidites’ (152, R = 2-tetrahydropyranyl) 83 for RNA synthesis on silica supports, and (152, R = t-butyldimethylsilyl) and (153) for assemblage of a branched tetraribonucleotide 84 Another alkyl phosphorodiamidits (154) has been introduced to prepare dinucleoside allyl phosphates (155);85 the allyl group is easily removed by catalytic amounts of Pd(Ph3PI4 and a nucleophile, e.g. butylamine. An elegant route to synthesise RNA oligomers on solid supports, which obliviates the need to protect and deprotect the 5‘-OH groups of the ribonucleoside monomers, has been briefly described.83 The procedure is outlined in Scheme 2. Ribonucleoside-3’phosphoramidites (156) have been prepared from methyl phosphoramidochloridites (157) and used for automated synthesis of oligoribonucleotides on a controlled pore glass support.86 The phosphoramidites (156, R = Pri) gave coupling efficiencies of up to 98%. The chloridite (157, R = Pri) has also been used to prepare (158) and (159) which were applied in the first synthesis of branched triribonucleotides.87 Polystyrene-supported deoxyribonucleoside-3’ phosphoramidites (160), or analogous compounds bound to the support via a piperazine linkage, have been used in a three-phase synthesis of oligonucleotides. 7 0 An activated nucleoside derivative, presumably (1 61 ) , is liberated upon treatment of (160) with tetrazole in acetonitrile, giving high coupling yields in standard polymer-supported DNA synthesis. Several groups have used dinucleoside-3’ phosphoramidites as building blocks for synthesis of oligodeoxyribonucleotides.88-90 In one case the dimer used contained l80 on the phosphate in a known configuration,89 in another case the use of dimers allowed synthesis of a 101-mer in a 15% overall yield (DMT efficiency).9 0 A triribonucleoside 2-5A core analogue has been synthesised using 2,2,2-trichloroethyl phosphorodichloridite. Modifications of guanine bases by nucleoside phosphoramidites are shown to occur during solid phase synthesis of oligonucleotides.92 This is claimed to cause very low yields of oligonucleotides if they contain a large number of guanine bases. In a study of the relative yields of the components in synthesis of mixed sequence oligonucleotides it was observed that deoxyribonucleoside-3’ phosphoramidites containing 2-cyanoethyl groups were more stable in solution than their methyl protected counterparts.93
.
123
4: Tervalent Phosphorus Acids
cat.
" - O V ' OH OR
O ,
OR
.
MeO-P,
N Pr '2
@wold' . .
1 2 / H20 f
"-"V' Me0
-
O,
OR
p'oYiB2
OH OR
OH
OR
Scheme 2 MeO,
"".OV O,
MeO-
R;NAp-oYl
OSiButMe2
P,
NR2
.
(156) NR,= NPr',, N
W0 M M1
Pr ;N
-Po, ,
P - N Pr I2 OMC MtO'
"""VB McO' (160 1
0,
DMTo
I
Et
(161)
OrganophosphorusChemistry
124
+ ( COD 1 P t I
/
/Pt
\
I I
@*
(162)
+ (163)
ii'
-C -Si Me3
( PriN 12P
hv
[( Pr ;N
),Pr C -Sib&,++(
Pr LN),l%-Si
,I
Me
(165) 6, -41
(164)
Xb0
CL
'
I
( Pr;N ),P=C(
Si Me,),
(166)
OPPh,
(168) R = H , M e
I
R3
I
\Ph
(169) R ' = H , Me R2, R 3 = H , PPh,
PPh, (170)
\Ph
125
4: Tervalent Phosphorus Acids
H
2 , [ph-P=S]
ROH
+
I
Ph-PP=S
I OR
(173)
H
5 [Ph-P=Se]
MeOH
+
A
[x-P=S]
0
(179) X = OCHZCCI,,
%Me
\ NM e 2 (177)
I R' (180)
I
OMe
(174)
-
I
Ph-PZSe
OrganophosphorusChemistry
126
3.4 Miscellaneous.- The planar 10-P-3 compound (162) forms a platinum complex (163) in which the ligand is bent (has the normal 8-P-3 structure) 94 A distillable diamino (diazomethyl)phosphine ( 164) upon uv irradiation gave a very unstable intermediate, presumably (165), trimethylsilyl chloride to give which could be trapped with g . (166). 9 5 New tervalent phosphorus ligands for use in asymmetric catalysis reactions are (167) 96 and (168)-(170). 97
.
4 Reactions involving Two-co-ordinate Phosphorus Pyrolysis of ally1 phosphorodichloridite (171) at 1150 K gave phosphoryl chloride (172) which was characterized by mass and matrix infrared spectroscopy.98 Phenylthioxophosphine ( 173) and phenylselenoxyphosphine (174) are probable intermediates in thermolysis of (175) and photolysis of ( 1 76) , resp.9 9 Similar tricyclic compounds (1 77) gave (178) on thermolysis in the presence of 2,3-dimethylbutadieneI probably via the thiophosphenous acid derivatives (179).100 1 review has appeared on cycloaddition reactions of tervalent P=C, P=N, and P=P compounds. Like a-diketones, a-diimines with 1 ,2,4 ,3The aminoiminophostriazaphospholes ( 180) gave phosphoranes ( 18 1 ) phine (182) is alkylated at the three-co-ordinated phosphorus atom by methyl iodide, but at the two-co-ordinated phosphorus atom by more bulky alkyl halides. O2 Aminoiminophosphines have carbene or alkene character depending on the substituents. Thus (183) with hexafluoroacetone gave (1841, but (185) gave (186).'Io3 The results were correlated with the n and 71 ionisation potentials. The first representatives of a 1 ,2-azaphosphole, (1 87), O 4 and a 1 ,2 ,4-thiadiphosphole , ( 1 88) , have been prepared. Phosphenium ion synthesis and reactions have been reviewed. A full paper has appeared on the reactions of phosphenium ions with 1 ,3- and 1,4-dienes. The reactions with 1,3-dienes are stereo(189) with transItrans-2,4-hexadiene gave only (190), specific, the product expected from a [2+4]cheletropic cycloaddition reaction. With l,$-dienes, 1,5-additionoccursto give, %. ( 1 9 1 ) . Cyclo-octatetraene and the phosphenium ion (192) gave a 9-phosphabarbaralene (193),which undergoesfast Cope rearrangements at room temperature; an 5-ray crystal structure determination shows a nearly symmetrical structure. O7 The stannazene (1 94) with phosphorus trichloride surprisingly gave the dipolar phosphenium stannate (195).108 Two diphosphenes (1 96) , O 9 two phosphaarsenes (197) and a phospha-
.
%.
127
4: Tervalent PhosphorusAcids
+
R~N-PP=N-R' 1
(CF,),CO
f 181)
(183) R'= R2= Me3Si
(185) R'= P r ' , R2= But
Pr;N
- P-NBut
I I 0- C(CF3l2
Me3SiS,
I
R' ( 1 87 1
I
Me (190)
(189) Me N
2 \ +
P
(191)
+
CI'
(192) But
But
I
I PCI,
-t 2 ButN(SnMe3I2 (19L)
C I - P /N-
\
SnMe3
N-SnMe3
I But
*
+
N ,SnMe,CI
/ \ -
P,
N
I
B"+ (195)
Organophosphorus Chemistry
128
J
-LO
(196)E=P, R2N=(Me3SiI2N, (197) E=As,R=Me3Si 6ufMe2Si (1 98) E = S b R = But Me2Si
C;
P-NEt,
Et,N
-P
OC
4: Tervalent Phosphorus Acids
129
stibene 11981 have been prepared by thermal elimination of trimethylsilyl chloride as shown. Even the phosphastibene (198) i s stable "for a long time" at room temperature. The trans-diphosphene (199) reacts with diazomethane to give a thermally stable diphosphirane (200);'I1 diazomethane did not react with the isomeric cisdiphosphene at -78 OC. 5 Miscellaneous Reactions
Polymerisation of 2-diethy1amino-lr3,2-dioxaphosphorinanes (201) and ( 2 0 2 ) t o high molecular weight polyphosphoramidites are initiated by potassium t-butoxide; after hydrolysis and oxidation polyphosphordi112 esters of potential for biological applications are obtained. References
1 A. H. Cowley and R. A. Kemp, Chem. Rev., 1985, 25, 567. Dianova, Phosphorus Sulfur, 1986,
2 B. A . Arbuzov and E. M .
26, 203.
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OrganophosphorusChemistry
130
2 0 D. W. Morton and R. H. Neilson, Phosphorus Sulfur, 1 9 8 5 , 25,, 3 1 5 . 2 1 T. Kobayashi and M. Nitta, Chem. Lett., 1 9 8 5 ,
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4: Tervalent Phosphorus Acids
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4 7 P. A. Gurevich, A. I. Razumov, T. V. Komina, G. Yu. Klimentova, and T. V. Zykova, J. Gen. Chem. USSR, 1 9 8 5 , 55, 1 1 8 7 . 4 8 A . R. Burilov, M. A. Pudovik, L. N. Usmanova, and A. N. Pudovik, J. Gen. Chem. USSR, 1 9 8 5 , E l 2 1 3 4 .
A. Al’fonsov, D. J. Gen. Chem. USSR, 5 0 V. A. Al’fonsov, D. J. Gen. Chem. USSR,
4 9 V.
A. Pudovik, E. S. Batyeva, and A. N. Pudovik, 1 9 8 5 , 55, 8 3 2 ; ibid., 1 9 5 6 . A. Pudovik, E. S. Batyeva, and A. N. Pudovik, 1985,
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6 3 D. M. Malenko, L . A. Repina, and A. D. Sinitsa, J. Gen. Chem. USSR, 1 9 8 5 , 55, 6 2 2 . 6 4 W. Dabkowski, J. Michalski, and Z. Skrzypczyiiski, Phosphorus Sulfur, 1 9 8 6 , 26, 3 2 1 .
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M. K. Grachev, A. R. Bekker, and E. E. Nifant’ev, J. Gen. Chem. USSR, 1 9 8 5 , 55, 2 0 1 6 . 6 9 E. A. Mel’nichuk, A. A. Kisilenko, and N. G. Feshchenko, J. Gen. Chem. U S S R , 1 9 8 5 , 55, 8 9 6 .
Organophosphorus Chemistry
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J. 7 3 C. R. 7 4 N.
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883. 7 5 K. Imai, T. Ito, S. Kondo, and H. Takaku, Nucleosides Nucleotides 1 9 8 5 , 4, 6 6 9 . 7 6 E. Uhlmann and J. Engels, Tetrahedron Lett., 1 9 8 6 , Chemica Scripta, 1 9 8 6 , 26, 2 1 7 . 7 7 T. Tanaka, S. 27, 199.
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Tamatsukuri, and M. Ikehara, Tetrahedron Lett., 1 9 8 6
7 8 J. E. Marugg, A. Burik, M. Tromp, C. A. van der Marel, and J. H. 2271. van Boom, Tetrahedron Lett., 1 9 8 6 ,
27,
27,
7 9 B. C. Froehler and M. D. Matteucci, Tetrahedron Lett., 1 9 8 6 , 469; P. J. Garegg, T. Regberg, J. Stawiiiski, and R. Stromberg, Chemica Scripta, 1 9 8 5 , 280.
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E. Kuyl-Yeheskiely, G. A. van der Marel, and J. H. van Boom, Tetrahedron Lett., 1 9 8 6 , 27, 2 6 6 1 . P. J. Garegg, T. Regberg, J. Stawifiski, and R. Stromberg, Chemica Scripta, 1 9 8 6 , 26, 5 9 . J. Nielsen, J. E. Marugg, M. Taagaard, J. H. van Boom, and 0 . Dahl, Recl. J. R. Neth. Chem. SOC., 1 9 8 6 , 105, 3 3 . M. H. Caruthers, D. Dellinger, K. Prosser, A. D. Barone, J. W. Dubendorff, R. Kierzek, and M. Rosendahl, Chemica Scripta, 1 9 8 6 , 26, 2 5 . R. Kierzek, D. W. Kopp, M. Edmonds, and M. H. Caruthers, Nucleic Acids Res., 1 9 8 6 , 14, 4 7 5 1 . Y. Hayakawa, M. Uchiyama, H. Kato, and R. Noyori, Tetrahedron Lett., 1 9 8 5 , 26, 6 5 0 5 . N. Usman, R. T. Pon, and K. K. Ogilvie, Tetrahedron Lett., 1 9 8 5 ,
8 0 J. E. Marugg, M. Tromp, 81 82 83
84 85 86
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W. Bannwarth, Helv. Chim. Acta, 1 9 8 5 ,
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13,
Zon, K. A. Gallo, C. J. Samson, K.-L. Shao, M. F. Summers, and R. A . Byrd, N u c l e i c Acids Res., 1 9 8 5 , 13, 8 1 8 1 .
9 3 G.
4: Tervalent Phosphorus Acids
133
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2,1 5 3 .
5
Quinquevalent Phosphorus Acids BY
R. S. EDMUNDSON
Aspects of the chemistry of carbohydrate phosphates,' and of phosphonomycin ( cis-3-methy 1-2- oxirany lbhosphonic acid have been reviewed.
1. Phosphoric Acids and their Derivatives 1.1 Synthesis of Phosphoric Acids and their Derivatives.- A detailed study of the kinetics of formation of alkyl phosphorodichloridates and dialkyl phosphorochloridates from P0Cl3 and alcohols has been described in a series of papers.3 Monoalkyl dihydrogen phosphates have been prepared in quite high yield in the apparently facile interaction of alcohols and a reagent prepared from P4Ol0 and he~amethyldisiloxane.~Several cyclic hydrogen phosphates ( 1 ; K = Me, MeO, EtO, C1, or C12) have been synthesized and resolved; the 2-chlorophenyl compound is an effective resolving agent, and its absolute configuration has been deter~nined.~ The cyclic acid (2) and its trimethylsilyl ester have been obtained during a study of the chemistry of 2,2,2-triethoxy-2,2-dihydro-tetrakis~trifluoromethyl~-ly3y2-
dioxaphospholane.6 Enol phosphate esters of types ( 4 ) and ( 5 ) have been prepared by reaction between trialkyl phosphites and (3; R = H or Me). Shikimic acid has been converted into the 5-enol-3-phosphate (6; R = CH2Ph), and thence to the free acid (6;R = OH) by the use of tetrabenzyl pyrophosphate.8 During the course of an examination of the substrate specificity of glycerol kinase, several 3-substituted-propane-ly2-diol1-phosphates were ~ r e p a r e d . ~A general method for the synthesis of glycerophospholipids (Scheme 1 ) employs compounds of tervalent phosphorus in the initial stages;lOthe choice of reagent (v or vi, vii or vi) depends on the protecting group in R2 derived from choline tosylate, N-tritylethanolamine, or 1,2-isopropylide-eglycerol. A second prccedure designed for 134
5: Quinquevalent Phosphorus Acids
135
related compounds (Scheme 2) is based on a condensation achieved by the use of 2,4,6-triisopropylbenzenesulphonyl chloride (TPS-C1) .I1 Methylation of (7; R-H) was employed as a means of purification of the acid since the methyl ester (7;R=Me) could be demethylated readily by NaI. Solution and solid phase techniques have each been used in the synthesis of appropriately N-protected g-phosphoseryl 12 peptides. Trialkyl phosphorotetrathioates are convertible to the phosphorodibromidodi thioates ( 8 1 by the use of PSBr3.l 3 A study of the 1,5-dihydro-7,8-dimethyl-2,4,3-benzodithiaphosphepin derivatives (9 has centred on spectroscopic and X-ray techniques .I4 Bis(trifluoromethy1) disulphide has been shown to react with the phosphite ( 1 0 ) ( and also its phosphorus epimer) in an essentially stereospecific manner giving the thiophosphates (11; a and b) in the ratio 8 9 ~ 1 1 .However, methanolysis of the latter compounds is much less stereospecific; from lla, for example, the yields of (12) and (13) are in the ratio 69:31, and the compounds ( 1 4 ) and ( 1 5 ) are also formed in the ratio73:27.15 The thermally-induced cyclization of (2-haloethyl)phosphoramidothioic esters (16) to give the 1,3,2-thiazaphospholclosely related idines ( 1 7 ) has been reported in fu1l;''some syntheses were reported several years a g o but only in preliminary form. The example illustrated in Scheme 3 is, perhaps, a little more surprising.17 In a new approach to the synthesis of phosphoramidates by the Todd-Atherton reaction, those from the more weakly basic amines, more particularly aromatic amines, have been obtained by reaction between dialkyl hydrogen phosphonates and the N-formyl or N-chloroacetylarylamine in a two-phase system.1 8
1.2. Reactions and Properties of Phosphoric Acids and their Derivatives.-The use of isotope labels, in particular l 8 O , at appropriate sites, as a means of differentiating between alternative mechanisms in phosphorus chemistry, continues to expand. The Appel reaction (between dialkyl hydrogen phosphate and arnine in the presence of Ph3P/CC14) exemplifies such application. The known final products could arise either directly by interaction of a nucleophile and the proposed intermediate
Organophosphorus Chemistry
136
&;, \
Me
R
5
R
(3)
0
a II
0 P(OR21, I
R'
0
\
R'o R'O
slL
vd o r vi
0IIO ,R ,OP,
. S
OP, i , Pr$(MeO)FCi
, Et3N;
2
Scheme 1
'''1 .
:,OR2 OP O 'H
-
R'O7 OR ,2;
OR2
OP\
OMe
i i , R 2OH, tetrazole;
i v y S8 ; v , PhSH ( o r EtSH) , Me3N
R'o
OMe
v i i or V I.
,I Reagents:
OMe
OH
i i i , Me3COOH ;
; v i , MeCOOH ; v i i ,
Me3 N
5: Quinquevalent Phosphorus Acids
137
R'O
I
Me0
I
OR3
OH (71 2
1
R = palmitoyl or oleoyl ; R = palmitoyl ReagenTs: i , T E - C l
;
ii, CH2N2
Scheme
2
i
RSPBr, S
( 8 )
A
X
(12) X = OMe ; Y = = O (13) X - = O ; Y =OMe
OAr
(14) A = = O (15)P.z F
;
B=F
i B:=O
138
Organophosphorus Chemistry
(18;Scheme 4) or indirectly by initial expulsion of k'h3k'0 and subsequent involvement of a phosphoryl chloride. The model compounds examined were based on the 4-methyl-1,3,2-dioxaphosphorinane system. The =-and trans-2-hydroxy 2-18U-oxides ( 1 91 were separately converted into the diastereoisomeric anilides (2U). No evidence was forthcoming to suggest the participation of an initially-formed phosphorochloridate, and evidently the axial oxygen undergoes preponderant reaction (by a factor of 6 6 1 , the reaction proceeding with inversion of configuration through an intermediate probably of type (18).19 Another brief but interesting communication2' outlines a reexamination, based on 180-induced changes in phosphorus chemical shifts, of the reaction between a methyl phosphate ester and a phosphorylchloride to give a pyrophosphate, and which employed models based on the 5,5-dimethyl-1,3,2-dioxaphosphorinane system. Far from being the simple process of phosphoryl attack on phosphorus a s originally envisaged, the complete scrambling of the oxygen label was attributed primarily to the participation of a tricyclic dioxadiphosphetane intermediate ( 2 1 1 , but the presence of: free cyclic phosphoric acid introduced further complications. The kinetics of hydrolysis of 4-nitr0phenyL~~ and 2,4-dinitrophenyl dihydrogen phosphates22 (see also ref. 3 0 1 have been determined. In the hydrolysis of diphenyl 4-nitrophenyl phosphate,replacement of R=H in the tetraco-ordinate zinc complex (22) by R=C16H33 results in the enhancement of the catalytic effect of the complex.2 3 Expulsion of dinitrophenate and formation of monodentate N-bound phosphoramidate in almost quantitative yield is observed when coordinated 2,4-dinitrophenyl pentaaminecobalt( I 1 1 1 is treated with aqueous base. 24 A further test of the stereoelectronic theory ot reactivity of phosphate esters has been attempted using measurements ot the rates of displacement of: 4-nitrophenate from the esters ( 2 3 ) and (241, their phosphorus epimers, and also (251, in aqueous methanol; the introduction of the 4a-Me group into the system would, it was hoped, reduce the the flexibility of the bicyclic structures and so possibly eliminate the participation of twist-boat conformations. The presence of the 4a-Me group has no effect of: the rate of displacement of the axial ArO group
5: Quinquevalent Phosphorus Acids
139
(16)
X = C I or
(17) 2
1
Br ; R = a l k y l ; R = alkyl or CH,CH,X
; Z =alkyl ,alkoxy, or aryloxy
0
II
(Et2N),P-NCH2CH,Br
I
heat
+
-EtBr
Et Scheme 3
(18)
\
- Ph3P0
'
Reagents: i , Ph,P Cclq ; ii, bhki
Scheme 4
i; (19)
(20)
.=
18
0
0
\p4 a'
Organophosphorus Chemistry
140
CI
(211
0
II
R
(23)R = H ( 2 4 ) R = Me 0
(26)
11
R'-
Re (27)
kR+
c p
,.OMe
0-P0
oI'-
-0
- cp/.0-P.
Ib o -
0 Me
ROCH CH OP-0
*
(29)
* I
(30)
Scheme 5
0-
5: Quinquevalent Phosphorus Acids
141
whereas for the (pseudo)equatorial aryloxy groups, the added methyl group reduces the rate of displacement. Each equatorial epimer hydrolyses faster than the corresponding axial compound, and compound (25) hydrolyses at a rate intermediate between those of the equatorial isomers on the one hand, and the axial isomers on the other. Such relative rates of hydrolysis were thought to be consistent with the idea that axial isomers react via chair conformations, whilst the equatorial isomers react via twist-boat conformations with the aryloxy group in the pseudoaxial position. 2 5 The factors involved and mechanistic pathways in the hydrolysis of phosphate esters, particularly those of a cyclic nature, continue to be the source of much speculation. A further study of the simplest cyclic triester, ethylene methyl phosphate, seems only to have served to consolidate already polarized views. The original experiments of Westheimer's group employed H nmr spectroscopy and demonstrated that ethylene methyl gc and ' phosphate (26) hydrolyses under alkaline conditions by processes which include exocyclic bond fission. More recent work by Gorenstein et al. using 31P nmr spectroscopy apparently showed that, consistent with the stereoelectronic theory of phosphate ester reactivity, there was complete endocyclic bond cleavage for solutions of (26) in 5M aqueous alkali. A re-examination of the hydroLysis of ester (261, using both ' H and 31P nmr techniques, now confi-rms that exocyclic cleavage to give MeOH and ethylene hydrogen phosphate does indeed occur, and that che extent of that process increases with higher concentrations of base (Scheme 5: R=H, O=O=160). In addition, the - methyl 2-hydroxyethyl product of initial ring opening,viz hydrogen phosphate, hydrolyses too slowly to account for the amount of methanol liberated in the early stages of the hydrolysis of (26).26 The mechanism outlined in the Scheme requires that direct ring opening of the initial pentaco-ordinate intermediate ('27328) competes with proton ( R - H ) removal (27--)29) prior to pseudorotation. The minimal amount of exocyclic cleavage product produced in dilute base indicates that ring opening is faster than pseudorotation. As the concentration of base is increased, the rate of proton removal increases relative to that of ring opening.
142
OrganophosphorusChemistry
The results of additional experiments using D20 containing D2I80 are also conveniently incorporated into Scheme 5 (R=D; O= 160, 0= 18O).27 Using conditions as close as possible to those employed by Goren scein et al., Kluger et al-showed that only one equivalent of base DO- was incorporated during exocyclic cleavage; in spite of kinetics indicating second order dependence on base, the lack of incorporation of a second equivalent of base suggests that it is probably used simply for proton removal in the stage (27+29). Since 2-hydroxyethyl dihydrogen phosphate (30) triply labelled with isotopic oxygen is also not formed, it seems unlikely that hexaco-ordinate intermediates are not involved in the hydrolysis of (261, a point over which chere does appear to be agreement. Many mechanistic aspects of the hydrolysis of phosphate esters in protic media remain uncertain. In spite of predictions that racemization at phosphorus should be the final outcome if indeed the (hypothetical)metaphosphate intermediate is involved in the solvolysis of monoesters, Che results of several studies on the methanolysis of appropriately 0-isotopically labelled compounds are consistent with reactions proceeding with inversion o f configuration, as observed for all enzymic and non-enzymic systems so far examined; this has resulted in the suggestion that if metaphosphate is actually formed, then it must be in a 'masked' form. In the quest for 'free' metaphosphate, racemization has been observed for phosphoryl transfer from phenyl dihydrogen ( E l - [ 160,170,180]-phosphate to tert-butyl alcohol in MeCN. 28 The solvolysis of isotopically-chiral (S)-adenosine-5'-diphosphate (31) by inter alia tert-butyl alcohol a l s o proceeds with racemization.29 However,the preassociation of metaphosphate with solvent molecules and multiple transfers with other solvent molecules before entrapment by the alcohol has been advanced as an alternative explanation for the racemization observed. Moreover, Ramirez et al. found that the liberation of 2,4-dinitrophenoxide from its monophosphate dianion in aqueous solution is accelerated by pressure, a result not possible to reconcile with the intermediacy of 'free' metaphosphate.30 Other workers have concluded that, for the solvolysis of phosphate monoesters, the bonding between nucleophile and mecaphosphate is not far developed in the transition state and
5: Quinquevalent Phosphorus Acids
143
that the very large rate accelerations observed in enzymecatalysed transfers must depend particularly on the microenvironment:large rate enhancements were found for dipolar aprotic solvents specific for the dianion substrate.31 Compound (32) phosphorylates hindered alcohols in the presence of EtOH consistent with a dissociative mechanism involving a metaphosphate-like intermediate,since it proceeds with considerable racemization at phosphorus(Scheme 6 ) . The extent of phosphoryl transfer which proceeds with retention of configuration is ca. 35% ( i L . ca. 70% racemization); the excess of (SIP configuration would arise from transfer with configurational inversion, and might indicate a relatively 'free' metaphosphate but is also consistent with the preassociative mechanism discussed above. 32 33 The involvement of monomeric metaphosphate in the phosphoryl transfer from phosphate monoesters, and of pentaco-ordinate intermediates from phosphotriesters represent two extremes in the mechanistics of the phosphoryl transfer process. Between the extremes are the ( S N 2 ) p processes involving transition states having various bond orders, but no true intermediates. The conclusion reached from a study of the hydrolysis of j180]-glucose-6-phosphate was that the total bond order izo phosphorus is not conserved in the transition state.34,35 Evidence has appeared suggesting the participation of pentaco-ordinate intermediates in the reaction between phosphorothioic acids (Scheme 7 : RL=Et or Ph) and carbohydrate epoxides. The reactions were followed by 31P nmr spectroscopy and signals were observed corresponding to the 2-alkyl esters (33), the isomeric 9-alkyl esters ( 3 4 ) and also stereoisomeric forms of the 1,3,2-oxathiaphospholane (35), the formation of which was favoured for R1=Ph presumably because of the better leaving character of PhO-, but the equilibrium can be shifted towards (35) by removal of EtOH. Since (35) cannot be the intermediate between (33) and (34), there must be another, and this is purportedly the pentaco-ordinate species which undergoes pseudorotation. 36 In the reaction between nucleotide cyclic 0,0-3',5'-phosphorothioic acids with styrene oxide, oxidation is accompanied by extensive rearrangement of the six-membered ring to the Fsomeric cyclic 2',3'-phosphate.37 An interesting communication concerns an attempt to quantify bond orders in thiophosphoric acids using 34s and 36s-
Organophosphorus Chemistry
144
( 31
S-
0-
I
EtOP-0-P-0
II
0
(32)
I
0 . ~ ~ 0e ,= o 17
, o =18o
-
II 0
yo
MeS
/ \ -
0
EtO
0
0 It
S P(OR’),,
2
0
Scheme 6 R2
0
\
R’O-P-S
I
I\
R’O OH
2
R2CP,0R1 o-p\
I
0R’
OH
11
(33)
R‘
(35)
R2=
F0Y0
1””
(34)
0
O+Me Me
Scheme 7
145
5: Quinquevalent Phosphorus Acids
induced perturbations of "P chemical shifts for the model compounds ( 3 6 ) and (37).38The results have suggested chat che negative charge in the anion of the hvdrolysis product (38) is located on sulphur with the phosphorus-sulphur bond of order 1. This is in agreement with earlier measurements of l 8 O perturbations of 31P chemical shifts in 0-alkyl and O,O-dialkyl phosphorothioates. An X-ray analysis has confirmed the structure of the product ( 3 9 ) formed when 2-aminobenzamiae is heated with P4Sl0 in pyridine (there is no reaction in toluene,. In the presence of alkali, dimethyl sulphate converts ( 3 9 1 into (40; R=SMe) which, in turn, yields ( 4 0 ; R=C H N or PhNH) by reaction with pyrrolidine or aniline. 34 In the synthesis of butenolides substituted in a position adjacent to the carbonyl, the bis(dimethy1amino)phosphinyloxy group has been employed for the direction of an incoming electrophile (Scheme 8).40 Azines have been prepared by initial condensation of diethoxyphosphinylhydrazine anions with aldehydes or ketones (Scheme 9 ) . Phosphoryl azides undergo 1,3-dipolar cycloaddition to 2-tetralone enamines to give triazolines, possibly en rouce to amidines.42 A full paper on the addition of diethyl dibromophosphoramidate to alkenes(1eading to the synthesis of 2-bromoalkylamines) has appeared.4 3
'+'
The phosphorylation of alcohols by CEP-imidazole" (41;X=N)with CEP-ring retention is already well-established. Following from the observation that CEP-pyrrole (41;X=CH) phosphorylates alcohols with CEP-ring opening, an explanation has been advanced based upon the differences in apicophilicities of the pyrrole and imidazole moieties in pentaco-ordinate intermediates (Scheme 10).44 A scale of relative reactivities based upon the reactions in the equations + Azole' , k CEP-Azole2 + Azole 1 CEP-Azole' .t*
-1.
CEP-Azole + TMGH"" 7 --l CEP-TMG + Azole was drawn up for a series of azoles and also for N , N , N I N 1 tetramethylguanidine and its derivative (45).Increased replacement of N by CH leads to decreased reactivity towards both TMGH and other azoles. CEP-pyrrole cannot be prepared from
CEP
.,-.to
cyclic enediol phosphoryl ;
I\
I\
TMGH
=
tetramethylguanidine
Organophosphorus Chemistry
146
(36) X = S , Y = O (37) X = O , Y = S
(38)
H NH
S
R
(39)
(40)
Reagents:
i, BuLi ;
ii, E+
; iii, HCOOH
Scheme 8
Reagents:
i, R1R2C0
; ii, NaH ; iii, R3R4C0
Scheme 9
147
5: Quinquevalent Phosphorus Acids
OR
Scheme 10
'PN
11
Me
\
Scheme 11
NMe,
148
Organophosphorus Chernistry
other CEP-azoles by reaction with pyrrole because the latter is insufficiently nucleophilic, but zhe nucleophilicity of TMGH allows the preparation of CEP-TMG from CEP-azoles; both CEP-pyrrole and CEP-imidazole react with TMGH with complete CEP-ring retention. Such a contrast to the behaviour of CEP-pyrrole and CEP-TMG towards alcohols is explicable assuming that the pyrrole moiety i s apicophobic. In Scheme 11, therefore, for X=CH, (421-4431 and, because the strong basicity of TMGH prevents protonation of ( 4 4 ) the ring-opening reaction cannot be driven to completion. However, the conversion of (44) into (43) with expulsion of TMGH, and hence ultimately into (451, are possible. The lack of reactivity of (45) and CEP-pyrrole towards alcohols is attributed, at least partly, to the double bond character of the phosphorus-nitrogen bond as evidenced by the crystallographically determined abnormally short P-N bond lengths. A problem of a related nature concerns the reactivity of the cyclic diamides (46):marked differences are to be observed in methanolysis between, on the one hand, (46; R=Ph or OPh) and (46;R=MeNH)on the other. In all cases ring opening occurs to some extent although in different ways (Scheme 1 2 ) . 45 F o r (46;R=OPh)ring retention is also observed. The lower reactivity of (46;R=MeNH)is possibly linked to the smaller endocyclic NPN angle (demonstrated by X-ray analysis) and a high degree of coplanarity of the phospholidine ring with possible resonance interactions between endocyclic nitrogens and carbonyl and phosphoryl groups. Both ring opening and ring retention are observed in the interaction of (46;R=PhO)and anisidine, and here reaction occurs at both the phosphoryl and the carbonyl (giving (47)1 groups, whereas with a sterically hindered amine reaction occurs only at a carbonyl group. With a more reactive primary amine, e.g. benzylamine, the initially-formed (48) cyclizes spontaneously to (49). Continuing their studies on analogues and derivatives of cyclophosphamide as agents for cancer therapy, Luaeman et al.have synchesized the phosphoramidates (50 a,b,c; R=Me or Ph) by established methods and have studied their r e a ~ t i v i t y .By ~~ contrast L O aldophosphamide (50a; R = H ) whicn unaergoes tautorrieric cyclization to (51a ; R=H), '4-phenylketophosphamide'. (50a; R-Ph) and to a lesser extent the methyl analogue, are resistent t o t h e change. In aqueous solution the phenyl compound(50a; R=Ph) is converted into the diamide (52) faster
5: Quinquevalent Phosphorus Acids
I49
Me
(47) Me
(46)
(MeO),P(O)NHMe Reagent :
+
( CONHMeI,
i , MeOH
S c h e m e 12
(48)
(49)
R '3
'
H2°2
OPNHR'
I
N R2R3
R'CH=CR
2 ~ ~CH,3 = (53)
+
C I C HR' C R L CR 3CH2P(0)CI
150
Organophosphorus Chemistry
H;)
bH
0 (57)
(56)
(58)
COOR
0 ( R’
II
R2
0
II
I
o i2p-c H - P z
( Me3SiO),P(X)COOR
(60)
0
(61)
0
I
(EtO),!-CHGR’
It
(R0I2P<
‘
X
II
O
( R O ),PCH(OR),
0
OR2
PhCH20-
Met( Me
0
OCH2Ph
5: Quinquevalent Phosphorus Acids
151
(by a faccor of 3 ) thar, (50a; R=Me!. 2.Phosphonic and Phosphinic Acids and their Derivatives 2.1 Synthesis of Phosphonic and Phosphinic Acids and their Derivatives.-The phosphonium adductsfrom PC15 and alkyl vinyl ethers are converted into the corresponding phosphonic dichlorides by hexamethyldisiloxane. 47 Oxidative phosphorylation of the 48 1,3-butadienes ( 5 3 ) affords the phosphonic dichlorides ( 5 4 ) . The reaction between 2-adamantyl halides and PC13/A1Br3 yields a mixture of di-2-adamantylphosphinic chloride and bromide together with (l-adamanyl)(2-adamantyl)phosphinic chloride; 1-adamantyl halides are already known to afford only 1-adamantylphosphonic acid derivatives.49 An Arbuzov reaction between gem-dibromocyclopropanes yields phosphonate esters (553 accompanied by debrominated compounds;successful reaction requires the presence of traces of water !and is thus not the 'normal' Arbuzov reaction) which, 50 by studies with D20, has been shown to supply the a-proton of (56). 'Normal' Arbuzov reactions, using ethyl diphenyl phosphite, have been used to prepare a phosphonate isostere of B-D-arabinose1,5-diphosphate.51 Trimethylsilyl esters of arylphosphonic acids have been prepared by Ni-catalysed Arbuzov reactions between aryl bromides and tris (trimethylsilyl) phosphite.52 NiC12 also catalyses reactions between 2,5-dibromothiophene and phosphonous ( or phosphinous) esters to give the compounds ( 57 1 . 5 3 Pd compounds in the presence of triethylamine catalyse the phosphination of 1-bromoalkenes with alkyl phosphinates to give the esters ( 5 8 ; R 1 ,R2 , R 3=H,Me, or Ph; R4 =Me or Ph; R 5 = Et or B u ) and ~ ~ the phosphonation of iodoaromatics with dialkyl
phosphonates, although in this case with poorer yields (better results of the dialkyl arylphosphonates are obtained by photostimulation). 55 Chemical oxidation (using AgN03-peroxodisulphate) and anodic oxidation of aromatics in the presence of trialkyl phosphites produces dialkyl arylphosphonates in good yields. 56 The CuI-catalysed arylation of dialkyl (cyanomethyl1 phosphonates affords dialkyl (a-cyanobenzyl)phosphonates.57 Several phosphonodicarboxylates (59; R=Et; X=H or Me) and the corresponding acids have been prepared by typical active methylene reactions,during a study of the oxidation of
152
OrganophosphorusChemistry
3-phosphono-3,5,5-trimethylcyclohexanone ,58 and reactions between the lithium complexes of phosphonic esters (R’O) 2P(0)CH2R2 and the chlorides Z2P(0)C1 (Z= EtO, Ph, or Me2N) have given the compounds (60).59 The phosphonoformic esters (61; X=O, S, or Se; R=Me or Et) have been prepared conventionally from bis(trimethylsily1) hypophosphite.60 SnCl4 catalyses the formation of the (a-aryloxybenzyl) phosphonates (62) from diethyl trimethylsilyl phosphite and (dialkoxymethyllaryls.61 In a similar reaction, 2-alkoxy-1 ,3-dioxolanes with ZnC12 yield the phosphonates (63),62 whilst mixtures of trialkyl phosphites or mixed phosphites (Et0I2PR (R= MeCOO or Me3Si0, for example) and orthoformic esters in the presence of BF3.Et20 yield the esters (64). Other reactions using alkoxy-4chlorophenoxymethanes are also catalysed by BF3.Et20, but best results in the synthesis of diethyl or diphenyl (alkoxymethy1)phosphonaces are achieved using TiC14 catalyst at -78OC.This last process presents certain advantages over the more conventional Arbuzov process, not least of which is the mildness of the reaction conditions. A potentially widely applicable procedure, viz. alkoxide displacement on (sulphonyloxymethy1)phosphonates leads to an unusual ring enlargement in the case of the 1,3,2-dioxaphosphorinane (65).63 Two papers describe the hydrophosphonation of unsaturated cyclic hydrocarbons. With dialkyl phosphonates, cycloocta-lY5-diene affords the phosphonate esters (66) but in the presence of strong acids, or when using the moderately strong H2P(0)OH itself, the monocyclic esters (67) are also formed. Cyc1ododeca-ly5,9-triene affords a mixture of polycyclic phosphonate esters of which (681, (691, and ( 7 0 ) have been identified.64 Compound (711 is the initial hydrophosphonation product from the tricyclo[4.2.2.02’5]deca-3,7-diene dicarboxylic ester illustrated, and may be further hydrophosphonated; (71) has been characterised crystallographically.65 The ester (72) (with the OH group appropriately protected) has been transformed into the phosphacyclohexane (75) by way of (73) and (74) by processes of reduction, acidolysis, and peroxide oxidation. Variations of this procedure are also described.66 Improved syntheses of diethyl [ (phenylsulphonyll68 methyl j ~ h o s p h o n a t eand ~ ~ bis (diphenylphosphinic) peroxide have been reported. Bis(2,2,2-trifluoroethyl) hydrogen phosphonate has been synthesized and its use in the synthesis of
5: Quinquevalent Phosphorus Acids
153
03 (66)
(67)
P(O)(OR
PI0 )(OR 12
COOMe COOMe
COOMe
COOMe
0
II
b0
X,PCH,
Of
Me
( 7 2 )X = O E t ( 7 3 )X = H
0 HO@OH
Me
OH
( 7 4 )Y = H (75) Y = O H
154
Organophosphorus Chemistry
phosphoric mono and diesters investigated.69’70 Ths vinylphosphonic esters (77) are obcainable by distillation of the phosphite esters (76)(Scheme 13).71 No reaction takes place at the vinyl halogen during the preparation of the esters (781, but the interaction of phosphonites and 2-chloroacetimidoyl chlorides is accompanied by proton migration. 72 An adaptation of the Arbuzov reaction (Scheme 14) using the hydrazones of 1-chloroalkyl ketones provides a route to dialkyl (2-oxoalkyl)phosphonates (79; R 1=Me, C1CH2, Ph, EtOOCCH2, or 2 73 (EtO)2P(0)CH2; R =H, generally; R3=Me0, EtO). In a paper concerned primarily with the use of epoxyalkylphosphonates in the synthesis of heterocyclic compounds, the (epoxyalky1)phosphonic esters have been obtained, accompanied by (2-oxoalkyl)phosphonic esters (81) in the reaction between the alkenephosphonates ( 8 0 ) and alkaline hydrogen peroxide.74 Where there exists a choLce of double bond capable of being epoxidized, as in the 1,3-butadienephosphonic esters, peroxytrifluoroacetic acid reacts at the double bond distant from the phosphoryl centre;thus (821 gives (831 . 75 Epoxidation of the phosphonates (84) by MCPBA yields mixtures of erythro-and threoproducts (85; R 1 ,R2= H or Me; R3=Me, Et or PhCH2), the reactions for the (Z)-(84) being highly stereospecific. For the phosphinates (84; R 4=alkoxy; R5=aryl), the (Zl-form reacts more selectively than does the (El-form.76 Preparations of a-diazophosphonoacetic acid derivatives have been described. 77 Thus far, ( a-diazoalkyl)phosphonic and -phosphinic acids have been known only as their esters. The phosphinic esters (86; R1=H, Me, Ph, PhCH2, PhCO, and MeOOC; R2=Me0; X=Ph) have now been dealkylated with bromotrimethylsilane to give the compounds (86; R2=Me3SiO) and both the methyl and trimethylsilyl esters react with tert-butylamine to give salts of the free phosphinic acids. A similar sequence furnished salts of the compounds (86; R1 as before; R 2=MeO, Me2N or Et2N) and thence the phosphonic acids (86; R 1=PhCO or MeOOC; R 2= X = O H ) . 78 The threo-formsof the (1,2-dihydroxy-3-oxoalkyl)phosphonates (87)act as useful precursors in the synthesis of a wide variety of other phosphonic acid types (Scheme 1 5 ) . 79 Et2NSF3 is a useful reagent for the low temperature conversion of the (hydroxyalky1)phosphonic esters (88;X=OH;R=allyl, or aryl) and (89.) into the corresponding (fluoroalky1)phosphonic acid esters. 8o
5: Quinquevalent Phosphorus Acids
155
Me 0 .. II I II M e C C H C l C M e __i_) ( RO$POC=CCMe 0
0
II
It
0
.
i
I
Me
(77)
(76) i , (RO)2W:
;
I,,
II
+(R0I2PC=CCICMe
CI Reagents:
0
It
Ill
I
i i i , heat
;
Et3N
Scheme 13
R2
R2
R2 . . ...
II > I l l
'
R'+CI NNHCOOMe
Reagents :
R1+P=":
N N HCOOMe i , R;POR4
;
ii . Me2C0
0 ;
iii , H30'
11
0
(79)
S c h e m e 14
0
0
+ (80)
0
II
(R'O),PCH,COR~
(81)
R
156
OrganophosphorusChemistry
U
0
0
II
II
-
( R~ oi2 PCH~CHCR'
I
OTs
Reagents:
i,
'
\"
Os04, H202 ;
0
II
CN I
I R'O),PCH,CHCR~
II
0
+
(R'O),PCH,
+
(R~O)~PCH=CCR~
0 0
0
ii, TsCl, pyr. ;
0
0
II
II
I
iii, H2-Pd ; iv; BU4NtCN-
v, Eiu4X!+N3S c h e m e 15
OEt
R
R
0
R
OEt
R
5: Quinquevalent Phosphorus Acids
157
Migration of phosphorus €rom oxygen to aromatic carbon is induced by Lithium diisopropylamide and provides a convenient route to esters of (2-hydroxyary1)phosphonic acids (90) and bis ( 2-hydroxyaryl Iphosphinic acids (911 . Interaction of chlorides of tervalent phosphorus and phenols, particularly those in which the hydroxyl group is sterically hindered, leads to 5-phosphorylation, and the products may be oxidized to esters or (4-hydroxyphenyl1phosphonic acids; (&hydroxy-3,5-di-tert-butylphenyl )phosphonic acid was thus prepared.82 ihe reaction between sterically hindered phosphorous chlorides (92; n=O or 1 ) and benzyL alcohol affords the phosphonates ( 9 3 1 .83 The bisphosphonic acid 1 9 4 ) has been prepared and its chelating properties investigated.84 Methylenebisphosphinic acid (95 has been described and its crystal and molecular structure determined. 85 Pd(PPh3j2Ll2 catalyses the internal alkylatjon of the phosphonate esters ( 9 6 ) and the formation of the 3-methyLene-lo x a - 2 - p h o s p h a c y c l o a l k a n e 2-oxides (971, phosphorus-containing analogues of a-methylenelactones ." Further examples of the lY3,2-dioxaphosphorin system (991 have been prepared as indicated with the esters (98) as isolable intermediates.87 The related compounds (100;R-Et or Pri) are obtained by a rearrangement process at room temperature.8 8 Studies described in earlier Reports have shown that the diketone (101; _n=3) reacts with dichloromethylphosphine/acetic acid to give the bicyclic anhydride (102). but such a reaction does not occur with MePC12/A1C13. A new paper now describes reactions of the diketone (101; n = 4 ) with MePC12/CH3COOH. These reagents yield (103). Evidently the acidity of unpurified chloroform is 'sufficient to transform 11031 into the phosphinic acid (104);other reactions are illustrated in Scheme 16. Using the unsaturated ketones (105) and (106!, the bicyclic 1,2-oxaphosphole derivatives (107) and (108',respectively, were obtained; the structure of the latter was confirmed by X-ray analysis. The tautomeric nature of (1081 is evidenced by its reaction with diazomethane to g i v e the methyl ester of the phosphinic acid (109).8 9 The preparation of the 1,3,2,4-dithiadiphosphetane 2,4-disulphides (110; R=Me, Et, Pri, or Ph) has been described. 90 Some new sulphur-containing compounds including the oximino esters (111; isolable as their methyl esters) and the dihydro-
Organophosphorus Chemistry
158
.CI i Me3C
Me3C
R
O
Me
159
5: Quinquevalent Phosphorus Acids
Br 0
(105)
0
Ph
Ph
(103) Reagents:
i , Mepc12, MeCOOH ; ii, k120
iii, Br2
;
iv, E30+
S c h e m e 16
,
0
160
Organophosphorus Chemistry
1,3,2-thiazaphospholes (112) have been obtained from oximes by reaction with 2 , 4 - b i s ( 4 - m e t h o x y p h e n y l ) - 1 , 3 , 2 , 4 - d i t h i a d i p h o s p h etane 2,4-disulphide (Lawesson's reagent;LR). Depending on the nature of R in (1131, it is also possible to prepare the 91 dihydro-1,3,5,2-oxathiazaphospholes (114). Details have appeared of reactions which occur between 2,4,6-tris-tert-butylphenyldithiaphosphorane (115) and MeOH, to give ( 1 1 6 ) , and 2,3-dimethyl-1,3-butadiene, when (117) is formed.92 Scheme (17) illustrates the synthesis of the diphenyl ester (118) of (1-amino-2-propeny1)phosphonic acid (1191, an acid which is a strong inhibitor of the alanine racemases from P-aeruginosa and &faecilis.93 Other aminophosphonic acids prepared by a variety of methods include the compounds (120-1281 94-97 The Arbuzov reaction was employed in the preparation of the"-(phosphonoacety1)-1-aminoalkyl]phosphonic acids (Scheme 18) and the same publication describes the acids (129-131). N-(Phosphonoacety1)-L-aspartic acid is of particular interest since it is a tumour inhibitor active against several transplantable tumours;lung carcinomas and melanomas are very sensitive to this compound, but leukemias and bladder cancers are unaffected.98 A convenient synthesis of (aminomethyl)phosphonic acid proceeds through its N-benzoyl derivative.99 A successful synthesis (Scheme 19) of the phosphonic acid analogues of S a n d L-penicillamine commences with the cyclic phosphorochloridite (132). Other attempts using (132; R=Me or COOEt 1 failed.loo 2-Amino-4-phosphonobutanoic acid , the phosphonic acid analogue of glutamic acid, has been obtained in resolved forms by the action of papain, followed by aniline, on 2-benzoylamino-4-(diethoxyphosphinyl)butanoic acid when anilide occurs preferentially for the L- compound. Enantiomers of 4-amino-4-phosphonobutanoic acid were obtained by resolution of the N-benzyloxycarbonyl diethyl ester derivative with 1-phenylethylamine.101 Bromination of the (acylarninomethy1)phosphonic esters (133) and subsequent dehydrobromination, leads to the (acyliminornethyllphosphonate esters ( 1 3 4 ) , precursors to a variety of phosphonate types (Scheme 20). Treatment of (134) with Grignard reagents ( R 2=vinyl, phenylethynyl, or 1-naphthyl) affords the a-substituted esters (135). The bisphosphonic acid derivatives (136; R 2 =Me or Et) are obtained through Arbuzov reactions. A two-stage process provides the alkylated derivatives
161
5: Quinquevalent Phosphorus Acids
S
\\
2, / S R
1 2
R R C=NOH
RS
LR
S
(11 0)
LR
(116)
But (115)
II
R’R~C=NOP-SH
Organophosphorus Chemistry
162
0 ( P hO l,P(
II
PhS-
01
P(OPh),
NH2
Ph
It
s-fp(o NH2
0
0 II
0
0 II
v
__* q / P ( OIIH ) 2
~ P ( O P h ) zv i
~
Ph I2
NH2
NH 2
(118)
(119)
i, MeCOOH ; ii, F'hSCK2CH2CH0 ; iii, PnCF!;,9XJM12
Reagents:
; v, heat
iv, H202, MeCOOH
Scheme
\
R
; vi, H30+
17
N HCH2CO0E t
COOH
(mg5
( 1 2 0 1 ~ '=~H (121 l9'R = CH,COOH
I123 1''
,
@c H, NH CH co o H HOO,T")@ N 95
1127Ig6R= H or Me
( 125 Ig5
(121) n = 0,l R HOCH,CH,NCH
(126)96 @CR~NHCH,C%OH
( n C 0 O H !Hz@
H
R 2C HC HN , CH,CH ,OH
I
OH
@
(l28Ig7R = CH2@ or CMe2@ 0
= P(0)(OH12
0
I1
( R' 0 l2 P CR2 R N H CO C H2C I
\L
II
II
( HO),PCR2R3N HCOCH,P(
0
It
0
( R'O),PCR2
Reagents:
0
II
/ l l
R3NHC0CH,P(OEt),
i , (Et0)3P
;
ii, MeCixIH, HBr.
Scheme 18
0 H,)
5: Quinquevalent Phosphorus Acids
163
@ CH,CON H C H R’ I
CHR~
I
( 1 2 9 )= ~ COOH (130)R’= @ (131) R’=COOH
I I
R~=COOH
@
R2=COOH
, R2=
i
@
= P(O)(OH),
(1321
Ill
R = CMe,(OMel
HNXS
H N X s
Me
Me
‘Ho12p+Me SH H NH,
Reagents:
i , Me3COH ;
“x’ Scheme 19
ii, BF -Et20 ; iv, H30+ 3
164
Organophosphorus Chemistry
(137; R1=4-chlorophenyl).102 Scheme 21 summarizes further reactions leading to phosphonic acid analogues of amino acids. Treatment of the nitrone (138; R1=Me or Pri) with a dialicyl hydrogen phosphonate (best as the Li derivative which shows greater diastereoselectivity than the Na or K salts), and subsequent steps involving acidolysis of the oximino compound (139) lead to the free (a-aminoalky1)phosphonic acids (140)(phosphonoalanine, phosphonovaline). As an alternative process, the nitrone (138; R 1 =CH20CH2Ph) yields a mixture of diastereoisomeric (benzyloxymethy1)phosphonic derivatives of which (141) is the main component;acidolysis and hydrogenolytic debenzylation lead to phosphoserine (1431, the (S) chirality of which was demonstrated by X-ray analysis of the derivative (144). In a further variation, the di-tert-butyl ester analogue of (142) was employed, the ester groups being removed by acidolysis.103 Several acyl derivatives of (aminomethyl)-and (1-aminoethy1)-phosphonic acids, in the latter case including [L-1-([L-alanyl]amino)ethyljphosphonic acid (alafosfalin), have been prepared in their various diastereoisomeric forms and the relationship between structure and biological reactivity discussed.104 (2-Aminoethy1)phosphonic acid occurs in many aquatic and terrestrial animals as well as microorganisms, and their lipid fractions arethe most abundant source of the glycerophosphonolipids based upon that acid. Examples of such phosphonolipds have been prepared by a condensation between the glycerol esters (145;R=C15H31C0 or C18H37CO) and the phosphonic derivatives (146;R=H or CH2Ph; n=2 or 3) in the presence of TPS-C1; the phosphonolipids are obtained by a final hydrogenolysis; the same products (147) can also be obtained through the use of the phthalimide derivatives (148) the protecting group being removed with hydrazine. 105 Spontaneous dimerization of the benzylideneamido phosphites (149) yields dihydrodiazadiphosph(v)orines (150;R=Et, or (RO) -ethylenedioxy or phenylenedioxy) lo' whilst similar 2starting materials are stated to give the diazaphospholidines (151; R 1 ,R3=alkyl; R2=alkyl o r Ph) . I o 7 The 1 3-diaza-4,6-diphosphorine derivative (152) i - s obtainable from methylenebisphosphonic dichloride.lo8 The reaction between the d i a m i n o d i a z a d i p h o s p h e t i d i n e (153; R=cyclohexyl) and aromatic aldehydes with the formation of
165
5: Quinquevalent Phosphorus Acids
0
(133 1
Reagents:
(135)
i , NBS, CC14; V,
(p20)3p
ii, E t 3 N
; i i i , R k X i n THF
vii, Et2E
; vi,
Scheme
20
; iv, H301
CMe
;
166
OrganophosphorusChemistry
A
I
Me Me
R’
Ho+ !
R’ ( 139)
J’ii,
H
(138 1
O ‘ NN(
iv
P(01 0 C H,Ph l2 OCHZPh
OH
(1411
Reagents: i, (EtO)$OLi,
CH2C12,
-70’
; ii, H C 1 - k O H
iv, H30+
Scheme 21
; iii, H2-Pd
;
5: Quinquevalent Phosphorus Acids
167
the 1,3,4-oxazaphospholidines (154;R=cyclohexyl), structures confirmed by X-ray analysis, have been discussed in terms of a 109 tricyclic biphosphorane intermediate. 2.2.Reactions and Properties of Phosphonic and Phosphinic Acids and their Derivatives.-A free radical mechanism has been proposed to
acccunt for the cleavage of the phosphorus-carbon bond in the alkylphosphonic acids (155) by E.coli to give a mixture of alkane (methane only, from methylphosphonic acid) and terminal alkene. A much higher ratio of unsaturated:saturated hydrocarbons is observed than in the case of cleavage with lead tetraacetate. 110 Hexamethyldisiloxane converts the chloride (156;R=Cli directly into the anhydride of the acid( 156;R=OH).'I1 The rates of disproportionation of mixed anhydrides from protected 0 a-aminoacids and phosphorus acids are insignificant at 0 C,from a preparative viewpoint, compared with the rates of aminolysis. On balance, diphenylphosphinic and tetramethylenephosphinic chlorides are the best chlorides for u s e in peptide synthesis .'I2 Phosphinic acids in the 3-phospholene series are converted into their diethylamides by direct reaction with TDAP. Alkylphosphonic dichlorides (and even PC13) have been suggested as reagents for the determination of enantiomeric excesses in chiral alcohols and thiols using 31P chemical shifts. Best results are achieved with the smaller alkyl group in the acid chloride and the larger in the alcohol. Derivatives of phosphonoacetic acid and related acids have been acylated (for example to give ( 1 5 7 ) and nitrosated (to give, for example, (158))?16 The latter compound forms blue solutions thought to contain dimeric species. Somewhat unexpectedly. monodemethylation of the esters (159;R=Me) proved impossible using several standard techniques. Deallylation of mono and diallyl ester analogues of ( 1 5 9 1 , and of diallyl and ally1 methyl [ (1-acety1oxy)alkylJphosphonates was however acheived using palladium-containing catalysts, suggesting a potential wider applicability of the diallyloxv117 phosphinyl group in synthesis. Carbanions from tetraethyl methylenediphosphonates have been studied using several spectroscopic techniques The monohalogen esters !160;X=H,Y=Cl or B r ' l have been alkylated via their thallium salts,'l9 and sulphenation of their Li or Na derivatives with CC1nF3-nSC1 has been shown to be a complex
168
OrganophosphorusChemistry
+
0
0 OH
II/
II
PhCH20CNH(CH21,P,
OH
OR
(145)
i TPS-CI
RO Ro{
b0
!'
1 0 CI 2 n 'OH
0
0 PhNKNPh
CL-P-
1
1
II
0
P-CI
II0
(152)
0
0
II
(RO)2PCHCONEt2
I
C H2C0N Et (1 5 7
II t OP (CH2),,NH3 i
(146) @N(CH
0
II
Me
I
( Et0I2P-CCOOMe
1
NO (158)
5: Quinquevalent Phosphorus Acids
169
0:
P h C HO , C0N H
o
I1
x
(Pr'O),P-C-
0
P(OR1,
I
I
0
0
II
I1
P(OPr' I2
( RO),PCFXCOYH
Y
(160)
( 1 59)
(161)
0
0
II
( Et0I2PCF,Li
cs2 Me I
~
II
( E t O),P CF2 C SS M e
0
II
(Pr'01,PCHFLi
0
It
c-52 Mel ( Pr
(1 6 4 )
pXsMe
O I2
F
NuH
SMe
" F
Br
/RO'
Ph Reagents:
i , NBA
Scheme 2 2
CONu
H
170
Organophosphorus Chemistry
process and, depending on the individual sulphenyl chloride, unexpected reactions include the replacement of F by C1, and sometimes loss of sulphur.120 The dihalogen esters (160;X=Y=Cl or Br) are monodehalogenated using KF in MeCN containing a 18-crown6-ether.121 (Fluoromethyljphosphonate ester anions react with C02 or COS to yield esters of the type (161;Y=O or S ) which may be dealkylated to the free acid through the use of bromotrimethylsilane, but the course of the reaction with CS2 depends on the individual ester; thus, (162) yields (163), but (1651 is formed from (164).Iz2 Esters of [1-(diethoxyphosphinyloxy)perfluoro-1-alkenelphosphonic acid appear to be effective reagents for the synthesis of perfluoro-a,B-unsaturated carboxylic acids and their derivatives;presumably an initially-generated perfluoroketene (166) is acted upon by a nucleophile (NuH=RNH2, R2NH, or ROH). The
(E)/(Z-) ratio of the product components increases with increasing length of Rf. 1 2 3 In contrast with the behaviour of typical vinylphosphonic acid derivatives, the carbon-carbon double bond in the 1,2-oxaphospholene ( 1 6 7 ) is remarkably unreactive towards a broad spectrum of reagents including electrophiles, most epoxidizing and organometallic reagents, as well as to dipolar addition reactants. Exceptional reagents are, however, N-bromoacetamide (NBA), ozone, dimethyllithiumcuprate, and sodium-naphthalene. The reaction between (167) and NBA is set out in Scheme 2 2 . In aqueous solution, the reaction proceeds cleanly; ‘H nmr spectroscopic analysis indicates the formation of only one diastereoisomer of the acid (168;R=H);Chis acid was too labile for isolation but was isolated as a 1:l mixture of the esters (168;R=Me) enantiomeric at phosphorus. Ozone reacted slowly with & (169); (167) in chloroform To give phenylphosphonous acid y 124 the last was characterized as (170). The addition of g,g-diethyl hydrogen dithiophosphate to diethyl (3-rnethyl-1,Z-butadiene)phosphonate (171; R = H ) occurs at the 1,2-double bond, but on introduction of a vinyl group (171; R=CH=CH2) addition occurs across the latter to give 125 (172) after rearrangement. Addition of chiral sulphenylchlorides to cyclohexene affords diastereoisomeric mixtures of 2-chlorocyclohexylthio
5: Quinquevalent Phosphorus Acids
171
COOH
Ph
Me
’
M eO “/O ’
‘ 0
(169)
x C I I M e
(170)
0
0
II
( E t O ),PCR=C=CMe,
0
II
(Et0I2PCCH=CMe2
II
(
II
R’0 ),PC
H=C
=C R2R
CHCH,SP(S)(OEt), (171 1
(172)
0
II
( R’ 0 l2 P C H
RLS\e
=CC H R 5CI
I
R2fip:lR, R
SeR
(173)
Ph N H C H, P h
OPr‘
Me
(174)
R10\ /
0
II
-
MeNHNH2
PCH=C=CR2R3
CI
/ \
H2NN Me
( 177)
i
PhNHNH2
(178)
(1 79)
172
OrganophosphorusChemistry
esters Further observations on the addition of sulphenyl chlorides to (1,2-diene)phosphonic acid derivatives ( 1 7 3 ) have been reported.127 For the unsubstituted phosphonates, (173;R2=R3=HI) addition occurs at the terminal double bond to give (174;R5= H )
mainly in the (2) form for R4=Ph, but a mixture of (E) and ( Z ) forms for R4 =Me. For monosubstituted compounds,e.g. (173;R2=Pr; R 3 = H I the formation of acyclic addition product (174; R5=Pr) is accompanied by a small amount of 1,2-oxaphospholene (175; R2gPr; R3=H). Finally, t e r m i n a l l y - d i s u b s t i t u t e d compounds yield 1,2-oxaphospholenes (175) exclusively. The 1,2-oxaphospholene 1176) is formed by the BF3catalysed addition of benzylideneaniline to diisopropyl (3-methyl-l,2-butadiene)phosphonate.128 The course of the reaction between allenephosphonic monochloride monoesters and hydrazines depends on the individual hydrazine and is explicable in terms of the relative nucleophilicity of the nitrogen atoms in each. Thus (177; R1=Me,Et, Ph,PhCH2, or 1-naphthyl; R2 =H or Me; R3=H) reacts with methylhydrazine at the more nucleophilic nitrogen atom, .&i that carrying the methyl group, to give initially the hydrazide (178) which cyclizes t o (179). With phenylhydrazine, the more nucleophilic nitrogen atom is that in the NH2 group, and the reaction course is then (177)+(180)+1181). Depending on the manner of work-up, only one of (180) or (181) is is01able.l~~ Isolable pyrazolines (183) are obtained from the (1,3-butadiene)phosphonic acid esters 1182; X=S02Me, COOalkyl; R 1=H or Me; R2=Me or Ph) (products from (182;X=CN)are thermolabile) and diazomethane. Pyrolysis of the phosphorylated pyrazolines affords phosphonopentadienes rather than phosphonocyclopropanes (contrast (184)) and with NaH give pyrazoles or pyrazolephosphonic acid esters.130 Interaction of ( 173;R2=R3=Me1 and chromyl chloride affords the (cyc1opentenone)phosphonic esters (185). I 3 ' (a-Hydroxyalky1)phosphinic acid esters (186; R1,R2= H, or alkyl) are deoxygenated when treated with P214 yielding the compounds (187).132 The ester (188) rearranges to (189) in dry alcoholic(ROHI-HC1.133 In a useful communication, the cd and absolute configurations of the (a-hydroxybenzylphosphonic esters (190) have been reported. Normally obtained in small (10% for R1=R 2=Me; X = C 1 ) to medium (20% for R1=R 2=Pri; X=C1) enantiomeric
173
5: Quinquevalent Phosphorus Acids
(193) X = OSO,CF, (194) X = OCH,P(O)(OEt), ( 1 9 5 ) X . NR, or OAr
174
Organophosphorus Chemistry
excess, this can easily be raised by crystallization. The dextrorotatory compound (190;K1 =R 2=Me; X=C1) was shown crystallographically to have the (2)configuration.134 The decomposition of n i t r i l o t r i m e t h y l e n e t r i p h o s p h o n i c acid in acid solution has been studied. At 125-175O and pH 1.5, carbon-phosphorus bond cleavage occurs, but in 3M HC1 aq. carbon-nitrogen fission becomes important.135 A spectroscopic study of the esters (191) and (192) (R=H,C1,Br,N02,Me0,Me2N) has shown that the C=C, P=O, and C=O bonds are coplanar with, in (1Y2), a trans arrangement between the benzene ring and the ethoxycarbonyl group. It then becomes easy to explain the dephosphorylation which occurs when such esters are treated with aqueous alkali by postulating attack by HO- on the B-carbon of the carbon-carbon double bond.136 ' h e successful synthesis of diethyl phosphonomethyl at higher temperatures triflate ( 1 9 3 ) is possible only at (-15%; formation of the ether (1Y4) becomes important and exemplifies the further reaction with nucleophiles, including R2NH and ArO-, from which the esters (195) are obtained.137 in acetic acid, or aqueous acetone with subsequent treatment with acetic anhydride, the esters (196; R=4-MeO or 4-MeS) give rise to the expected esters(l97) or (198). For the 4-chlorophenyl derivative, a mixture of the unexpected products (199, 200; Ar=4-chlorophenyl) was obtained. The unsubstituted compound (196;R=H) gave only (1Y9) in aqueous acetone, but ( 2 0 0 ) in acetic acid. The postulated mechanism tor such a rearrangement centres around pseudophosphonium and-or phosphorane intermediates. The ester (201) also yields a mixture of rearranged and non-rearranged products. 138 Several communications have described uses for Lawesson's reagent and related compounds. Carboxylic acids have been the use of the reagent converted into their dithio analogue;13' as a peptide coupling agent proceeds with low racemization. 140 The products from the reagent and alcohols depend on the nature of the alcohol. Primary alcohols yield the esters (202) from which several derivatives have been obtained. When the -p-toluidine salts of (202) are heated in xylene, the phosphonamidodithioates (203) and the phosphonodiamidothioate (204) are formed. Tert-butyl alcohol presumably yields (202;R=CMe3) initially but at the reaction temperature butene is evolved
175
5: Quinquevalent Phosphorus Acids
r
1
OMS
OR
(197) R = H (198) R = Ac
(1 9 6 )
1
\
s
/’
C H 3CHP ( 0Et l2
Ar CH-P(OEt),
I
I
OMS ( 201 1
(i:;R=H
(200)R = Ac
Ms = 2 , 4 , 6 - t r i m e t h y l benzenesulphonyl
0 2CNH SR
Me 0
(202)
(204)
Me
(203)
S
s”’
‘Ar
II ArPI
RO
S
0-
II
PAr
I
OR
(205)
Ar = I - MeOC6HL
Ar t I
- Me OC6 HL
176
Organophosphorus Chemistry
and (205) is formed; in the presence of -p-toluidine (204) is once again produced, together with, for a reaction using 1-phenylethanol as substrate, (203; R=CHMePh) and (206; R 1=R 2=CHMePh). In the presence of pyridine, 1-phenylethanol gives the trithiophosphonate (206) as the sole product. 2-Butanol and cyclohexanol yield 141 0,O-diesters of type (207); phenol behaves similarly. Lawesson's reagent converts pyrrolidone derivatives into thioxopyrrolidones and peptides into thioxopeptides.143 N,N-Diacylhydrazines have been shown to yield 2,5-disubstituted1,3,4-thiadiazolesand 5 - p h e n y l - 1 , 3 , 4 - t h i a d i a z o l e - 2 ( 3 H ) - t h i o n e s ; in the case of N-acetyl-N'-ethoxycarbonylhydrazine, the thiadiazaphosphole ( 2 0 8 ) has been characterized by spectroscopic means.144 Other reactions which have already been discussed are those with oximes. The oxidative desulphurization of mono and dithio phosphonic and phosphinic acid esters may be carried out using hypochlorite.145 The stereochemistries of the reactions between g-aryl 0-methyl p h o s p h o n o c h l o r i d o t h i o a t e s and nucleophiles have been studied in relation to the synthesis of 1,3,2-oxazaphospholidines. No displacement of chlorine takes p l a c e on treatment of 2-methyl 0-4-nitrophenyl p h o s p h o n o c h l o r i d o t h i o a t e with 2-methoxyethanol, and in the presence of 1-phenylethylamine, it is only the latter which reacts. In addition, when the same phosphonochloridothioate is treated with sodium ethoxide, it is the 4-nitrophenoxy group, rather than chlorine, which is displaced. Both displacements were shown to occur with inversion of configuration at phosphorus. The use of such an acid chloride as a two-step 'cyclophosphorylating' agent of 2-aminoalcohols to give 1,3,2-oxazaphospholidines ( 2 0 9 1 , is illustrated.146 Differences in chirality of substrate, and nature of solvent, have no effect on the competitive nature of the displacement of 2-alkyl and S-methyl groups in the reactions between (+I-pinacolyl alkoxide and 0-ethyl (and methyl) S-methyl methylphosphonothioates (Scheme For the ( E l - ( + 1 esters , e.g. (2101, the displacements are highly stereoselective and occur with configurational inversion,but the enantiomeric esters do not display such stereoselectivity. (-)-Menthol might be considered a mirror image of (S)-pinacol, and similar reactions with the sodium salt of (-)-menthol occur highly stereoselectively
177
5: Quinquevalent Phosphorus Acids
S
OH
OMe
(2081
(209) 0
II
I
P
1
( Pin0I2P(O)Me
MeS’“ \Me OPin
Iii
II
P / ’ I \ Me Me 0
SMe
MeO’
1
” p\
Pin = pinacolyl
OPin
Me
Reagents:
i,
;
Scheme 2 3
ii, M ~ O -
178
Organophosphorus Chemistry
with the (?)-(-I esters but not with the enantiomers. Methoxide displaces the 5-alkyl group only. The effects of leaving group, solvent, and nucleophile, on the kinetics of aminolysis of a series of substituted aryl diphenylphosphinates and their mono and dithio analogues have been investigated.148 For the dithiophosphoric acid esters (211; R 1=R 2=alkylO) earlier work has already shown that methyl isocyanate (212; R 3 =Me) reacts with (211) under mild conditions to give the corresponding (2141, stable at room temperature, presumably y & the rearrangement of ( 2 1 3 ) (route b). At higher temperatures the products are the corresponding (215) and (216)(route a). A similar behaviour has now149 been shown for (212; R 3 =Et) but for isopropyl isocyanate, only route b is involved. The S + N rearrangement is inhibited in the case of the phenylphosphonate esters (211; R 1=alkylO; R 2=Ph) and diphenylphosphinic esters. The analogous behaviour of ?,2-2,3-butylene 2-trimethylsilyl phosphorodithioate suggested the possible intermediacy of the four-membered-ring phosphoranes as depicted in Scheme 24. A reaction between the bicyclic thiaphospholes (217) and alcohols occurs only in the presence of triethylamine. T h e products are ( 2 2 0 1 , probably formed by the dimerization of (2191, and the 2-alkoxy-1,2-thiaphosphole derivatives (218). Analogues of the latter are obtained with -p-toluenethiol and dialkylamines. The compound (217; R=Ph) is more reactive than (217; R=CMe3) and will react with aniline on addition of triethylamine even at room temperature, from which the formation of (221) was observed by spectroscopic characterization. Even more reactive is cyclohexylamine which furnishes an analogue of (221) without addition of strong base. 1 5 0 The phenylphosphonic diamides (222; X=O or S 1 15' and (223)152 are new condensing agents for the preparation of amides and esters of carboxylic acids. Interaction of allylphosphonic bis(dimethylamides1 and Schiff's bases ( 2 2 4 ) at low to moderate temperatures leads to both a and y adducts, but the rates of formation of these depend on reaction conditions and on steric effects of substituents in the base. For (224; Arl=Ph; Ar2=2-chloroor 2,4-dichlorophenyl) only the y adducts are formed. l-Aryl-1,3-butadienes are produced when the initial adduct anions are heated. 1 5 3
179
5: Quinquevalent Phosphorus Acids
.
-
R' Rt.
I
R'
Me3SiS'A,!o 'P-NR3
S
II
'POSiMe3
2/
-4-
R3NCS
R
-I
S S R''P-N,COSiMe3 II II
2'
R
(214)
Scheme 24 Ar
R
-[
(218)
( 2 1 91
Ar
Ar
PhN=P$Ph \
s-s
(2211
I \ X
K0
yh
1 Kx 0
N-P-N
nN-P-NYh n KS ys S
S
180
Organophosphorus Chemistry
Molecular geometrical differences between the amides (225) and (2261, the latter having the more pyramidal arrangement around nitrogen, have been correlated with the known differences in their solvolytic behaviour.154 Treatment of the sulphonate esters of N-phosphinylhydroxylamines with a strong base such as methoxide often results in a Lossen-like rearrangement. Thus with methoxide in methanol, the N-(arylphenylphosphiny1)hydroxylamine 2-methanesulphonates (227; R 1=Ph; K 2=Ar; R 3=Me) rearrange with competitive migration of Ph and Ar groups. For the -p-substituents,MeO, Me, C 1 , and NO2, the relative rates for ArIPh migrations are 30-35, s . 3 , 0.7, and 0.06; thus electron release into the aromatic ring encourages migration of that ring.155 Such a migration could conceivably (but is very unlikely to) occur through a phosphinylnitrene (235). Sulphides are known to be effective trapping reagents for nitrenes but attempts to employ them to attempt to demonstrate the intermediacy of such species are complicated by the fact that compounds (227) react readily with dialkyl sulphides,with displacement of sulphonate anion to give protonated N-phosphinylated sulphilimines and thence the sulphilimine (234). The reaction between (227; R1=R2=Ph; K3=Me) and dimethyl sulphide in the presence of tert-butylamine yields 90% of (231; R 1=R 2=Ph), and, 10% of (234); the latter, together with (233; R1=R2=Ph; R4=Me), is also produced when the nucleophile is m e t h 0 ~ i d e . l ~ In~ contrast to the behaviour of the phosphonic and phosphinic acid derivatives of type (2271, the phosphoric acid derivatives (227; R 1=R 2=ArO; R 3=Me or 4-nitrophenyl) in the presence of tert-butylamine do not rearrange but instead afford the amides (236) and the hydrazides (237). Some liberation of phenol may occur from (227;R1=ArO; K2=Ar) and thiswould arise either by attack by MeO- at phosphorus, or by elimination from the conjugate base (228) resulting in the formation of (232; R 3=Me) and (233; R4.=H) in approximately equal proportions, presumably by way of (229) and the formation therefrom of a mixed anhydride. Replacement of R 3=Me by R 3=4-nitrophenyl in (227) should result in increased formation of ( 2 3 1 ) at the expense of (2301, a 157 feature observed experimentally. The course of the alkylation of several potentially tautomeric phosphorus thio amides has been investigated. That of the diphosphazane (238) in the presence of' triethylamine
5: Quinquevalent Phosphorus Acids
181
l
Ar’CH=NAr2
(224)
+
(Me
N) PC=XH-CH2
II
( Me,N),PCH=CH
o
CH2CHAr’NHAr2
+
( Me2N),PCH CH-CH,
I
0
CHAr’ NHAr
Ph2P(0)NMe2
Ph2P(0)N3
/
o SO,R~
(227)
(228)
(230)
1
I I
+ I
0 R2’
0
0 / \ B ~ N H NHR~
‘N-SMe2
( 2 3 4I
-
+
(231) R<
R3S0,NH But
R 2 / ,p
9 0 N: L
(236)
1235) Ph,P-NH-
Ph2P=N P( S ) P h,
PPh,
I
II
II
S
S
SCHZR
(239)
(238) S
II
R,PNHX
S
II / x
R,PN
‘EMe3
, SEMe, R2Pk NX
182
Organophosphorus Chemistry
yields the 2-alkyl derivatives (239; R=CN or COOMe) In the reactions between the thiophosphinic amides ( 2 4 0 ) and the halides MenEC13-n (E=Si or Gel, it is only for the maximum steric hindrance in X and R (each 'at least' CMe3) that the imide For product ( 2 4 2 ) is stabilized relative to the amide ( 2 4 1 ) the oxygen analogues, the presence of tert-butyl groups (R, X I is required for E=Si, but for E=Ge, R=Prl is sufficient to stabilize the imide structure. 160 References
1. N.R.Williams, Carbohydrate Chem., 1985, 17, 67. 2. V.I.Yudelevich, L.G.Myasnikova, M.S.Polyak, E.P.Yakovleva, V.V.Belakhov, B.I.Ionin, and E.V.Komarov, Khim.-Farm. Zh., 1986, 20, 238 (Chem. Abstr., 1986, 104, 192 958). 3. N .N.Lebedev, B .V.Mamzurin, and V.P.Save1' yanov, J Gen. Chem.USSR (Engl. Transl.), 1985, 55, 480, 482, 485. 4. Y.Okamoto, Bull.Chem.Soc. Japan, 1985, 58, 3393. 5. W. ten Hoeve and H.Wynberg, J.Org.Chem., 1985, 50, 4508. 6. R.Bohlen, R.Francke, J-Heine,R.Schmutzler, and G.-V.Roeschenthaler, Z. Anorg. Allg. Chem., 1986, 533, 18. 7. L.S.Boulos, E.M.Yakout, and M.M.Sidky, Phosphorus Sulfur, 1984, 21, 47. 8. P.M.Chouinard and P.A.Bartlett, J.Org.Chem., 1986, 51, 75. 9. D.C.Crans and G.PI.Whitesides, J.Amer. Chem.Soc., 1985, 107, 7008, 7019. 10. K.S.Bruzik, G.Salamanczyk, and W.J.Stec, J.Org.Chem., 1986, 51, 2368. 11. J.F.W.Keana, M.Shimizu, and K.K.Jernstedt, J.Org.Chem., 1986, 51, 2297. 12. J.W.Perich, P.F.Alewood, and R.B.Johns, Tetrahedron Lett., 1986. 27, 1373; J.W.Perich, R.M.Valerio, and R.B.Johns, Tetrahedron Lett., 1986, 27, 1377. 13. FS.Khokhlov, L.S.Berseneva, and N.F.Savenkov, J.Gen.Chem.USSR (Engl.Trans1.,) 1984, 54, 2274. 14. C.D.Reddy, C.V.N.Rao, D.B.Reddy, M.D.Thompson, J.Jasinski, E.M.Holt, and K.D.Berlin, Indian J.Chem., Sect. B, 1985, 24, 481. 15. A . Lopusinski and A.Haas, Chem. Ber.,1985, 118,4623. 16. M.-P.Teulade and P.Savignac, Phosphorus S u l f u r , 1984, 21, 23. 17. A.P.Marchenko, V.V.Miroshnichenko, A.A.Kudryavtsev, and A.M.Pinchuk, J. Gen. Chem.USSR(Eng1. Transl.), 1984, 54, 2400. 18. L.K.Lukanov, A.P.Venkov, and N.M.Mollow, Synthesis, 1985, 971. 19. J.Baraniak and W.J.Stec, Tetrahedron Lett., 1985, 26, 4379. 20. P.M.Cullis, P.B.Kay, and S.Trippett, J.Chem.Soc.,C.Commun., 1985, 1329. 21. A.M.Beltran, A.Klaebe, and J.J.Perie, Tetrahedron Lett., 1985, 26, 1711. 22. C.A.Bunton and C.Quan, J.Org.Chem., 1985, 50, 3230. 23. S.H.Gellman, R.Petter, and R.Breslow, J.Amer.Chem.Soc., 1986, 108,2388. 24. P.Hendry and A.M.Sargeson, Inorg.Chem., 1986, 25, 865. 25. K.Taira, K.Lai, and D.G.Gorenstein, Tetrahedron, 1986, 42, 229. 26. R.Kluger and G.R.J.Thatcher, J.Amer.Chem.Soc., 1985, 107, 6006. 27. R.Kluger and G.R.J.Thatcher, J.Org.Chem., 1986, 2,207. 28. J.M.Friedman and J.R.Knowles, J.Amer.Chem.Soc., 1985, 107, 6126. 1298. 29. P.M.Cullis and A.J.Rous, J.Amer.Chem.Soc.,1986, 3, 30. F.Ramirez, J.Marecek, J.Minore, S.Srivastava, and W.le Noble, J.Amer.Chem.Soc. 1986, 108,348. 31. K.W.Y.Abel1 and A.J.Kirby, Tetrahedron Lett., 1986, 2, 1085. 32. P.M.Cullis and A.J.Rous, J.Amer.Chem.Soc., 1985, 107, 6721. 33. G.Lowe and S.P.Tuck, J.Amer.Chom.Soc., 1986, 108, 1300. 34. P.M.Weiss, W.B.Knight, and W.C.Cleland, J.Amer.Chem.Soc., 1986, 108,2761. 35. W.B.Knight, P.M.Weiss, and W.W.Cleland,J.Amer.Chem.Soc., 1986, 108,2759.
.
5: Quinquevalent Phosphorus Acids
36. 37. 38. 39.
183
W.Kudelska and M.Michalska, Tetrahedron, 1986, 42, 629. A.Okruszek, P.Guga, and W.J.Stec, J.Chem.Soc.,Chem.Commun.,l985, 1225. P.A.frey, W.Reimschusse1, and P.Paneth, J.Amer.Chem.Soc., 1986, 108, 1720. R.M.Acheson, C.T.Lines, M.R.Bryce, Z.Dauter, C.D.Reynolds, and A.Schmidpeter, J.Chem.Soc., Perkin Trans. 2, 1985, 1913. 40. J.H.N&man, N.Kopola,and G.Pensar, Tetrahedron Lett., 1986, 27 I 1391. 41. A.Koziara, K-Turski,and A.Zwierzak, Synthesis, 1986, 298. 42. S.Kitane, M.Berrada, J.Vebre1, and B.Laude,Bull.Soc.Chim.Belge I 1985, 94,163. 43. K.Osowska-Paciewicka and A.Zwierzak, Tetrahedron, 1985, 41,4717 44. F.Ramirez, J.S.Ricci, H.Ozakaki, J.F.Marecek, and M.Lewy, Phosphorus Sulfur, 1984, 20, 279. 45. A.T.Hutton, T.A.Modro, M.L.Niven,and S.Scaillet, J.Chem.Soc., Perkin.Trans.2, 1986, 17. 46. S.M.Ludeman, V.L.Boyd, J.B.Regan, K.A.Gallo, G.Zon, and K.Ishii, J.Med.Chem., 1986, 29, 716. 47. Yu. N.Mitrosov and V.V.Kormachov, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 1075. 48. Yu.I.Shvedova, A.V.Dogadina, B.I.Ionin, and A.A.Petrov, J.Gen.Chem.USSR (Engl. Transl.), 1984, 2 , 2494. 49. H.Duddeck, M.H.A.Elgama1, A.G.Hanna, and M.Kaiser, Tetrahedron, 1985, 41, 3763. 50. T.Hirao, M.Hagihara, and T.Agawa, sL.Chem.Soc.Japan, 1985, 58, 3104. 51. A.B.Reitz, S.O.Nortay, and B.E.Maryanoff, Tetrahedron Lett., 1985, 26,3915. 52. K.Issleib, A.Balszuweit, J.KBtz, St.Richter, and R.Leutleff, Z.Anorg.Allg.Chem, 1985, 29, 151. 53. E.A.Krasil'nikova, O.L.Nevzorova, and V.V.Sentemov, J.Gen.Chem.USSR (Engl.Transl.), 1985, 55, 1145. 54. Yuanyao Xu and Z.Li, Synthesis, 1986, 240. 55. J.J.Bulot, E.E.Aboujaouade, N.Collignon, and P.Savignac, Phosphorus Sulfur, 1984, 11,197. 56. F.Effenberger and H.Kottmann, Tetrahedron, 1985, 5, 4171. 57. H.Suzuki, K.Watanabe, and Q.Yi, Chem. Lett., 1985, 1779. 58. B.Cook and J.G.Dingwal1, Phosphorus Sulfur, 1985, 22, 211. 59. E.E.Aboujaouade, S.Lietje, N.Collignon, M.P.Toulade,and P.Savignac, Tetrahedron Lett., 1985, 26, 4435. 60. K.Issleib, W.MUgelin, and A.Balszuwert, Z.Anorg.Allg.Chem.,1985, 530, 16. 61. D.Y.Kim and D.Y.Oh, Synth.Commun., 1986, Is, 859. 6 2 . M.V.Livantsov, M.V.Proskurnina. A.A.Prishchenko, and I.F.Lutsenko, J.Gen.Chem.USSR (Engl.Transl.), 1984, 54, 2237. 63. J.R.H.Wilscn, J.Chern.Soc., Perkin Trans.1, 1986, 1065. 64. E.E.Nifant'ev, V.I.Maslennikova, R.K.Magdeeva, J.Gen.Chem.USSR(Engl.Transl.), 1984, 54, 2100. 65. E.E.Nifant'ev, V.I.Maslennikova, R.K.Magdeeva, N.V.Zyk, N.N.Nevskii, and A.R.Bekker, J.Gen.Chem.USSR (Engl.Transl.1, 1984, 54, 2341. 66. H.Yamamoto, T.Hanaya, H.Kawamoto, S.Inokawa, M.Yamashita, M.-A,Armour, and T.T.Nakashima, J.Org.Chem., 1985, 50, 3516. 67. T.A.Blumenkopf, Synth.Commun., 1986, Is, 139. 68. J.J.Yaouane, G.Masse, and G.Sturz, Synthesis, 1985, 807. 69, D.E.Gibbs and C.Larsen, Synthesis, 1984, 410. 70. H.Takaku, H.Tsuchiya, K.Imai, and D.E.Gibbs, Chem.Lett., 1984, 1267. 71. D.M.Malenko, L.A.Repina, and A.D.Sinitsa, J.Gen.Chem.USSR(Engl.Transl.), 1984, 54, 2148. 72. G.Salbeck, Phosphorus Sulfur, 1985, 22, 353. 73. B.Corbe1, L.Medinger, J.P.Haelters, and G.Sturtz, Synthesis, 1985, 1048. 74. E.Ohler, M.El-Badawi, and E.Zbira1, Chem-Ber., 1985, 118,4089. 75. V.G.Sobolev and B.I.Ionin, J.Gen.Chem.USSR(En,gl.Transl.), 1985, 55, 1455. 76. T.Nagase, T.Kawashima, and N.Inamoto, Chem.Lett., 1985, 1655. 77* P.S.Khokhlov, B.A.Kashemirov, A.D.Mikityuk, Yu.A.Strepikheev, and A.L.Chimishkyan, J.Gen.Chem.USSR.(Engl.Transl.), 1984, 54, 2359,2495.
OrganophosphorusChemistry
184
M.Regitz and R.Martin, Tetrahedron, 1985, 41,819. G.Penz and E.Zbira1, Chem.Ber., 1985, 118,4131. G.M.Blackburn and D.E.Kent, J.Chem.Soc.,Perkin Trans.1, 1986, 913. B.Dhawan and D.Redmore, J.Org.Chem., 1986, 51, 179. E.E.Nifant'ev and T.S.Kukhareva, J.Gen.Chem.USSR (Engl.Transl.), 1985, 2, 265. 83. P.A.Odoriso, S.D.Pastor, and J.D.Spivach, Phosphorus Sulfur, 1984, 20, 273. 84. H.Gross, T.Ya.Medved, S.Nowak, F.I.Bel'skii, I.Keite1, and M.I.Kabachnik, J.Gen.Chem.USSR (Engl. Transl.), 1985. 55, 654. 85. C. King, D.M.Roundhil1, and F.R.Franczek, Inorg.Chem., 1986, 25, 1290. 86. Y.Xu and Z.Li, Tetrahedron Lett., 1986, 27, 3017. 87. D.M. Malenko, L.A. Repina, and A.D.Sinitsa, J.Gen.Chem.USSR (Engl.Transl.), 1985, 55, 622. 88. F.S.MuEametov and E.E.Korshin, J.Gen.Chem.USSR (Engl.Transl.), 1984, 54, 2505. 5267. 89. A.Rudi, I.GoldSerg, and Y.Kashman, Tetrahedron, 1985, 5, 90. H.Day, Sulfur Lett., 1985, 3, 39. 91. R.Shebana, A.A.El-Barbary, A.B.A.G.Ghattas, and S.-O.Lawesson, Sulfur Lett., 1984, 2, 223; A.A.El-Barbary, R.Shabana, and S.-O.Lawesson, 375. Phosphorus Sulfur, 1985, 1, 92. J.Navech, M.Reve1, and R.Kraemer, Phosphorus Sulfur, 1984, 21, 105. 93. Yen Vo-Quang, D.Carniato, L.Vo-Quang, A.-Marie Lacoste, E.Neuzi1, and F.le Goffic, J.Med.Chem., 1986, 29, 579. 94. W.Subotkowski, R.Tyka, and P.Mastalerz, Pol. J. Chem., 1983, 57, 1389 (Chem. Abstr.,1985, 103, 71 404). 95. P.J.Die1 and L. Maier, Phosphorus Sulfur, 1984, 20, 313. 96. A.V.Barsukov, B.V.Zhadanov, T.A.Markovskaya, N.A.Kaslina, I.A.Polyakova, G.F.Yaroshenko, A.V.Kessenikh, and N.M.Dyatlova, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1417. 97. A.V.Barsukov, N.A.Kaslina, B.V.Zhadanov, T.A.Matkovskaya, I.A.Polyakova, G.F.Yaroshenko, N.M.Dyatlova, and A.V.Kessenikh, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 715. 98. P.Kafarski, B.Lejczak, P.Mastalerz, D.Dus, and C.Radzikowski, J.Med.Chem., 1985, 28, 1555. 99. M.J.Pidwer and T.M.Balthazer, Synth. Commun., 1986, 16, 733. 100. I.Hoppe, U.Schoellkopf, M.Nieger, and E.Egert, Angew. Chem.,Int.Ed. Engl., 1985, 24, 1067. 101. K.Antczak and J.Gzewczyk, Phosphorus S u l f u r , 1985, 22, 247. 102. T.Schrader, R.Kober, and W.Steglich, Synthesis, 1986, 372. 103. R.Huber, A.Knierzinger, J.P.Obrecht, and A.Vasella, Helv. Chim.Acta, 1985, 68, 1730. 104. F.R.Atherton, C.H.Hassal1, and R.W.Lambert, J.Med.Chem.,l986, 29, 29. 105. K.Yamauchi, F.Une, S.Tabata, and M.Kinoshita, J.Chem.Soc.,Perkin Trans . 1, 1986, 765. 106. L.I.Nesterov and A.D.Sinitsa, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1064. 107. Z.S.Novikova, M.M.Kabachnik, N.V.Mashchenko, and I.F.Lutsenko, J.Gen.Chem.USSR(Engl.Transl.), 1985, 2 , 404. 108. R.Neidlein and H.J.Degener, Chem.-Ztg., 1984, 108,412. 109. M.M.Yusupov, Sh.Egamberdyev, M.K.Makhmudov, and B.Tashkhodzhaev, J.Gen.Chem.USSR (Engl Transl.), 1984, 54, 2417. 110. M.L.Cordiero, D.L.Pompliano, and J.W.Frost, J.Amer.Chem.Soc., 1986, 108,332. 111. W.Jansen and R.Ulses, Z.Anorg.Allg.Chem., 1986, 532, 197. 112. R.Ramage, B.Atrash, D.Hopton, and M.J.Parrott, J.Chem.Soc.,Perkin Trans . 1, 1985, 1617. 113. J.Szewczyk, J.R.Lloyd, and L.D.Quin, Phosphorus Sulfur, 1984, 21, 155. 114. B.L.Feringa, A.Srnaardijk, H.Wynberg, B-Strijtveen, and R.M.Kellogg, Tetrahedron Lett., 1986, 13, 997.; B.L.Feringa, A. Smaardijk, and H.Wynberg, J.Amer.Chem.Soc., 1985, 107, 4798. 115. D.J.McCabe, S.M.Bowen, and R.T.Paine, Synthesis, 1986, 319. 78, 79. 80. 81. 82.
.
'
185
5: Quinquevalent Phosphorus Acids
116. B.A.Kashemirov, P.S.Khoklov, E.A.Polenov, O.G.Soko1, and L.I.Kakadii, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 407. 117. M.Kamber and G.Just, Can. J.Chem., 1985, 63, 823. 118. T.Bottin-Strzalko, J.Corset, F.Froment, M.J.Pouet, J.Seyden-Penne, and M.P.Simonnin, Phosphorus Sulfur, 1985, 22, 217. 119. D.W.Hutchinson and G.Semple,J.Organomet.Chem., 1985, 291, 145. 120. G.M.Blackburn and T.W.Maciej, J.Chem.Soc.,Perkin. T r a n s L , 1 9 8 5 , 1935. 121. D.W.Hutchinson and G.Semple, Phosphorus Sulfur, 1984, 21, 1. 122. G.M.Blackburn, D.Brown, and S.J.Martin, J.Chem.Res.(S), 1985, 92. 123. T.Ishihara, Y.Yamasaki, and T.Ando, Tetrahedron Lett., 1986, 27, 2879. 124. R.S.Macomber, I.Constantinides, and G.Garrett, J.Org.Chem., 1985, 50, 4711. 125. N.G.Khusainova, I.Ya.Sippel', E.A.Berdnikov, R.A.Cherkasov, and A.N.Pudovik, J.Gen.Chem.USSR (Engl. Transl.), 1984, 54, 2506. 126. G.Haegele, M.Engelhardt, W.Peters, A.Skowronska, J.Gwara, and D.Wendisch, Phosphorus Sulfur, 1984, 21, 53. 127. Kh.M.Angelov and Ch.Tancheva, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 5 5 , 45. 128. L.S.Trifonov and A.S.Orahovats, Heterocycles, 1985, 23, 1723. 129. N.Ayad, B.Baccar, F.Mathis, and R.Mathis, Phosphorus Sulfur, 1985, 21, 335. 130. T.Minami, S.Tokumasu, R.Minasu, and I.Hirao, Chem. Lett., 1985, 1099. 131. Yu.M.Dangyan, M.R.Tirakyan, G.A.Panosyan, and Sh.O.Badanyan, J.Gen.Chem.USSR(Engl.Transl.), 1985, 55, 1451. 132. M.Yamashita, K.Tsunekawa, M.Sugiura, T.Oshikawa, and S.Inokawa, Synthesis, 1985, 896. 133. E.Castagnino, S.Corgano, and G.Piancatelli, Synth.Commun.,l985,15, 783. A. Smaardijk, S. Noorda, F. van Bolhuis, and H. Wynberg, 134. Tetrahedron Lett., 1985, 26, 493. 135. N.A.Kaslina, I.A.Polyakova, A.V.Kessenikh, B.V.Zhadanov, M.V.Rudomino, N.V.Churilino, and M.I.Kabachnik, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 534; V.P.Vasil'ev, L.A.Kochergina, and T.D.O?leva, ibid. 720. 136. A.V.Mbskvin, M.V.Korsakov, N.A.Smorygo, and B.A.Ivin, J.Gen.Chem.USSR (Engl. Transl.), 1984, 54, 1987. 137. D.P.Phillion and S.S.Andrew, Tetrahedron Lett., 1986, 27, 1477. 138. X.Creaery and M.E.Mehrsheikh-Mohammadi, J.Org.Chem., 1986, 51, 7. 139. H.Davy and P.'Metzner, J.Chem.Res.(S), 1985, 272. 140. M.Thorson, T.P.Anderson, U-Pedersen, B.Yde, S.O.Lawesson, and H.F.Hansen, Tetrahedron, 1985, 2,5633. 141. R.Shabana, A.A.El-Barbary, N.M.Yousif, S.O.Lawesson,Sulfur Lett., 1984, 2, 203. 142. T.P.Andersen, P.B.Rasmussen, Ib.Thomsen, S.O.Lawesson, P.Joergensen, and P.Lindhardt, Justus Liebigs Ann.Chem., 1986, 269, 143. G.Sauve, V.S.Rao, G.Lajoie, and B.Belleau, Can. J.Chem., 1985, 63, 3089. 144. P.B.Rasmussen, U.Pedersen, I.Thomsen, B.Yde, and S.O.Lawesson, Bull. S O C . Chim. Fr., 1985, 62. 145. L.Horner and J.Gerhard, Phosphorus Sulfur, 1985, 22, 13. 146. Shao Yong Wu and M.Eto, Agric. Biol. Chem., 1984, 48, 3071. 147. C.R.Hal1, T.D.Inch, C.Pottage, and N.E.Williams, Tetrahedron, 1985, 41, 4909. 148. R.D.Cook, W.A.Daouk, A.N.Hajj, A.Kabbani, A.Kurku, M.Samaha, F.Shayban, and O.V.Tanielian, Can.J.Chem., 1986, 64, 213. 149. G.A.Kutyrev, A.V.Lygin, R.A.Cherkasov, and A.N.Pudovik, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 223. 150. H.Tanaka, T.Saito, and S.Motoki, Chem.Pharm.Bull., 1986, 59, 59. 151. M.Ueda, A.mochizuki, I.Hiratsuka, and H.Oikawa, Bull.Chem.Soc.Japan, 1985, 58, 3291. 152. T.Mujasaka, S.Hibino, Y.Inouye, and S.Nakamura, J.Chem.Soc.,Perkin Trans. 1, 1986, 479. 153. M.Kirilov, I.Petrova, and Z.Zdravkova, Phosphorus Sulfur, 1985, 11,301. 154. B.Davidowitz, T.A.Modro, and M.L.Niven, Phosphorus Sulfur, 1985, 22, 255. 155. M.J.P.Harger and A.Smith, J.Chem.Soc.,Perkin Trans.1, 1985, 1787. ~
~
~
186
OrganophosphorusChemistry
156. M.J.P.Harger and A.Smith, J.Chem.Soc., Perkin Trans. 1, 1986, 377. 157. M.J.P.Harger and A.Smith, J.Chem.Soc., Perkin Trans. 1, 1985, 2651. 158. N.G.Zabirov, E.L.Gol’dfarb,R.A.Cherkasov, and A.N.Pudovik, J.Gen. Chem.USSR(Eng1. Transl.), 1984, 54, 2502. 159. Yu.A.Veits, V.L.Foss, V.A.Leksunkin, and M.V.Gurov, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1459. 160. V.L.Foss, Yu.A.Veits, V.A.Leksunkin, and M.V.Gurov, J.Gen.Chem.USSR (EngLTransl.), 1985, 55, 1458.
5
Quinquevalent Phosphorus Acids BY
R. S. EDMUNDSON
Aspects of the chemistry of carbohydrate phosphates,' and of phosphonomycin ( cis-3-methy 1-2- oxirany lbhosphonic acid have been reviewed.
1. Phosphoric Acids and their Derivatives 1.1 Synthesis of Phosphoric Acids and their Derivatives.- A detailed study of the kinetics of formation of alkyl phosphorodichloridates and dialkyl phosphorochloridates from P0Cl3 and alcohols has been described in a series of papers.3 Monoalkyl dihydrogen phosphates have been prepared in quite high yield in the apparently facile interaction of alcohols and a reagent prepared from P4Ol0 and he~amethyldisiloxane.~Several cyclic hydrogen phosphates ( 1 ; K = Me, MeO, EtO, C1, or C12) have been synthesized and resolved; the 2-chlorophenyl compound is an effective resolving agent, and its absolute configuration has been deter~nined.~ The cyclic acid (2) and its trimethylsilyl ester have been obtained during a study of the chemistry of 2,2,2-triethoxy-2,2-dihydro-tetrakis~trifluoromethyl~-ly3y2-
dioxaphospholane.6 Enol phosphate esters of types ( 4 ) and ( 5 ) have been prepared by reaction between trialkyl phosphites and (3; R = H or Me). Shikimic acid has been converted into the 5-enol-3-phosphate (6; R = CH2Ph), and thence to the free acid (6;R = OH) by the use of tetrabenzyl pyrophosphate.8 During the course of an examination of the substrate specificity of glycerol kinase, several 3-substituted-propane-ly2-diol1-phosphates were ~ r e p a r e d . ~A general method for the synthesis of glycerophospholipids (Scheme 1 ) employs compounds of tervalent phosphorus in the initial stages;lOthe choice of reagent (v or vi, vii or vi) depends on the protecting group in R2 derived from choline tosylate, N-tritylethanolamine, or 1,2-isopropylide-eglycerol. A second prccedure designed for 134
5: Quinquevalent Phosphorus Acids
135
related compounds (Scheme 2) is based on a condensation achieved by the use of 2,4,6-triisopropylbenzenesulphonyl chloride (TPS-C1) .I1 Methylation of (7; R-H) was employed as a means of purification of the acid since the methyl ester (7;R=Me) could be demethylated readily by NaI. Solution and solid phase techniques have each been used in the synthesis of appropriately N-protected g-phosphoseryl 12 peptides. Trialkyl phosphorotetrathioates are convertible to the phosphorodibromidodi thioates ( 8 1 by the use of PSBr3.l 3 A study of the 1,5-dihydro-7,8-dimethyl-2,4,3-benzodithiaphosphepin derivatives (9 has centred on spectroscopic and X-ray techniques .I4 Bis(trifluoromethy1) disulphide has been shown to react with the phosphite ( 1 0 ) ( and also its phosphorus epimer) in an essentially stereospecific manner giving the thiophosphates (11; a and b) in the ratio 8 9 ~ 1 1 .However, methanolysis of the latter compounds is much less stereospecific; from lla, for example, the yields of (12) and (13) are in the ratio 69:31, and the compounds ( 1 4 ) and ( 1 5 ) are also formed in the ratio73:27.15 The thermally-induced cyclization of (2-haloethyl)phosphoramidothioic esters (16) to give the 1,3,2-thiazaphospholclosely related idines ( 1 7 ) has been reported in fu1l;''some syntheses were reported several years a g o but only in preliminary form. The example illustrated in Scheme 3 is, perhaps, a little more surprising.17 In a new approach to the synthesis of phosphoramidates by the Todd-Atherton reaction, those from the more weakly basic amines, more particularly aromatic amines, have been obtained by reaction between dialkyl hydrogen phosphonates and the N-formyl or N-chloroacetylarylamine in a two-phase system.1 8
1.2. Reactions and Properties of Phosphoric Acids and their Derivatives.-The use of isotope labels, in particular l 8 O , at appropriate sites, as a means of differentiating between alternative mechanisms in phosphorus chemistry, continues to expand. The Appel reaction (between dialkyl hydrogen phosphate and arnine in the presence of Ph3P/CC14) exemplifies such application. The known final products could arise either directly by interaction of a nucleophile and the proposed intermediate
Organophosphorus Chemistry
136
&;, \
Me
R
5
R
(3)
0
a II
0 P(OR21, I
R'
0
\
R'o R'O
slL
vd o r vi
0IIO ,R ,OP,
. S
OP, i , Pr$(MeO)FCi
, Et3N;
2
Scheme 1
'''1 .
:,OR2 OP O 'H
-
R'O7 OR ,2;
OR2
OP\
OMe
i i , R 2OH, tetrazole;
i v y S8 ; v , PhSH ( o r EtSH) , Me3N
R'o
OMe
v i i or V I.
,I Reagents:
OMe
OH
i i i , Me3COOH ;
; v i , MeCOOH ; v i i ,
Me3 N
5: Quinquevalent Phosphorus Acids
137
R'O
I
Me0
I
OR3
OH (71 2
1
R = palmitoyl or oleoyl ; R = palmitoyl ReagenTs: i , T E - C l
;
ii, CH2N2
Scheme
2
i
RSPBr, S
( 8 )
A
X
(12) X = OMe ; Y = = O (13) X - = O ; Y =OMe
OAr
(14) A = = O (15)P.z F
;
B=F
i B:=O
138
Organophosphorus Chemistry
(18;Scheme 4) or indirectly by initial expulsion of k'h3k'0 and subsequent involvement of a phosphoryl chloride. The model compounds examined were based on the 4-methyl-1,3,2-dioxaphosphorinane system. The =-and trans-2-hydroxy 2-18U-oxides ( 1 91 were separately converted into the diastereoisomeric anilides (2U). No evidence was forthcoming to suggest the participation of an initially-formed phosphorochloridate, and evidently the axial oxygen undergoes preponderant reaction (by a factor of 6 6 1 , the reaction proceeding with inversion of configuration through an intermediate probably of type (18).19 Another brief but interesting communication2' outlines a reexamination, based on 180-induced changes in phosphorus chemical shifts, of the reaction between a methyl phosphate ester and a phosphorylchloride to give a pyrophosphate, and which employed models based on the 5,5-dimethyl-1,3,2-dioxaphosphorinane system. Far from being the simple process of phosphoryl attack on phosphorus a s originally envisaged, the complete scrambling of the oxygen label was attributed primarily to the participation of a tricyclic dioxadiphosphetane intermediate ( 2 1 1 , but the presence of: free cyclic phosphoric acid introduced further complications. The kinetics of hydrolysis of 4-nitr0phenyL~~ and 2,4-dinitrophenyl dihydrogen phosphates22 (see also ref. 3 0 1 have been determined. In the hydrolysis of diphenyl 4-nitrophenyl phosphate,replacement of R=H in the tetraco-ordinate zinc complex (22) by R=C16H33 results in the enhancement of the catalytic effect of the complex.2 3 Expulsion of dinitrophenate and formation of monodentate N-bound phosphoramidate in almost quantitative yield is observed when coordinated 2,4-dinitrophenyl pentaaminecobalt( I 1 1 1 is treated with aqueous base. 24 A further test of the stereoelectronic theory ot reactivity of phosphate esters has been attempted using measurements ot the rates of displacement of: 4-nitrophenate from the esters ( 2 3 ) and (241, their phosphorus epimers, and also (251, in aqueous methanol; the introduction of the 4a-Me group into the system would, it was hoped, reduce the the flexibility of the bicyclic structures and so possibly eliminate the participation of twist-boat conformations. The presence of the 4a-Me group has no effect of: the rate of displacement of the axial ArO group
5: Quinquevalent Phosphorus Acids
139
(16)
X = C I or
(17) 2
1
Br ; R = a l k y l ; R = alkyl or CH,CH,X
; Z =alkyl ,alkoxy, or aryloxy
0
II
(Et2N),P-NCH2CH,Br
I
heat
+
-EtBr
Et Scheme 3
(18)
\
- Ph3P0
'
Reagents: i , Ph,P Cclq ; ii, bhki
Scheme 4
i; (19)
(20)
.=
18
0
0
\p4 a'
Organophosphorus Chemistry
140
CI
(211
0
II
R
(23)R = H ( 2 4 ) R = Me 0
(26)
11
R'-
Re (27)
kR+
c p
,.OMe
0-P0
oI'-
-0
- cp/.0-P.
Ib o -
0 Me
ROCH CH OP-0
*
(29)
* I
(30)
Scheme 5
0-
5: Quinquevalent Phosphorus Acids
141
whereas for the (pseudo)equatorial aryloxy groups, the added methyl group reduces the rate of displacement. Each equatorial epimer hydrolyses faster than the corresponding axial compound, and compound (25) hydrolyses at a rate intermediate between those of the equatorial isomers on the one hand, and the axial isomers on the other. Such relative rates of hydrolysis were thought to be consistent with the idea that axial isomers react via chair conformations, whilst the equatorial isomers react via twist-boat conformations with the aryloxy group in the pseudoaxial position. 2 5 The factors involved and mechanistic pathways in the hydrolysis of phosphate esters, particularly those of a cyclic nature, continue to be the source of much speculation. A further study of the simplest cyclic triester, ethylene methyl phosphate, seems only to have served to consolidate already polarized views. The original experiments of Westheimer's group employed H nmr spectroscopy and demonstrated that ethylene methyl gc and ' phosphate (26) hydrolyses under alkaline conditions by processes which include exocyclic bond fission. More recent work by Gorenstein et al. using 31P nmr spectroscopy apparently showed that, consistent with the stereoelectronic theory of phosphate ester reactivity, there was complete endocyclic bond cleavage for solutions of (26) in 5M aqueous alkali. A re-examination of the hydroLysis of ester (261, using both ' H and 31P nmr techniques, now confi-rms that exocyclic cleavage to give MeOH and ethylene hydrogen phosphate does indeed occur, and that che extent of that process increases with higher concentrations of base (Scheme 5: R=H, O=O=160). In addition, the - methyl 2-hydroxyethyl product of initial ring opening,viz hydrogen phosphate, hydrolyses too slowly to account for the amount of methanol liberated in the early stages of the hydrolysis of (26).26 The mechanism outlined in the Scheme requires that direct ring opening of the initial pentaco-ordinate intermediate ('27328) competes with proton ( R - H ) removal (27--)29) prior to pseudorotation. The minimal amount of exocyclic cleavage product produced in dilute base indicates that ring opening is faster than pseudorotation. As the concentration of base is increased, the rate of proton removal increases relative to that of ring opening.
142
OrganophosphorusChemistry
The results of additional experiments using D20 containing D2I80 are also conveniently incorporated into Scheme 5 (R=D; O= 160, 0= 18O).27 Using conditions as close as possible to those employed by Goren scein et al., Kluger et al-showed that only one equivalent of base DO- was incorporated during exocyclic cleavage; in spite of kinetics indicating second order dependence on base, the lack of incorporation of a second equivalent of base suggests that it is probably used simply for proton removal in the stage (27+29). Since 2-hydroxyethyl dihydrogen phosphate (30) triply labelled with isotopic oxygen is also not formed, it seems unlikely that hexaco-ordinate intermediates are not involved in the hydrolysis of (261, a point over which chere does appear to be agreement. Many mechanistic aspects of the hydrolysis of phosphate esters in protic media remain uncertain. In spite of predictions that racemization at phosphorus should be the final outcome if indeed the (hypothetical)metaphosphate intermediate is involved in the solvolysis of monoesters, Che results of several studies on the methanolysis of appropriately 0-isotopically labelled compounds are consistent with reactions proceeding with inversion o f configuration, as observed for all enzymic and non-enzymic systems so far examined; this has resulted in the suggestion that if metaphosphate is actually formed, then it must be in a 'masked' form. In the quest for 'free' metaphosphate, racemization has been observed for phosphoryl transfer from phenyl dihydrogen ( E l - [ 160,170,180]-phosphate to tert-butyl alcohol in MeCN. 28 The solvolysis of isotopically-chiral (S)-adenosine-5'-diphosphate (31) by inter alia tert-butyl alcohol a l s o proceeds with racemization.29 However,the preassociation of metaphosphate with solvent molecules and multiple transfers with other solvent molecules before entrapment by the alcohol has been advanced as an alternative explanation for the racemization observed. Moreover, Ramirez et al. found that the liberation of 2,4-dinitrophenoxide from its monophosphate dianion in aqueous solution is accelerated by pressure, a result not possible to reconcile with the intermediacy of 'free' metaphosphate.30 Other workers have concluded that, for the solvolysis of phosphate monoesters, the bonding between nucleophile and mecaphosphate is not far developed in the transition state and
5: Quinquevalent Phosphorus Acids
143
that the very large rate accelerations observed in enzymecatalysed transfers must depend particularly on the microenvironment:large rate enhancements were found for dipolar aprotic solvents specific for the dianion substrate.31 Compound (32) phosphorylates hindered alcohols in the presence of EtOH consistent with a dissociative mechanism involving a metaphosphate-like intermediate,since it proceeds with considerable racemization at phosphorus(Scheme 6 ) . The extent of phosphoryl transfer which proceeds with retention of configuration is ca. 35% ( i L . ca. 70% racemization); the excess of (SIP configuration would arise from transfer with configurational inversion, and might indicate a relatively 'free' metaphosphate but is also consistent with the preassociative mechanism discussed above. 32 33 The involvement of monomeric metaphosphate in the phosphoryl transfer from phosphate monoesters, and of pentaco-ordinate intermediates from phosphotriesters represent two extremes in the mechanistics of the phosphoryl transfer process. Between the extremes are the ( S N 2 ) p processes involving transition states having various bond orders, but no true intermediates. The conclusion reached from a study of the hydrolysis of j180]-glucose-6-phosphate was that the total bond order izo phosphorus is not conserved in the transition state.34,35 Evidence has appeared suggesting the participation of pentaco-ordinate intermediates in the reaction between phosphorothioic acids (Scheme 7 : RL=Et or Ph) and carbohydrate epoxides. The reactions were followed by 31P nmr spectroscopy and signals were observed corresponding to the 2-alkyl esters (33), the isomeric 9-alkyl esters ( 3 4 ) and also stereoisomeric forms of the 1,3,2-oxathiaphospholane (35), the formation of which was favoured for R1=Ph presumably because of the better leaving character of PhO-, but the equilibrium can be shifted towards (35) by removal of EtOH. Since (35) cannot be the intermediate between (33) and (34), there must be another, and this is purportedly the pentaco-ordinate species which undergoes pseudorotation. 36 In the reaction between nucleotide cyclic 0,0-3',5'-phosphorothioic acids with styrene oxide, oxidation is accompanied by extensive rearrangement of the six-membered ring to the Fsomeric cyclic 2',3'-phosphate.37 An interesting communication concerns an attempt to quantify bond orders in thiophosphoric acids using 34s and 36s-
Organophosphorus Chemistry
144
( 31
S-
0-
I
EtOP-0-P-0
II
0
(32)
I
0 . ~ ~ 0e ,= o 17
, o =18o
-
II 0
yo
MeS
/ \ -
0
EtO
0
0 It
S P(OR’),,
2
0
Scheme 6 R2
0
\
R’O-P-S
I
I\
R’O OH
2
R2CP,0R1 o-p\
I
0R’
OH
11
(33)
R‘
(35)
R2=
F0Y0
1””
(34)
0
O+Me Me
Scheme 7
145
5: Quinquevalent Phosphorus Acids
induced perturbations of "P chemical shifts for the model compounds ( 3 6 ) and (37).38The results have suggested chat che negative charge in the anion of the hvdrolysis product (38) is located on sulphur with the phosphorus-sulphur bond of order 1. This is in agreement with earlier measurements of l 8 O perturbations of 31P chemical shifts in 0-alkyl and O,O-dialkyl phosphorothioates. An X-ray analysis has confirmed the structure of the product ( 3 9 ) formed when 2-aminobenzamiae is heated with P4Sl0 in pyridine (there is no reaction in toluene,. In the presence of alkali, dimethyl sulphate converts ( 3 9 1 into (40; R=SMe) which, in turn, yields ( 4 0 ; R=C H N or PhNH) by reaction with pyrrolidine or aniline. 34 In the synthesis of butenolides substituted in a position adjacent to the carbonyl, the bis(dimethy1amino)phosphinyloxy group has been employed for the direction of an incoming electrophile (Scheme 8).40 Azines have been prepared by initial condensation of diethoxyphosphinylhydrazine anions with aldehydes or ketones (Scheme 9 ) . Phosphoryl azides undergo 1,3-dipolar cycloaddition to 2-tetralone enamines to give triazolines, possibly en rouce to amidines.42 A full paper on the addition of diethyl dibromophosphoramidate to alkenes(1eading to the synthesis of 2-bromoalkylamines) has appeared.4 3
'+'
The phosphorylation of alcohols by CEP-imidazole" (41;X=N)with CEP-ring retention is already well-established. Following from the observation that CEP-pyrrole (41;X=CH) phosphorylates alcohols with CEP-ring opening, an explanation has been advanced based upon the differences in apicophilicities of the pyrrole and imidazole moieties in pentaco-ordinate intermediates (Scheme 10).44 A scale of relative reactivities based upon the reactions in the equations + Azole' , k CEP-Azole2 + Azole 1 CEP-Azole' .t*
-1.
CEP-Azole + TMGH"" 7 --l CEP-TMG + Azole was drawn up for a series of azoles and also for N , N , N I N 1 tetramethylguanidine and its derivative (45).Increased replacement of N by CH leads to decreased reactivity towards both TMGH and other azoles. CEP-pyrrole cannot be prepared from
CEP
.,-.to
cyclic enediol phosphoryl ;
I\
I\
TMGH
=
tetramethylguanidine
Organophosphorus Chemistry
146
(36) X = S , Y = O (37) X = O , Y = S
(38)
H NH
S
R
(39)
(40)
Reagents:
i, BuLi ;
ii, E+
; iii, HCOOH
Scheme 8
Reagents:
i, R1R2C0
; ii, NaH ; iii, R3R4C0
Scheme 9
147
5: Quinquevalent Phosphorus Acids
OR
Scheme 10
'PN
11
Me
\
Scheme 11
NMe,
148
Organophosphorus Chernistry
other CEP-azoles by reaction with pyrrole because the latter is insufficiently nucleophilic, but zhe nucleophilicity of TMGH allows the preparation of CEP-TMG from CEP-azoles; both CEP-pyrrole and CEP-imidazole react with TMGH with complete CEP-ring retention. Such a contrast to the behaviour of CEP-pyrrole and CEP-TMG towards alcohols is explicable assuming that the pyrrole moiety i s apicophobic. In Scheme 11, therefore, for X=CH, (421-4431 and, because the strong basicity of TMGH prevents protonation of ( 4 4 ) the ring-opening reaction cannot be driven to completion. However, the conversion of (44) into (43) with expulsion of TMGH, and hence ultimately into (451, are possible. The lack of reactivity of (45) and CEP-pyrrole towards alcohols is attributed, at least partly, to the double bond character of the phosphorus-nitrogen bond as evidenced by the crystallographically determined abnormally short P-N bond lengths. A problem of a related nature concerns the reactivity of the cyclic diamides (46):marked differences are to be observed in methanolysis between, on the one hand, (46; R=Ph or OPh) and (46;R=MeNH)on the other. In all cases ring opening occurs to some extent although in different ways (Scheme 1 2 ) . 45 F o r (46;R=OPh)ring retention is also observed. The lower reactivity of (46;R=MeNH)is possibly linked to the smaller endocyclic NPN angle (demonstrated by X-ray analysis) and a high degree of coplanarity of the phospholidine ring with possible resonance interactions between endocyclic nitrogens and carbonyl and phosphoryl groups. Both ring opening and ring retention are observed in the interaction of (46;R=PhO)and anisidine, and here reaction occurs at both the phosphoryl and the carbonyl (giving (47)1 groups, whereas with a sterically hindered amine reaction occurs only at a carbonyl group. With a more reactive primary amine, e.g. benzylamine, the initially-formed (48) cyclizes spontaneously to (49). Continuing their studies on analogues and derivatives of cyclophosphamide as agents for cancer therapy, Luaeman et al.have synchesized the phosphoramidates (50 a,b,c; R=Me or Ph) by established methods and have studied their r e a ~ t i v i t y .By ~~ contrast L O aldophosphamide (50a; R = H ) whicn unaergoes tautorrieric cyclization to (51a ; R=H), '4-phenylketophosphamide'. (50a; R-Ph) and to a lesser extent the methyl analogue, are resistent t o t h e change. In aqueous solution the phenyl compound(50a; R=Ph) is converted into the diamide (52) faster
5: Quinquevalent Phosphorus Acids
I49
Me
(47) Me
(46)
(MeO),P(O)NHMe Reagent :
+
( CONHMeI,
i , MeOH
S c h e m e 12
(48)
(49)
R '3
'
H2°2
OPNHR'
I
N R2R3
R'CH=CR
2 ~ ~CH,3 = (53)
+
C I C HR' C R L CR 3CH2P(0)CI
150
Organophosphorus Chemistry
H;)
bH
0 (57)
(56)
(58)
COOR
0 ( R’
II
R2
0
II
I
o i2p-c H - P z
( Me3SiO),P(X)COOR
(60)
0
(61)
0
I
(EtO),!-CHGR’
It
(R0I2P<
‘
X
II
O
( R O ),PCH(OR),
0
OR2
PhCH20-
Met( Me
0
OCH2Ph
5: Quinquevalent Phosphorus Acids
151
(by a faccor of 3 ) thar, (50a; R=Me!. 2.Phosphonic and Phosphinic Acids and their Derivatives 2.1 Synthesis of Phosphonic and Phosphinic Acids and their Derivatives.-The phosphonium adductsfrom PC15 and alkyl vinyl ethers are converted into the corresponding phosphonic dichlorides by hexamethyldisiloxane. 47 Oxidative phosphorylation of the 48 1,3-butadienes ( 5 3 ) affords the phosphonic dichlorides ( 5 4 ) . The reaction between 2-adamantyl halides and PC13/A1Br3 yields a mixture of di-2-adamantylphosphinic chloride and bromide together with (l-adamanyl)(2-adamantyl)phosphinic chloride; 1-adamantyl halides are already known to afford only 1-adamantylphosphonic acid derivatives.49 An Arbuzov reaction between gem-dibromocyclopropanes yields phosphonate esters (553 accompanied by debrominated compounds;successful reaction requires the presence of traces of water !and is thus not the 'normal' Arbuzov reaction) which, 50 by studies with D20, has been shown to supply the a-proton of (56). 'Normal' Arbuzov reactions, using ethyl diphenyl phosphite, have been used to prepare a phosphonate isostere of B-D-arabinose1,5-diphosphate.51 Trimethylsilyl esters of arylphosphonic acids have been prepared by Ni-catalysed Arbuzov reactions between aryl bromides and tris (trimethylsilyl) phosphite.52 NiC12 also catalyses reactions between 2,5-dibromothiophene and phosphonous ( or phosphinous) esters to give the compounds ( 57 1 . 5 3 Pd compounds in the presence of triethylamine catalyse the phosphination of 1-bromoalkenes with alkyl phosphinates to give the esters ( 5 8 ; R 1 ,R2 , R 3=H,Me, or Ph; R4 =Me or Ph; R 5 = Et or B u ) and ~ ~ the phosphonation of iodoaromatics with dialkyl
phosphonates, although in this case with poorer yields (better results of the dialkyl arylphosphonates are obtained by photostimulation). 55 Chemical oxidation (using AgN03-peroxodisulphate) and anodic oxidation of aromatics in the presence of trialkyl phosphites produces dialkyl arylphosphonates in good yields. 56 The CuI-catalysed arylation of dialkyl (cyanomethyl1 phosphonates affords dialkyl (a-cyanobenzyl)phosphonates.57 Several phosphonodicarboxylates (59; R=Et; X=H or Me) and the corresponding acids have been prepared by typical active methylene reactions,during a study of the oxidation of
152
OrganophosphorusChemistry
3-phosphono-3,5,5-trimethylcyclohexanone ,58 and reactions between the lithium complexes of phosphonic esters (R’O) 2P(0)CH2R2 and the chlorides Z2P(0)C1 (Z= EtO, Ph, or Me2N) have given the compounds (60).59 The phosphonoformic esters (61; X=O, S, or Se; R=Me or Et) have been prepared conventionally from bis(trimethylsily1) hypophosphite.60 SnCl4 catalyses the formation of the (a-aryloxybenzyl) phosphonates (62) from diethyl trimethylsilyl phosphite and (dialkoxymethyllaryls.61 In a similar reaction, 2-alkoxy-1 ,3-dioxolanes with ZnC12 yield the phosphonates (63),62 whilst mixtures of trialkyl phosphites or mixed phosphites (Et0I2PR (R= MeCOO or Me3Si0, for example) and orthoformic esters in the presence of BF3.Et20 yield the esters (64). Other reactions using alkoxy-4chlorophenoxymethanes are also catalysed by BF3.Et20, but best results in the synthesis of diethyl or diphenyl (alkoxymethy1)phosphonaces are achieved using TiC14 catalyst at -78OC.This last process presents certain advantages over the more conventional Arbuzov process, not least of which is the mildness of the reaction conditions. A potentially widely applicable procedure, viz. alkoxide displacement on (sulphonyloxymethy1)phosphonates leads to an unusual ring enlargement in the case of the 1,3,2-dioxaphosphorinane (65).63 Two papers describe the hydrophosphonation of unsaturated cyclic hydrocarbons. With dialkyl phosphonates, cycloocta-lY5-diene affords the phosphonate esters (66) but in the presence of strong acids, or when using the moderately strong H2P(0)OH itself, the monocyclic esters (67) are also formed. Cyc1ododeca-ly5,9-triene affords a mixture of polycyclic phosphonate esters of which (681, (691, and ( 7 0 ) have been identified.64 Compound (711 is the initial hydrophosphonation product from the tricyclo[4.2.2.02’5]deca-3,7-diene dicarboxylic ester illustrated, and may be further hydrophosphonated; (71) has been characterised crystallographically.65 The ester (72) (with the OH group appropriately protected) has been transformed into the phosphacyclohexane (75) by way of (73) and (74) by processes of reduction, acidolysis, and peroxide oxidation. Variations of this procedure are also described.66 Improved syntheses of diethyl [ (phenylsulphonyll68 methyl j ~ h o s p h o n a t eand ~ ~ bis (diphenylphosphinic) peroxide have been reported. Bis(2,2,2-trifluoroethyl) hydrogen phosphonate has been synthesized and its use in the synthesis of
5: Quinquevalent Phosphorus Acids
153
03 (66)
(67)
P(O)(OR
PI0 )(OR 12
COOMe COOMe
COOMe
COOMe
0
II
b0
X,PCH,
Of
Me
( 7 2 )X = O E t ( 7 3 )X = H
0 HO@OH
Me
OH
( 7 4 )Y = H (75) Y = O H
154
Organophosphorus Chemistry
phosphoric mono and diesters investigated.69’70 Ths vinylphosphonic esters (77) are obcainable by distillation of the phosphite esters (76)(Scheme 13).71 No reaction takes place at the vinyl halogen during the preparation of the esters (781, but the interaction of phosphonites and 2-chloroacetimidoyl chlorides is accompanied by proton migration. 72 An adaptation of the Arbuzov reaction (Scheme 14) using the hydrazones of 1-chloroalkyl ketones provides a route to dialkyl (2-oxoalkyl)phosphonates (79; R 1=Me, C1CH2, Ph, EtOOCCH2, or 2 73 (EtO)2P(0)CH2; R =H, generally; R3=Me0, EtO). In a paper concerned primarily with the use of epoxyalkylphosphonates in the synthesis of heterocyclic compounds, the (epoxyalky1)phosphonic esters have been obtained, accompanied by (2-oxoalkyl)phosphonic esters (81) in the reaction between the alkenephosphonates ( 8 0 ) and alkaline hydrogen peroxide.74 Where there exists a choLce of double bond capable of being epoxidized, as in the 1,3-butadienephosphonic esters, peroxytrifluoroacetic acid reacts at the double bond distant from the phosphoryl centre;thus (821 gives (831 . 75 Epoxidation of the phosphonates (84) by MCPBA yields mixtures of erythro-and threoproducts (85; R 1 ,R2= H or Me; R3=Me, Et or PhCH2), the reactions for the (Z)-(84) being highly stereospecific. For the phosphinates (84; R 4=alkoxy; R5=aryl), the (Zl-form reacts more selectively than does the (El-form.76 Preparations of a-diazophosphonoacetic acid derivatives have been described. 77 Thus far, ( a-diazoalkyl)phosphonic and -phosphinic acids have been known only as their esters. The phosphinic esters (86; R1=H, Me, Ph, PhCH2, PhCO, and MeOOC; R2=Me0; X=Ph) have now been dealkylated with bromotrimethylsilane to give the compounds (86; R2=Me3SiO) and both the methyl and trimethylsilyl esters react with tert-butylamine to give salts of the free phosphinic acids. A similar sequence furnished salts of the compounds (86; R1 as before; R 2=MeO, Me2N or Et2N) and thence the phosphonic acids (86; R 1=PhCO or MeOOC; R 2= X = O H ) . 78 The threo-formsof the (1,2-dihydroxy-3-oxoalkyl)phosphonates (87)act as useful precursors in the synthesis of a wide variety of other phosphonic acid types (Scheme 1 5 ) . 79 Et2NSF3 is a useful reagent for the low temperature conversion of the (hydroxyalky1)phosphonic esters (88;X=OH;R=allyl, or aryl) and (89.) into the corresponding (fluoroalky1)phosphonic acid esters. 8o
5: Quinquevalent Phosphorus Acids
155
Me 0 .. II I II M e C C H C l C M e __i_) ( RO$POC=CCMe 0
0
II
It
0
.
i
I
Me
(77)
(76) i , (RO)2W:
;
I,,
II
+(R0I2PC=CCICMe
CI Reagents:
0
It
Ill
I
i i i , heat
;
Et3N
Scheme 13
R2
R2
R2 . . ...
II > I l l
'
R'+CI NNHCOOMe
Reagents :
R1+P=":
N N HCOOMe i , R;POR4
;
ii . Me2C0
0 ;
iii , H30'
11
0
(79)
S c h e m e 14
0
0
+ (80)
0
II
(R'O),PCH,COR~
(81)
R
156
OrganophosphorusChemistry
U
0
0
II
II
-
( R~ oi2 PCH~CHCR'
I
OTs
Reagents:
i,
'
\"
Os04, H202 ;
0
II
CN I
I R'O),PCH,CHCR~
II
0
+
(R'O),PCH,
+
(R~O)~PCH=CCR~
0 0
0
ii, TsCl, pyr. ;
0
0
II
II
I
iii, H2-Pd ; iv; BU4NtCN-
v, Eiu4X!+N3S c h e m e 15
OEt
R
R
0
R
OEt
R
5: Quinquevalent Phosphorus Acids
157
Migration of phosphorus €rom oxygen to aromatic carbon is induced by Lithium diisopropylamide and provides a convenient route to esters of (2-hydroxyary1)phosphonic acids (90) and bis ( 2-hydroxyaryl Iphosphinic acids (911 . Interaction of chlorides of tervalent phosphorus and phenols, particularly those in which the hydroxyl group is sterically hindered, leads to 5-phosphorylation, and the products may be oxidized to esters or (4-hydroxyphenyl1phosphonic acids; (&hydroxy-3,5-di-tert-butylphenyl )phosphonic acid was thus prepared.82 ihe reaction between sterically hindered phosphorous chlorides (92; n=O or 1 ) and benzyL alcohol affords the phosphonates ( 9 3 1 .83 The bisphosphonic acid 1 9 4 ) has been prepared and its chelating properties investigated.84 Methylenebisphosphinic acid (95 has been described and its crystal and molecular structure determined. 85 Pd(PPh3j2Ll2 catalyses the internal alkylatjon of the phosphonate esters ( 9 6 ) and the formation of the 3-methyLene-lo x a - 2 - p h o s p h a c y c l o a l k a n e 2-oxides (971, phosphorus-containing analogues of a-methylenelactones ." Further examples of the lY3,2-dioxaphosphorin system (991 have been prepared as indicated with the esters (98) as isolable intermediates.87 The related compounds (100;R-Et or Pri) are obtained by a rearrangement process at room temperature.8 8 Studies described in earlier Reports have shown that the diketone (101; _n=3) reacts with dichloromethylphosphine/acetic acid to give the bicyclic anhydride (102). but such a reaction does not occur with MePC12/A1C13. A new paper now describes reactions of the diketone (101; n = 4 ) with MePC12/CH3COOH. These reagents yield (103). Evidently the acidity of unpurified chloroform is 'sufficient to transform 11031 into the phosphinic acid (104);other reactions are illustrated in Scheme 16. Using the unsaturated ketones (105) and (106!, the bicyclic 1,2-oxaphosphole derivatives (107) and (108',respectively, were obtained; the structure of the latter was confirmed by X-ray analysis. The tautomeric nature of (1081 is evidenced by its reaction with diazomethane to g i v e the methyl ester of the phosphinic acid (109).8 9 The preparation of the 1,3,2,4-dithiadiphosphetane 2,4-disulphides (110; R=Me, Et, Pri, or Ph) has been described. 90 Some new sulphur-containing compounds including the oximino esters (111; isolable as their methyl esters) and the dihydro-
Organophosphorus Chemistry
158
.CI i Me3C
Me3C
R
O
Me
159
5: Quinquevalent Phosphorus Acids
Br 0
(105)
0
Ph
Ph
(103) Reagents:
i , Mepc12, MeCOOH ; ii, k120
iii, Br2
;
iv, E30+
S c h e m e 16
,
0
160
Organophosphorus Chemistry
1,3,2-thiazaphospholes (112) have been obtained from oximes by reaction with 2 , 4 - b i s ( 4 - m e t h o x y p h e n y l ) - 1 , 3 , 2 , 4 - d i t h i a d i p h o s p h etane 2,4-disulphide (Lawesson's reagent;LR). Depending on the nature of R in (1131, it is also possible to prepare the 91 dihydro-1,3,5,2-oxathiazaphospholes (114). Details have appeared of reactions which occur between 2,4,6-tris-tert-butylphenyldithiaphosphorane (115) and MeOH, to give ( 1 1 6 ) , and 2,3-dimethyl-1,3-butadiene, when (117) is formed.92 Scheme (17) illustrates the synthesis of the diphenyl ester (118) of (1-amino-2-propeny1)phosphonic acid (1191, an acid which is a strong inhibitor of the alanine racemases from P-aeruginosa and &faecilis.93 Other aminophosphonic acids prepared by a variety of methods include the compounds (120-1281 94-97 The Arbuzov reaction was employed in the preparation of the"-(phosphonoacety1)-1-aminoalkyl]phosphonic acids (Scheme 18) and the same publication describes the acids (129-131). N-(Phosphonoacety1)-L-aspartic acid is of particular interest since it is a tumour inhibitor active against several transplantable tumours;lung carcinomas and melanomas are very sensitive to this compound, but leukemias and bladder cancers are unaffected.98 A convenient synthesis of (aminomethyl)phosphonic acid proceeds through its N-benzoyl derivative.99 A successful synthesis (Scheme 19) of the phosphonic acid analogues of S a n d L-penicillamine commences with the cyclic phosphorochloridite (132). Other attempts using (132; R=Me or COOEt 1 failed.loo 2-Amino-4-phosphonobutanoic acid , the phosphonic acid analogue of glutamic acid, has been obtained in resolved forms by the action of papain, followed by aniline, on 2-benzoylamino-4-(diethoxyphosphinyl)butanoic acid when anilide occurs preferentially for the L- compound. Enantiomers of 4-amino-4-phosphonobutanoic acid were obtained by resolution of the N-benzyloxycarbonyl diethyl ester derivative with 1-phenylethylamine.101 Bromination of the (acylarninomethy1)phosphonic esters (133) and subsequent dehydrobromination, leads to the (acyliminornethyllphosphonate esters ( 1 3 4 ) , precursors to a variety of phosphonate types (Scheme 20). Treatment of (134) with Grignard reagents ( R 2=vinyl, phenylethynyl, or 1-naphthyl) affords the a-substituted esters (135). The bisphosphonic acid derivatives (136; R 2 =Me or Et) are obtained through Arbuzov reactions. A two-stage process provides the alkylated derivatives
161
5: Quinquevalent Phosphorus Acids
S
\\
2, / S R
1 2
R R C=NOH
RS
LR
S
(11 0)
LR
(116)
But (115)
II
R’R~C=NOP-SH
Organophosphorus Chemistry
162
0 ( P hO l,P(
II
PhS-
01
P(OPh),
NH2
Ph
It
s-fp(o NH2
0
0 II
0
0 II
v
__* q / P ( OIIH ) 2
~ P ( O P h ) zv i
~
Ph I2
NH2
NH 2
(118)
(119)
i, MeCOOH ; ii, F'hSCK2CH2CH0 ; iii, PnCF!;,9XJM12
Reagents:
; v, heat
iv, H202, MeCOOH
Scheme
\
R
; vi, H30+
17
N HCH2CO0E t
COOH
(mg5
( 1 2 0 1 ~ '=~H (121 l9'R = CH,COOH
I123 1''
,
@c H, NH CH co o H HOO,T")@ N 95
1127Ig6R= H or Me
( 125 Ig5
(121) n = 0,l R HOCH,CH,NCH
(126)96 @CR~NHCH,C%OH
( n C 0 O H !Hz@
H
R 2C HC HN , CH,CH ,OH
I
OH
@
(l28Ig7R = CH2@ or CMe2@ 0
= P(0)(OH12
0
I1
( R' 0 l2 P CR2 R N H CO C H2C I
\L
II
II
( HO),PCR2R3N HCOCH,P(
0
It
0
( R'O),PCR2
Reagents:
0
II
/ l l
R3NHC0CH,P(OEt),
i , (Et0)3P
;
ii, MeCixIH, HBr.
Scheme 18
0 H,)
5: Quinquevalent Phosphorus Acids
163
@ CH,CON H C H R’ I
CHR~
I
( 1 2 9 )= ~ COOH (130)R’= @ (131) R’=COOH
I I
R~=COOH
@
R2=COOH
, R2=
i
@
= P(O)(OH),
(1321
Ill
R = CMe,(OMel
HNXS
H N X s
Me
Me
‘Ho12p+Me SH H NH,
Reagents:
i , Me3COH ;
“x’ Scheme 19
ii, BF -Et20 ; iv, H30+ 3
164
Organophosphorus Chemistry
(137; R1=4-chlorophenyl).102 Scheme 21 summarizes further reactions leading to phosphonic acid analogues of amino acids. Treatment of the nitrone (138; R1=Me or Pri) with a dialicyl hydrogen phosphonate (best as the Li derivative which shows greater diastereoselectivity than the Na or K salts), and subsequent steps involving acidolysis of the oximino compound (139) lead to the free (a-aminoalky1)phosphonic acids (140)(phosphonoalanine, phosphonovaline). As an alternative process, the nitrone (138; R 1 =CH20CH2Ph) yields a mixture of diastereoisomeric (benzyloxymethy1)phosphonic derivatives of which (141) is the main component;acidolysis and hydrogenolytic debenzylation lead to phosphoserine (1431, the (S) chirality of which was demonstrated by X-ray analysis of the derivative (144). In a further variation, the di-tert-butyl ester analogue of (142) was employed, the ester groups being removed by acidolysis.103 Several acyl derivatives of (aminomethyl)-and (1-aminoethy1)-phosphonic acids, in the latter case including [L-1-([L-alanyl]amino)ethyljphosphonic acid (alafosfalin), have been prepared in their various diastereoisomeric forms and the relationship between structure and biological reactivity discussed.104 (2-Aminoethy1)phosphonic acid occurs in many aquatic and terrestrial animals as well as microorganisms, and their lipid fractions arethe most abundant source of the glycerophosphonolipids based upon that acid. Examples of such phosphonolipds have been prepared by a condensation between the glycerol esters (145;R=C15H31C0 or C18H37CO) and the phosphonic derivatives (146;R=H or CH2Ph; n=2 or 3) in the presence of TPS-C1; the phosphonolipids are obtained by a final hydrogenolysis; the same products (147) can also be obtained through the use of the phthalimide derivatives (148) the protecting group being removed with hydrazine. 105 Spontaneous dimerization of the benzylideneamido phosphites (149) yields dihydrodiazadiphosph(v)orines (150;R=Et, or (RO) -ethylenedioxy or phenylenedioxy) lo' whilst similar 2starting materials are stated to give the diazaphospholidines (151; R 1 ,R3=alkyl; R2=alkyl o r Ph) . I o 7 The 1 3-diaza-4,6-diphosphorine derivative (152) i - s obtainable from methylenebisphosphonic dichloride.lo8 The reaction between the d i a m i n o d i a z a d i p h o s p h e t i d i n e (153; R=cyclohexyl) and aromatic aldehydes with the formation of
165
5: Quinquevalent Phosphorus Acids
0
(133 1
Reagents:
(135)
i , NBS, CC14; V,
(p20)3p
ii, E t 3 N
; i i i , R k X i n THF
vii, Et2E
; vi,
Scheme
20
; iv, H301
CMe
;
166
OrganophosphorusChemistry
A
I
Me Me
R’
Ho+ !
R’ ( 139)
J’ii,
H
(138 1
O ‘ NN(
iv
P(01 0 C H,Ph l2 OCHZPh
OH
(1411
Reagents: i, (EtO)$OLi,
CH2C12,
-70’
; ii, H C 1 - k O H
iv, H30+
Scheme 21
; iii, H2-Pd
;
5: Quinquevalent Phosphorus Acids
167
the 1,3,4-oxazaphospholidines (154;R=cyclohexyl), structures confirmed by X-ray analysis, have been discussed in terms of a 109 tricyclic biphosphorane intermediate. 2.2.Reactions and Properties of Phosphonic and Phosphinic Acids and their Derivatives.-A free radical mechanism has been proposed to
acccunt for the cleavage of the phosphorus-carbon bond in the alkylphosphonic acids (155) by E.coli to give a mixture of alkane (methane only, from methylphosphonic acid) and terminal alkene. A much higher ratio of unsaturated:saturated hydrocarbons is observed than in the case of cleavage with lead tetraacetate. 110 Hexamethyldisiloxane converts the chloride (156;R=Cli directly into the anhydride of the acid( 156;R=OH).'I1 The rates of disproportionation of mixed anhydrides from protected 0 a-aminoacids and phosphorus acids are insignificant at 0 C,from a preparative viewpoint, compared with the rates of aminolysis. On balance, diphenylphosphinic and tetramethylenephosphinic chlorides are the best chlorides for u s e in peptide synthesis .'I2 Phosphinic acids in the 3-phospholene series are converted into their diethylamides by direct reaction with TDAP. Alkylphosphonic dichlorides (and even PC13) have been suggested as reagents for the determination of enantiomeric excesses in chiral alcohols and thiols using 31P chemical shifts. Best results are achieved with the smaller alkyl group in the acid chloride and the larger in the alcohol. Derivatives of phosphonoacetic acid and related acids have been acylated (for example to give ( 1 5 7 ) and nitrosated (to give, for example, (158))?16 The latter compound forms blue solutions thought to contain dimeric species. Somewhat unexpectedly. monodemethylation of the esters (159;R=Me) proved impossible using several standard techniques. Deallylation of mono and diallyl ester analogues of ( 1 5 9 1 , and of diallyl and ally1 methyl [ (1-acety1oxy)alkylJphosphonates was however acheived using palladium-containing catalysts, suggesting a potential wider applicability of the diallyloxv117 phosphinyl group in synthesis. Carbanions from tetraethyl methylenediphosphonates have been studied using several spectroscopic techniques The monohalogen esters !160;X=H,Y=Cl or B r ' l have been alkylated via their thallium salts,'l9 and sulphenation of their Li or Na derivatives with CC1nF3-nSC1 has been shown to be a complex
168
OrganophosphorusChemistry
+
0
0 OH
II/
II
PhCH20CNH(CH21,P,
OH
OR
(145)
i TPS-CI
RO Ro{
b0
!'
1 0 CI 2 n 'OH
0
0 PhNKNPh
CL-P-
1
1
II
0
P-CI
II0
(152)
0
0
II
(RO)2PCHCONEt2
I
C H2C0N Et (1 5 7
II t OP (CH2),,NH3 i
(146) @N(CH
0
II
Me
I
( Et0I2P-CCOOMe
1
NO (158)
5: Quinquevalent Phosphorus Acids
169
0:
P h C HO , C0N H
o
I1
x
(Pr'O),P-C-
0
P(OR1,
I
I
0
0
II
I1
P(OPr' I2
( RO),PCFXCOYH
Y
(160)
( 1 59)
(161)
0
0
II
( Et0I2PCF,Li
cs2 Me I
~
II
( E t O),P CF2 C SS M e
0
II
(Pr'01,PCHFLi
0
It
c-52 Mel ( Pr
(1 6 4 )
pXsMe
O I2
F
NuH
SMe
" F
Br
/RO'
Ph Reagents:
i , NBA
Scheme 2 2
CONu
H
170
Organophosphorus Chemistry
process and, depending on the individual sulphenyl chloride, unexpected reactions include the replacement of F by C1, and sometimes loss of sulphur.120 The dihalogen esters (160;X=Y=Cl or Br) are monodehalogenated using KF in MeCN containing a 18-crown6-ether.121 (Fluoromethyljphosphonate ester anions react with C02 or COS to yield esters of the type (161;Y=O or S ) which may be dealkylated to the free acid through the use of bromotrimethylsilane, but the course of the reaction with CS2 depends on the individual ester; thus, (162) yields (163), but (1651 is formed from (164).Iz2 Esters of [1-(diethoxyphosphinyloxy)perfluoro-1-alkenelphosphonic acid appear to be effective reagents for the synthesis of perfluoro-a,B-unsaturated carboxylic acids and their derivatives;presumably an initially-generated perfluoroketene (166) is acted upon by a nucleophile (NuH=RNH2, R2NH, or ROH). The
(E)/(Z-) ratio of the product components increases with increasing length of Rf. 1 2 3 In contrast with the behaviour of typical vinylphosphonic acid derivatives, the carbon-carbon double bond in the 1,2-oxaphospholene ( 1 6 7 ) is remarkably unreactive towards a broad spectrum of reagents including electrophiles, most epoxidizing and organometallic reagents, as well as to dipolar addition reactants. Exceptional reagents are, however, N-bromoacetamide (NBA), ozone, dimethyllithiumcuprate, and sodium-naphthalene. The reaction between (167) and NBA is set out in Scheme 2 2 . In aqueous solution, the reaction proceeds cleanly; ‘H nmr spectroscopic analysis indicates the formation of only one diastereoisomer of the acid (168;R=H);Chis acid was too labile for isolation but was isolated as a 1:l mixture of the esters (168;R=Me) enantiomeric at phosphorus. Ozone reacted slowly with & (169); (167) in chloroform To give phenylphosphonous acid y 124 the last was characterized as (170). The addition of g,g-diethyl hydrogen dithiophosphate to diethyl (3-rnethyl-1,Z-butadiene)phosphonate (171; R = H ) occurs at the 1,2-double bond, but on introduction of a vinyl group (171; R=CH=CH2) addition occurs across the latter to give 125 (172) after rearrangement. Addition of chiral sulphenylchlorides to cyclohexene affords diastereoisomeric mixtures of 2-chlorocyclohexylthio
5: Quinquevalent Phosphorus Acids
171
COOH
Ph
Me
’
M eO “/O ’
‘ 0
(169)
x C I I M e
(170)
0
0
II
( E t O ),PCR=C=CMe,
0
II
(Et0I2PCCH=CMe2
II
(
II
R’0 ),PC
H=C
=C R2R
CHCH,SP(S)(OEt), (171 1
(172)
0
II
( R’ 0 l2 P C H
RLS\e
=CC H R 5CI
I
R2fip:lR, R
SeR
(173)
Ph N H C H, P h
OPr‘
Me
(174)
R10\ /
0
II
-
MeNHNH2
PCH=C=CR2R3
CI
/ \
H2NN Me
( 177)
i
PhNHNH2
(178)
(1 79)
172
OrganophosphorusChemistry
esters Further observations on the addition of sulphenyl chlorides to (1,2-diene)phosphonic acid derivatives ( 1 7 3 ) have been reported.127 For the unsubstituted phosphonates, (173;R2=R3=HI) addition occurs at the terminal double bond to give (174;R5= H )
mainly in the (2) form for R4=Ph, but a mixture of (E) and ( Z ) forms for R4 =Me. For monosubstituted compounds,e.g. (173;R2=Pr; R 3 = H I the formation of acyclic addition product (174; R5=Pr) is accompanied by a small amount of 1,2-oxaphospholene (175; R2gPr; R3=H). Finally, t e r m i n a l l y - d i s u b s t i t u t e d compounds yield 1,2-oxaphospholenes (175) exclusively. The 1,2-oxaphospholene 1176) is formed by the BF3catalysed addition of benzylideneaniline to diisopropyl (3-methyl-l,2-butadiene)phosphonate.128 The course of the reaction between allenephosphonic monochloride monoesters and hydrazines depends on the individual hydrazine and is explicable in terms of the relative nucleophilicity of the nitrogen atoms in each. Thus (177; R1=Me,Et, Ph,PhCH2, or 1-naphthyl; R2 =H or Me; R3=H) reacts with methylhydrazine at the more nucleophilic nitrogen atom, .&i that carrying the methyl group, to give initially the hydrazide (178) which cyclizes t o (179). With phenylhydrazine, the more nucleophilic nitrogen atom is that in the NH2 group, and the reaction course is then (177)+(180)+1181). Depending on the manner of work-up, only one of (180) or (181) is is01able.l~~ Isolable pyrazolines (183) are obtained from the (1,3-butadiene)phosphonic acid esters 1182; X=S02Me, COOalkyl; R 1=H or Me; R2=Me or Ph) (products from (182;X=CN)are thermolabile) and diazomethane. Pyrolysis of the phosphorylated pyrazolines affords phosphonopentadienes rather than phosphonocyclopropanes (contrast (184)) and with NaH give pyrazoles or pyrazolephosphonic acid esters.130 Interaction of ( 173;R2=R3=Me1 and chromyl chloride affords the (cyc1opentenone)phosphonic esters (185). I 3 ' (a-Hydroxyalky1)phosphinic acid esters (186; R1,R2= H, or alkyl) are deoxygenated when treated with P214 yielding the compounds (187).132 The ester (188) rearranges to (189) in dry alcoholic(ROHI-HC1.133 In a useful communication, the cd and absolute configurations of the (a-hydroxybenzylphosphonic esters (190) have been reported. Normally obtained in small (10% for R1=R 2=Me; X = C 1 ) to medium (20% for R1=R 2=Pri; X=C1) enantiomeric
173
5: Quinquevalent Phosphorus Acids
(193) X = OSO,CF, (194) X = OCH,P(O)(OEt), ( 1 9 5 ) X . NR, or OAr
174
Organophosphorus Chemistry
excess, this can easily be raised by crystallization. The dextrorotatory compound (190;K1 =R 2=Me; X=C1) was shown crystallographically to have the (2)configuration.134 The decomposition of n i t r i l o t r i m e t h y l e n e t r i p h o s p h o n i c acid in acid solution has been studied. At 125-175O and pH 1.5, carbon-phosphorus bond cleavage occurs, but in 3M HC1 aq. carbon-nitrogen fission becomes important.135 A spectroscopic study of the esters (191) and (192) (R=H,C1,Br,N02,Me0,Me2N) has shown that the C=C, P=O, and C=O bonds are coplanar with, in (1Y2), a trans arrangement between the benzene ring and the ethoxycarbonyl group. It then becomes easy to explain the dephosphorylation which occurs when such esters are treated with aqueous alkali by postulating attack by HO- on the B-carbon of the carbon-carbon double bond.136 ' h e successful synthesis of diethyl phosphonomethyl at higher temperatures triflate ( 1 9 3 ) is possible only at (-15%; formation of the ether (1Y4) becomes important and exemplifies the further reaction with nucleophiles, including R2NH and ArO-, from which the esters (195) are obtained.137 in acetic acid, or aqueous acetone with subsequent treatment with acetic anhydride, the esters (196; R=4-MeO or 4-MeS) give rise to the expected esters(l97) or (198). For the 4-chlorophenyl derivative, a mixture of the unexpected products (199, 200; Ar=4-chlorophenyl) was obtained. The unsubstituted compound (196;R=H) gave only (1Y9) in aqueous acetone, but ( 2 0 0 ) in acetic acid. The postulated mechanism tor such a rearrangement centres around pseudophosphonium and-or phosphorane intermediates. The ester (201) also yields a mixture of rearranged and non-rearranged products. 138 Several communications have described uses for Lawesson's reagent and related compounds. Carboxylic acids have been the use of the reagent converted into their dithio analogue;13' as a peptide coupling agent proceeds with low racemization. 140 The products from the reagent and alcohols depend on the nature of the alcohol. Primary alcohols yield the esters (202) from which several derivatives have been obtained. When the -p-toluidine salts of (202) are heated in xylene, the phosphonamidodithioates (203) and the phosphonodiamidothioate (204) are formed. Tert-butyl alcohol presumably yields (202;R=CMe3) initially but at the reaction temperature butene is evolved
175
5: Quinquevalent Phosphorus Acids
r
1
OMS
OR
(197) R = H (198) R = Ac
(1 9 6 )
1
\
s
/’
C H 3CHP ( 0Et l2
Ar CH-P(OEt),
I
I
OMS ( 201 1
(i:;R=H
(200)R = Ac
Ms = 2 , 4 , 6 - t r i m e t h y l benzenesulphonyl
0 2CNH SR
Me 0
(202)
(204)
Me
(203)
S
s”’
‘Ar
II ArPI
RO
S
0-
II
PAr
I
OR
(205)
Ar = I - MeOC6HL
Ar t I
- Me OC6 HL
176
Organophosphorus Chemistry
and (205) is formed; in the presence of -p-toluidine (204) is once again produced, together with, for a reaction using 1-phenylethanol as substrate, (203; R=CHMePh) and (206; R 1=R 2=CHMePh). In the presence of pyridine, 1-phenylethanol gives the trithiophosphonate (206) as the sole product. 2-Butanol and cyclohexanol yield 141 0,O-diesters of type (207); phenol behaves similarly. Lawesson's reagent converts pyrrolidone derivatives into thioxopyrrolidones and peptides into thioxopeptides.143 N,N-Diacylhydrazines have been shown to yield 2,5-disubstituted1,3,4-thiadiazolesand 5 - p h e n y l - 1 , 3 , 4 - t h i a d i a z o l e - 2 ( 3 H ) - t h i o n e s ; in the case of N-acetyl-N'-ethoxycarbonylhydrazine, the thiadiazaphosphole ( 2 0 8 ) has been characterized by spectroscopic means.144 Other reactions which have already been discussed are those with oximes. The oxidative desulphurization of mono and dithio phosphonic and phosphinic acid esters may be carried out using hypochlorite.145 The stereochemistries of the reactions between g-aryl 0-methyl p h o s p h o n o c h l o r i d o t h i o a t e s and nucleophiles have been studied in relation to the synthesis of 1,3,2-oxazaphospholidines. No displacement of chlorine takes p l a c e on treatment of 2-methyl 0-4-nitrophenyl p h o s p h o n o c h l o r i d o t h i o a t e with 2-methoxyethanol, and in the presence of 1-phenylethylamine, it is only the latter which reacts. In addition, when the same phosphonochloridothioate is treated with sodium ethoxide, it is the 4-nitrophenoxy group, rather than chlorine, which is displaced. Both displacements were shown to occur with inversion of configuration at phosphorus. The use of such an acid chloride as a two-step 'cyclophosphorylating' agent of 2-aminoalcohols to give 1,3,2-oxazaphospholidines ( 2 0 9 1 , is illustrated.146 Differences in chirality of substrate, and nature of solvent, have no effect on the competitive nature of the displacement of 2-alkyl and S-methyl groups in the reactions between (+I-pinacolyl alkoxide and 0-ethyl (and methyl) S-methyl methylphosphonothioates (Scheme For the ( E l - ( + 1 esters , e.g. (2101, the displacements are highly stereoselective and occur with configurational inversion,but the enantiomeric esters do not display such stereoselectivity. (-)-Menthol might be considered a mirror image of (S)-pinacol, and similar reactions with the sodium salt of (-)-menthol occur highly stereoselectively
177
5: Quinquevalent Phosphorus Acids
S
OH
OMe
(2081
(209) 0
II
I
P
1
( Pin0I2P(O)Me
MeS’“ \Me OPin
Iii
II
P / ’ I \ Me Me 0
SMe
MeO’
1
” p\
Pin = pinacolyl
OPin
Me
Reagents:
i,
;
Scheme 2 3
ii, M ~ O -
178
Organophosphorus Chemistry
with the (?)-(-I esters but not with the enantiomers. Methoxide displaces the 5-alkyl group only. The effects of leaving group, solvent, and nucleophile, on the kinetics of aminolysis of a series of substituted aryl diphenylphosphinates and their mono and dithio analogues have been investigated.148 For the dithiophosphoric acid esters (211; R 1=R 2=alkylO) earlier work has already shown that methyl isocyanate (212; R 3 =Me) reacts with (211) under mild conditions to give the corresponding (2141, stable at room temperature, presumably y & the rearrangement of ( 2 1 3 ) (route b). At higher temperatures the products are the corresponding (215) and (216)(route a). A similar behaviour has now149 been shown for (212; R 3 =Et) but for isopropyl isocyanate, only route b is involved. The S + N rearrangement is inhibited in the case of the phenylphosphonate esters (211; R 1=alkylO; R 2=Ph) and diphenylphosphinic esters. The analogous behaviour of ?,2-2,3-butylene 2-trimethylsilyl phosphorodithioate suggested the possible intermediacy of the four-membered-ring phosphoranes as depicted in Scheme 24. A reaction between the bicyclic thiaphospholes (217) and alcohols occurs only in the presence of triethylamine. T h e products are ( 2 2 0 1 , probably formed by the dimerization of (2191, and the 2-alkoxy-1,2-thiaphosphole derivatives (218). Analogues of the latter are obtained with -p-toluenethiol and dialkylamines. The compound (217; R=Ph) is more reactive than (217; R=CMe3) and will react with aniline on addition of triethylamine even at room temperature, from which the formation of (221) was observed by spectroscopic characterization. Even more reactive is cyclohexylamine which furnishes an analogue of (221) without addition of strong base. 1 5 0 The phenylphosphonic diamides (222; X=O or S 1 15' and (223)152 are new condensing agents for the preparation of amides and esters of carboxylic acids. Interaction of allylphosphonic bis(dimethylamides1 and Schiff's bases ( 2 2 4 ) at low to moderate temperatures leads to both a and y adducts, but the rates of formation of these depend on reaction conditions and on steric effects of substituents in the base. For (224; Arl=Ph; Ar2=2-chloroor 2,4-dichlorophenyl) only the y adducts are formed. l-Aryl-1,3-butadienes are produced when the initial adduct anions are heated. 1 5 3
179
5: Quinquevalent Phosphorus Acids
.
-
R' Rt.
I
R'
Me3SiS'A,!o 'P-NR3
S
II
'POSiMe3
2/
-4-
R3NCS
R
-I
S S R''P-N,COSiMe3 II II
2'
R
(214)
Scheme 24 Ar
R
-[
(218)
( 2 1 91
Ar
Ar
PhN=P$Ph \
s-s
(2211
I \ X
K0
yh
1 Kx 0
N-P-N
nN-P-NYh n KS ys S
S
180
Organophosphorus Chemistry
Molecular geometrical differences between the amides (225) and (2261, the latter having the more pyramidal arrangement around nitrogen, have been correlated with the known differences in their solvolytic behaviour.154 Treatment of the sulphonate esters of N-phosphinylhydroxylamines with a strong base such as methoxide often results in a Lossen-like rearrangement. Thus with methoxide in methanol, the N-(arylphenylphosphiny1)hydroxylamine 2-methanesulphonates (227; R 1=Ph; K 2=Ar; R 3=Me) rearrange with competitive migration of Ph and Ar groups. For the -p-substituents,MeO, Me, C 1 , and NO2, the relative rates for ArIPh migrations are 30-35, s . 3 , 0.7, and 0.06; thus electron release into the aromatic ring encourages migration of that ring.155 Such a migration could conceivably (but is very unlikely to) occur through a phosphinylnitrene (235). Sulphides are known to be effective trapping reagents for nitrenes but attempts to employ them to attempt to demonstrate the intermediacy of such species are complicated by the fact that compounds (227) react readily with dialkyl sulphides,with displacement of sulphonate anion to give protonated N-phosphinylated sulphilimines and thence the sulphilimine (234). The reaction between (227; R1=R2=Ph; K3=Me) and dimethyl sulphide in the presence of tert-butylamine yields 90% of (231; R 1=R 2=Ph), and, 10% of (234); the latter, together with (233; R1=R2=Ph; R4=Me), is also produced when the nucleophile is m e t h 0 ~ i d e . l ~ In~ contrast to the behaviour of the phosphonic and phosphinic acid derivatives of type (2271, the phosphoric acid derivatives (227; R 1=R 2=ArO; R 3=Me or 4-nitrophenyl) in the presence of tert-butylamine do not rearrange but instead afford the amides (236) and the hydrazides (237). Some liberation of phenol may occur from (227;R1=ArO; K2=Ar) and thiswould arise either by attack by MeO- at phosphorus, or by elimination from the conjugate base (228) resulting in the formation of (232; R 3=Me) and (233; R4.=H) in approximately equal proportions, presumably by way of (229) and the formation therefrom of a mixed anhydride. Replacement of R 3=Me by R 3=4-nitrophenyl in (227) should result in increased formation of ( 2 3 1 ) at the expense of (2301, a 157 feature observed experimentally. The course of the alkylation of several potentially tautomeric phosphorus thio amides has been investigated. That of the diphosphazane (238) in the presence of' triethylamine
5: Quinquevalent Phosphorus Acids
181
l
Ar’CH=NAr2
(224)
+
(Me
N) PC=XH-CH2
II
( Me,N),PCH=CH
o
CH2CHAr’NHAr2
+
( Me2N),PCH CH-CH,
I
0
CHAr’ NHAr
Ph2P(0)NMe2
Ph2P(0)N3
/
o SO,R~
(227)
(228)
(230)
1
I I
+ I
0 R2’
0
0 / \ B ~ N H NHR~
‘N-SMe2
( 2 3 4I
-
+
(231) R<
R3S0,NH But
R 2 / ,p
9 0 N: L
(236)
1235) Ph,P-NH-
Ph2P=N P( S ) P h,
PPh,
I
II
II
S
S
SCHZR
(239)
(238) S
II
R,PNHX
S
II / x
R,PN
‘EMe3
, SEMe, R2Pk NX
182
Organophosphorus Chemistry
yields the 2-alkyl derivatives (239; R=CN or COOMe) In the reactions between the thiophosphinic amides ( 2 4 0 ) and the halides MenEC13-n (E=Si or Gel, it is only for the maximum steric hindrance in X and R (each 'at least' CMe3) that the imide For product ( 2 4 2 ) is stabilized relative to the amide ( 2 4 1 ) the oxygen analogues, the presence of tert-butyl groups (R, X I is required for E=Si, but for E=Ge, R=Prl is sufficient to stabilize the imide structure. 160 References
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.
5: Quinquevalent Phosphorus Acids
36. 37. 38. 39.
183
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OrganophosphorusChemistry
184
M.Regitz and R.Martin, Tetrahedron, 1985, 41,819. G.Penz and E.Zbira1, Chem.Ber., 1985, 118,4131. G.M.Blackburn and D.E.Kent, J.Chem.Soc.,Perkin Trans.1, 1986, 913. B.Dhawan and D.Redmore, J.Org.Chem., 1986, 51, 179. E.E.Nifant'ev and T.S.Kukhareva, J.Gen.Chem.USSR (Engl.Transl.), 1985, 2, 265. 83. P.A.Odoriso, S.D.Pastor, and J.D.Spivach, Phosphorus Sulfur, 1984, 20, 273. 84. H.Gross, T.Ya.Medved, S.Nowak, F.I.Bel'skii, I.Keite1, and M.I.Kabachnik, J.Gen.Chem.USSR (Engl. Transl.), 1985. 55, 654. 85. C. King, D.M.Roundhil1, and F.R.Franczek, Inorg.Chem., 1986, 25, 1290. 86. Y.Xu and Z.Li, Tetrahedron Lett., 1986, 27, 3017. 87. D.M. Malenko, L.A. Repina, and A.D.Sinitsa, J.Gen.Chem.USSR (Engl.Transl.), 1985, 55, 622. 88. F.S.MuEametov and E.E.Korshin, J.Gen.Chem.USSR (Engl.Transl.), 1984, 54, 2505. 5267. 89. A.Rudi, I.GoldSerg, and Y.Kashman, Tetrahedron, 1985, 5, 90. H.Day, Sulfur Lett., 1985, 3, 39. 91. R.Shebana, A.A.El-Barbary, A.B.A.G.Ghattas, and S.-O.Lawesson, Sulfur Lett., 1984, 2, 223; A.A.El-Barbary, R.Shabana, and S.-O.Lawesson, 375. Phosphorus Sulfur, 1985, 1, 92. J.Navech, M.Reve1, and R.Kraemer, Phosphorus Sulfur, 1984, 21, 105. 93. Yen Vo-Quang, D.Carniato, L.Vo-Quang, A.-Marie Lacoste, E.Neuzi1, and F.le Goffic, J.Med.Chem., 1986, 29, 579. 94. W.Subotkowski, R.Tyka, and P.Mastalerz, Pol. J. Chem., 1983, 57, 1389 (Chem. Abstr.,1985, 103, 71 404). 95. P.J.Die1 and L. Maier, Phosphorus Sulfur, 1984, 20, 313. 96. A.V.Barsukov, B.V.Zhadanov, T.A.Markovskaya, N.A.Kaslina, I.A.Polyakova, G.F.Yaroshenko, A.V.Kessenikh, and N.M.Dyatlova, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1417. 97. A.V.Barsukov, N.A.Kaslina, B.V.Zhadanov, T.A.Matkovskaya, I.A.Polyakova, G.F.Yaroshenko, N.M.Dyatlova, and A.V.Kessenikh, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 715. 98. P.Kafarski, B.Lejczak, P.Mastalerz, D.Dus, and C.Radzikowski, J.Med.Chem., 1985, 28, 1555. 99. M.J.Pidwer and T.M.Balthazer, Synth. Commun., 1986, 16, 733. 100. I.Hoppe, U.Schoellkopf, M.Nieger, and E.Egert, Angew. Chem.,Int.Ed. Engl., 1985, 24, 1067. 101. K.Antczak and J.Gzewczyk, Phosphorus S u l f u r , 1985, 22, 247. 102. T.Schrader, R.Kober, and W.Steglich, Synthesis, 1986, 372. 103. R.Huber, A.Knierzinger, J.P.Obrecht, and A.Vasella, Helv. Chim.Acta, 1985, 68, 1730. 104. F.R.Atherton, C.H.Hassal1, and R.W.Lambert, J.Med.Chem.,l986, 29, 29. 105. K.Yamauchi, F.Une, S.Tabata, and M.Kinoshita, J.Chem.Soc.,Perkin Trans . 1, 1986, 765. 106. L.I.Nesterov and A.D.Sinitsa, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1064. 107. Z.S.Novikova, M.M.Kabachnik, N.V.Mashchenko, and I.F.Lutsenko, J.Gen.Chem.USSR(Engl.Transl.), 1985, 2 , 404. 108. R.Neidlein and H.J.Degener, Chem.-Ztg., 1984, 108,412. 109. M.M.Yusupov, Sh.Egamberdyev, M.K.Makhmudov, and B.Tashkhodzhaev, J.Gen.Chem.USSR (Engl Transl.), 1984, 54, 2417. 110. M.L.Cordiero, D.L.Pompliano, and J.W.Frost, J.Amer.Chem.Soc., 1986, 108,332. 111. W.Jansen and R.Ulses, Z.Anorg.Allg.Chem., 1986, 532, 197. 112. R.Ramage, B.Atrash, D.Hopton, and M.J.Parrott, J.Chem.Soc.,Perkin Trans . 1, 1985, 1617. 113. J.Szewczyk, J.R.Lloyd, and L.D.Quin, Phosphorus Sulfur, 1984, 21, 155. 114. B.L.Feringa, A.Srnaardijk, H.Wynberg, B-Strijtveen, and R.M.Kellogg, Tetrahedron Lett., 1986, 13, 997.; B.L.Feringa, A. Smaardijk, and H.Wynberg, J.Amer.Chem.Soc., 1985, 107, 4798. 115. D.J.McCabe, S.M.Bowen, and R.T.Paine, Synthesis, 1986, 319. 78, 79. 80. 81. 82.
.
'
185
5: Quinquevalent Phosphorus Acids
116. B.A.Kashemirov, P.S.Khoklov, E.A.Polenov, O.G.Soko1, and L.I.Kakadii, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 407. 117. M.Kamber and G.Just, Can. J.Chem., 1985, 63, 823. 118. T.Bottin-Strzalko, J.Corset, F.Froment, M.J.Pouet, J.Seyden-Penne, and M.P.Simonnin, Phosphorus Sulfur, 1985, 22, 217. 119. D.W.Hutchinson and G.Semple,J.Organomet.Chem., 1985, 291, 145. 120. G.M.Blackburn and T.W.Maciej, J.Chem.Soc.,Perkin. T r a n s L , 1 9 8 5 , 1935. 121. D.W.Hutchinson and G.Semple, Phosphorus Sulfur, 1984, 21, 1. 122. G.M.Blackburn, D.Brown, and S.J.Martin, J.Chem.Res.(S), 1985, 92. 123. T.Ishihara, Y.Yamasaki, and T.Ando, Tetrahedron Lett., 1986, 27, 2879. 124. R.S.Macomber, I.Constantinides, and G.Garrett, J.Org.Chem., 1985, 50, 4711. 125. N.G.Khusainova, I.Ya.Sippel', E.A.Berdnikov, R.A.Cherkasov, and A.N.Pudovik, J.Gen.Chem.USSR (Engl. Transl.), 1984, 54, 2506. 126. G.Haegele, M.Engelhardt, W.Peters, A.Skowronska, J.Gwara, and D.Wendisch, Phosphorus Sulfur, 1984, 21, 53. 127. Kh.M.Angelov and Ch.Tancheva, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 5 5 , 45. 128. L.S.Trifonov and A.S.Orahovats, Heterocycles, 1985, 23, 1723. 129. N.Ayad, B.Baccar, F.Mathis, and R.Mathis, Phosphorus Sulfur, 1985, 21, 335. 130. T.Minami, S.Tokumasu, R.Minasu, and I.Hirao, Chem. Lett., 1985, 1099. 131. Yu.M.Dangyan, M.R.Tirakyan, G.A.Panosyan, and Sh.O.Badanyan, J.Gen.Chem.USSR(Engl.Transl.), 1985, 55, 1451. 132. M.Yamashita, K.Tsunekawa, M.Sugiura, T.Oshikawa, and S.Inokawa, Synthesis, 1985, 896. 133. E.Castagnino, S.Corgano, and G.Piancatelli, Synth.Commun.,l985,15, 783. A. Smaardijk, S. Noorda, F. van Bolhuis, and H. Wynberg, 134. Tetrahedron Lett., 1985, 26, 493. 135. N.A.Kaslina, I.A.Polyakova, A.V.Kessenikh, B.V.Zhadanov, M.V.Rudomino, N.V.Churilino, and M.I.Kabachnik, J.Gen.Chem.USSR(Eng1. Transl.), 1985, 55, 534; V.P.Vasil'ev, L.A.Kochergina, and T.D.O?leva, ibid. 720. 136. A.V.Mbskvin, M.V.Korsakov, N.A.Smorygo, and B.A.Ivin, J.Gen.Chem.USSR (Engl. Transl.), 1984, 54, 1987. 137. D.P.Phillion and S.S.Andrew, Tetrahedron Lett., 1986, 27, 1477. 138. X.Creaery and M.E.Mehrsheikh-Mohammadi, J.Org.Chem., 1986, 51, 7. 139. H.Davy and P.'Metzner, J.Chem.Res.(S), 1985, 272. 140. M.Thorson, T.P.Anderson, U-Pedersen, B.Yde, S.O.Lawesson, and H.F.Hansen, Tetrahedron, 1985, 2,5633. 141. R.Shabana, A.A.El-Barbary, N.M.Yousif, S.O.Lawesson,Sulfur Lett., 1984, 2, 203. 142. T.P.Andersen, P.B.Rasmussen, Ib.Thomsen, S.O.Lawesson, P.Joergensen, and P.Lindhardt, Justus Liebigs Ann.Chem., 1986, 269, 143. G.Sauve, V.S.Rao, G.Lajoie, and B.Belleau, Can. J.Chem., 1985, 63, 3089. 144. P.B.Rasmussen, U.Pedersen, I.Thomsen, B.Yde, and S.O.Lawesson, Bull. S O C . Chim. Fr., 1985, 62. 145. L.Horner and J.Gerhard, Phosphorus Sulfur, 1985, 22, 13. 146. Shao Yong Wu and M.Eto, Agric. Biol. Chem., 1984, 48, 3071. 147. C.R.Hal1, T.D.Inch, C.Pottage, and N.E.Williams, Tetrahedron, 1985, 41, 4909. 148. R.D.Cook, W.A.Daouk, A.N.Hajj, A.Kabbani, A.Kurku, M.Samaha, F.Shayban, and O.V.Tanielian, Can.J.Chem., 1986, 64, 213. 149. G.A.Kutyrev, A.V.Lygin, R.A.Cherkasov, and A.N.Pudovik, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 223. 150. H.Tanaka, T.Saito, and S.Motoki, Chem.Pharm.Bull., 1986, 59, 59. 151. M.Ueda, A.mochizuki, I.Hiratsuka, and H.Oikawa, Bull.Chem.Soc.Japan, 1985, 58, 3291. 152. T.Mujasaka, S.Hibino, Y.Inouye, and S.Nakamura, J.Chem.Soc.,Perkin Trans. 1, 1986, 479. 153. M.Kirilov, I.Petrova, and Z.Zdravkova, Phosphorus Sulfur, 1985, 11,301. 154. B.Davidowitz, T.A.Modro, and M.L.Niven, Phosphorus Sulfur, 1985, 22, 255. 155. M.J.P.Harger and A.Smith, J.Chem.Soc.,Perkin Trans.1, 1985, 1787. ~
~
~
186
OrganophosphorusChemistry
156. M.J.P.Harger and A.Smith, J.Chem.Soc., Perkin Trans. 1, 1986, 377. 157. M.J.P.Harger and A.Smith, J.Chem.Soc., Perkin Trans. 1, 1985, 2651. 158. N.G.Zabirov, E.L.Gol’dfarb,R.A.Cherkasov, and A.N.Pudovik, J.Gen. Chem.USSR(Eng1. Transl.), 1984, 54, 2502. 159. Yu.A.Veits, V.L.Foss, V.A.Leksunkin, and M.V.Gurov, J.Gen.Chem.USSR (Engl. Transl.), 1985, 55, 1459. 160. V.L.Foss, Yu.A.Veits, V.A.Leksunkin, and M.V.Gurov, J.Gen.Chem.USSR (EngLTransl.), 1985, 55, 1458.
7
Ylides and Related Compounds BY B. J. WALKER
1 Introduction Reflecting similar developments throughout organic chemistry there has been a notable increase this year in the number of theoretical studies of ylides and their reactions.
Methods of olefin synthesis
involving phosphine oxides are discussed in Chapter 3.
2 -Methylenephosphoranes
2.1 Prepcration and Structure.
- Among a number of
interesting
conclusions drawn from ab initio calculations on the model substituted ylide system (1) is that u-donor and r-acceptor substituents X (e.g. Li, BeH, BHZ) stabilized the ylide.' especially relevant to the current dispute'
This is
over the existence and
chemistry of the anions (2) (see also Reference 46).
On the basis
of MNDO calculations and its photoelectron spectra the phosphaalkene (3) does not have ylide character3 and all the results indicate that d-orbitals do not participate in the P = C bond. parent bis(methy1ene)phosphorane and ab initio SCF
calculation^.^
Bonding in the
(4) has been analysed using MNDO
The results of these calculations
are supported to some extent by electrochemical investigations of substituted bis(methy1ene)phosphoranes.
Ab initio calculations havc
been carried out on several species containing Si-P bonds including the ylide ( 5 ) .5
The results indicate that (5) is less strongly
298
7: Ylides and Related Compounds
H,P=CH
299
X
CH,P=CH,
(1)
(3)
H,P=Si
(5)
CH.
H,
300
Organophosphorus Chemistry
bonded than its carbon equivalent. A
number o f silylated bismethylenephosphoranes (6) have been
prepared and characterized by n.m.r. spectroscopy and X-ray structural analysis.
X-ray analysis reveals that the novel ylide
structure (7) is formed in the reaction o f tri-(n-buty1)phosphine with carbon diselenide.'
The cyclic diylides (10) have been
prepared by dimerization of the phosphaalkyne (8) followed by a P to P oxygen transfer, presumably & y
(9).8
The structure of (10) was
confirmed by X-ray analysis and hydrolysis to give (11). analysis of isopropylidenetri(isopropy1)phosphorane
An &-ray
(12) suggests
that the ylide P-C bond is relatively longer, and that the carbanionic carbon is relatively more pyramidal, than in most other ylides studied.
The structure o f phenacylidenetris(morpho1ino)-
phosphorane (13) has been investigated using X-ray diffraction and
13c n.m.r. spectroscopy. lo 13C,
H '
and 31P n.m.r. spectroscopy
all provide evidence that the ylide canonical forms (14b) and (14c) make important contributions to the structure of the 2-phosphinio-substituted 1-phospha-1-alkene (14). Specifically deuterated ylides (16) and bromoalkylphosphonium salts (17) (and the corresponding ylides (18)) have been prepared by the reaction of (1-dialkylbory1)alkylidenetriphenylphosphoranes (15) with, respectively, deuteromethanol and bromine. l2
Isocyano-
methylenetriphenylphosphorane (19) has been prepared for the first time.13
Both the ylide (19) and the corresponding phosphonium salt
are highly reactive, decomposing rapidly on treatment with water under basic o r acidic conditions.
The ylide (19) rearranges t o the
corresponding cyano compound on heating and the salt forms a variety of coordination compounds with transition metals.
The ylide-disalt
(20) is a product of the reaction of triphenylphosphine with 1,4-dibromo-Z-butyne, while a similar reaction of 1.4-diiodo-2-butyn
7: Ylides and Related Compounds
=
1
t
Ph3P- CBr2R
Br-
301
Bu*oBut
-k
But
Br B ( c
- C,H,),
(17 1 BuLi
R'
Ph3k-
c'
'
Br
CNCH,SiMe,
+
Ph,P
4-
C2CI,
*
+
CNCH,PPh,
X
-
OrganophosphorusChemistry
302
gives the disalt (21).14
A
variety of P-fluoro ylides (22) have
been synthesised and their chemistry and n.m.r. spectroscopy i n ~ e s t i 9 a t e d . l ~The related phosphorus ylides (23) and (24) are formed on irradiation of (trimethylsilyl)[bis(diisopropylamino)phosphino] diazomethane in the presence of, respectively, trimethylchlorosilane and dimethylamine.16
Some ylide products ( C g . 25)
have been obtained from the extensively studied reactions of cyclic phosphites and aminophosphines with activated doub1el7 and triple'' bonds.
The quasiphosphonium ylides (28) are formed in the reaction
of dialkyl aroylphosphonates (26) with excess trialkyl phosphites, probably via the carbene (~71.~' The stability of (28) depends on the nature of the substituents on the original phosphite.
2.2 - Reactions of Metxlenephosphoranes 2.2.1 Aldehydes.- A useful review of the more recent investigations of the mechanism of the Wittig reaction, especially those factors which control stereochemistry, has appeared.20
However, to
complicate matters still further, McEwen concludes his survey by suggesting yet another rationale (involving initial formation of a spin-paired diradical intermediate (29)) for the Wittig reaction and its stereochemistry.
It is not suggested that this mechanism is
applicable to all Wittig reactions, but rather that it represents a limiting case in the spectrum of possibilities for oxaphosphetane formation.
Continuing investigations of the role of through-space
2p-3d overlap effects in the mechanism of the Wittig reaction have involved comparisons of olefin stereochemistry observed in the ylide-aldehyde and the lithium phosphide-epoxide routes to the intermediate oxaphosphetanes. 21
On the basis of these results a
detailed mechanism has been proposed f o r the role of lithium ions in the reaction of benzylidenebis(0-methoxypheny1)methylphosphorane (30) (an ylide where through space effects should be observed) with
7: Ylides and Related Compounds
+
+
Ph,PCH,C CHZCHPPh
II
Ph,P
303
+
+
,
Ph,PCH,C=CCH,PPh,
2 8r(21)
(20)
F
I
( R\N),P=CHR2
( R, N),P=C(
S i Me,
-1
g
c
CI
,
(23)
Me3
R N ) P=CH,
21
NMe, (211
R = Pr'
0
II
ArCOP(OR)2 (26)
0
+ (R'O)3P
+
ArEblloR), (27)
+ (R'O),PO
2 Er-
OrganophosphorusChemistry
304 aldehydes.
An investigation of the reaction of the related ylides
(31) and (32) with benzaldehyde, using cross-over experiments (added
m-chlorobenzaldehyde) and direct observation by 31P n.m. r. spectroscopy, suggests that there is little o r no reversibility of oxaphosphetane formation.”
An explanation is offered for the
inferred greater rate of oxaphosphetane decomposition to alkene and phosphine oxide compared to dissociation to ylide and benzaldehyde. Maryanoff and Reitz have reported a study of the decomposition of diastereometrically pure Wittig intermediates (34) generated by deprotonation of the corresponding 6-hydroxyalkylphosphonium salts (33).23
Both the olefin stereochemistry observed and the results of
cross-over experiments (added m-chlorobenzaldehyde) confirm the faster rate of reversibility (to ylide and aldehyde) of --(34) compared to trans-(34) and indicate that this difference is greater than earlier work had suggested.
Even more interesting is the
observation of a synergistic effect (leading to excessively enhanced amounts of (E)-alkene) when deliberately prepared mixtures of ervthro- and threo-(33) are decomposed.
The volumes of activation
and reaction have been determined for the Wittig reaction of p-nitrobenzylidenetriphenylphosphorane with substituted benzaldehydes.24 The values obtained argue against a rate-determining first step, however they d o suggest that high pressures would be an advantage in forcing difficult Wittig reactions.
In fact the advantage is likely
to be much greater than the authors appear to realise, since in reactions of stabilized ylides the initial step of attack on carbonyl
rate-determining.
Stereoselective (Z)-alkene formation has been observed in Wittig reactions involving alkyl-and arylalkylphosphonium salts in aprotic organic media containing small amounts of water and using alkali metal carbonates as base.25
The low reactivity of stabilized
ylides and the dominance of (E)-stereochemistry in their
305
7: YIides and Related Compounds
H
\
,R'
R, c,
Me
R i'p
(fJjj;rH
I ' H
'0.
(29)
(30)
Ar Ph,P-CHPh
+
(31) Ar
+
-I
-
=
ONMe2
H
Prn
Ph P-0
Ph
IH
n o Ph 4
Pr"
( 3 3 ) - eryfhro
cis - ( 3 4 )
-I- Ph3P0
Ph
Ph3P=CH-Pr"
+
+ Ph, P
H
Prn
H O h -H- P h
( 33)- threo
Pr Ease ____)
Ph3P- 0
P:
Pr" trans
Ph
-(34 )
+
4-
PhCHO
+
Ph3P0
"
% Ph
OrganophosphorusChemistry
306
Wittig reactions has to some extent been overcome by use of the dianion (36) rather than the ylide (35) .26 Wittig reactions of (36) give poor to excellent yields of alkenes with moderate to good (Z)-stereoselectivity.
(E)-a,@-Unsaturated aldehydes have been
obtained stereoselectively under very mild conditions from Wittig reactions of f ormylmethylenearsonium ylide. 2 7 Ylides (37) derived from 3-dimethylaminopropyltriphenylphosphonium salts give good yields of (Z)-alkenes stereospecifically even in reactions with sterically hindered aldehydes .”
Since these
alkenes can be easily converted into 1.3-dienes. (37) provide an alternative to allylidenetriphenylphosphoranes which sometimes fail in olefin-forming reactions.
a,@-Unsaturated esters (39) are
obtained in good yields from a three-component reaction of alcohol, aldehyde and ketenylidenetriphenylphosphorane (38). presumably via initial formation of the ester-stabilized ylide (40) followed by a Wittig reaction.”
The reaction is also applicable to the
preparation of cyclic esters through the use of o-hydroxyaldehydes and has been applied to the synthesis of the macrolide antibiotic (41) and the related molecule ( 4 ~ 1 . ~ ’The previously reported 3 1 [2+2+2] route to cyclohexyl derivatives involving two consecutive
Michael additions of an enolate to a vinylphosphonium salt, followed by an intramolecular Wittig reaction has been extended to the coupling of three different components (Scheme lI3’ and to the simultaneous formation of four carbon-carbon bonds by generation of the initial enolate by Michael addition (Scheme Z).33 A
number of cyclic enol ethers have been pre,pared by Wittig and
Horner reactions of phosphonium ylide and phosphine oxide derivatives of tetrahydrofuran and tetrahydropyran. 34
The ylides
(43) and (44) react with simple aldehydes to give the expected
Wittig products. 3 5
However, reactions with aldehydes carrying
307
7: Ylides and Related Compounds
C H2C0 0 E t Ph p
NoH
P h , P q
-
0
v
o
*
E
I
3
0
(35)
0
(36)
i
RCHo
CO' R
CHZcoo
(37) Ph3P=C=C=0
+ R'OH +
R2CH0
(38)
R2
H
H
COOR'
X (
39)
Ph3P=CH COOR'
(40)
0
H
H 0
I
OCO(C H&C00 H
0
t
Organophosphorus Chemistry
308
+
PPh
Reagen+s:
i ) -78'C,
THF
j
ii
I
E t 3 B ; iii
,
Br
Scheme 1
0 II
Reagents : i , L i C ( S E t l 3 ;
+
it,
2 x Ph3PCH=CH2 ; iii, KOH
Scheme 2
( 4 3 )X = N H , O , S
7: Ylides and Related Compounds
309
nucleophilic centres, 9.2-formylpyrroles, give preferential substitution of phosphine.
The factors controlling the relative
extent to which the two pathways (a) and (b) are followed in the reaction of 2-silylethylidene ylides (45) with aldehydes have been investigated. 3 6
The silyl migration product (46) (largely syn) is
formed almost exclusively in reactions o f ylides carrying electron-donating groups on the aryl rings and electronegative substituents on silicon.
A further example of palladium-catalyzed
Wittig-type olefination has been reported. 37
The reaction is
thought to involve the salt (47) and shows little stereoselectivity.
2.2.2 --Ketones.- The stereochemistry o f olefination of 2.3-epoxy- and protected 2-hydroxy cyclohexanones with ethylidenetriphenylphosphorane in the presence of lithium salts and under "salt-free" contiditons has been investigated. 3 8
The (Z)-alkenes (48) and (49)
predominate under all conditions, although the highest ( Z ) : ( E ) ratios are from salt-free reactions.
Another example o f the
difficulties sometimes met when attempting Wittig-methylenations has been reported. 39
The problems associated with synthesizing (50) by
this method were partially overcome by using "salt-free" ylide generated from the phosphonium iodide. been used to synthesize (53). 40
A different approach has
While the obvious precursor, the
bicyclic ketone (51). is inert to treatment with methylene ylide, the precursor (52) reacts readily.
A further alternative
methylenation method is provided by the reaction o f oxaphospholan (55), prepared by base-treatment of the phosphonium salt (54). with
ketones and aldehydes in the absence of solvents and base.41
The
reaction has the added advantage that the by-product (56) is much less soluble in organic solvents than triphenylphosphine oxide, a property which facilitates isolation o f the alkene formed. The carbonyl group of 1-0x0-2-alkenylphosphonates
(57)
undergoes stereoselective Wittig reaction with acylidenephosphoranes
Organophosphoms Chemistry
310
RlYc!T 5!:
+
R ’ m C H 2 S i R 2 R 3R 6
R5
Me
2 3 I
CH2Si R R R Me
R’
ACHO
+ Ar 3P=CR5CH2Si R2R3RL (451 OSi R2R3R
0’
‘CH, R* Me
Me
R5
PA r3 (46)
1
PhCHO
wPh
7: YIides and Related Compounds
311
&OR
Ph
&
Ph (52)
(53)
+
Ph2P(CH.$,CH -CH,
I
Me
\0/
(55)
Br-
(54)
1
R'COR~
1 2
R RC=CH,
+
A
HOCHZ
O+
PPh,
OrganophosphorusChemistry
312
to give the dienone phosphonates (58) which, depending on the substituents present, usually cyclise to give the isomeric 2H-pyran-4-ylphosphonates (59). 42
Benzoic acid catalyzed Wittig
reactions of 2-carbonylalkylphosphonium salts with cyclopropanone hemi-acetal have been used to prepare ethyl cyclopropylidene alkanoates (60) in moderate to good yield.43
The reactions of the
bis ylide (61). generated under phase transfer conditions, with a variety of quinones have been reported.44
In only one case, that of
quinone (62). was the product (63) of a bis-Wittig reaction observed.
Partial hydrolysis of ylide intermediates often takes
place and initial reaction at one carbonyl group is followed by a variety of steps other than a second Wittig reaction.
The
intramolecular Wittig reaction of 2-(succinimidy1)benzylphosphonium ylides (64) has been used to form benzopyrrolizine derivatives (65) in a study directed towards the synthesis of mitomycins .45 2.2.3 Miscellaneous Reactions.- At temperatures of >-30°C the 1-(arylcarbony1oxy)alkylidene ylides (66) undergo a novel
rearrangement to 1.2-diketones (69) .46 Two possible mechanisms are considered for this reaction; a polar route via (67) or initial formation of the carbene (68) (Scheme 3 ) .
Ab initio calculations on
model compounds suggest that ylides containing r-donor/a-acceptor substituents (e.g.66) are potential carbene precursors (see also Reference 1).
Dihydroxyphenacylidenetriphenylphosphoranes provide a
new route to 6-hydroxy- and 7-hydroxychromones through acylation and intramolecular Wittig reaction (Scheme 4 ) . 47
Attempts to prepare
dihydrothiopyrans by intramolecular Wittig reaction of ylides generated in situ from 1-mercaptoketones and cyclopropylphosphonium salt (70) either failed to give the required product o r led to mixtures of isomers.
However, isolation of the ylide (71) and
thermal decomposition under neutral, anhydrous conditions gave moderate yields of one isomer (72) (Scheme 5 ) . 4 8
The ylide (73)
7: YIides and Related Compounds
313
0 II Ph3P=CHCOR3
+
(R’0)2PCOCH=CR1RZ
0 (R
’
II O
I
~
* COR~
( 57)
(58)
’&
COR’
+
Ph36CHR’COR2 ____) PhCOOH
Me(;s;)Me
r”3r
3
P
~
R
~
Organophosphorus Chemistry
3 14
R2Y;Ph3 0,
0,
COR'
COR'
f 66)
Reagents: i , NaN(SiMe3I2
, -6OoC,
T H F ; ii
, />
-3OOC
Scheme 3
COCH=PPh,
.
,,
1 , 1 1 R3
OH R'=OH , R2: H R ' = H , R2=OH
R e a g e n t s : i , R3COCl, pyridine ; i i , NaOH
, H20 , 5OoC
Scheme 1
7: Ylides and Related Compounds
315
' /
(70)
Ph,P+
0-
PhCOCH,SCH,CH,C=C,
OEt
COOEt
Reagents
.
I,
PhCH2AMe3 CL-, K O H
,H20,
CH2CL2 ; II
, Toluene , 112 OC
Scheme 5
R
P oPh3P YcooEt
OrganophosphorusChemistry
316
is a versatile acceptor for Michael addition reactions and provides a synthesis of cyclopropanes (75) &y formed anions (74)."
cyclization of the initially
The advantages of using (73) are that many
other Michael acceptors provide very low yields of cyclopropanes with highly reactive nucleophiles and that (75) is readily modified through reactions of the ylide function. The first synthesis of derivatives (77) of pentatetraenecarboxylic acid has been reported using a Wittig reaction of l-H-allene-1.3-dicarboxylate
monoester chlorides (76) in the
presence o f t~iethylamine.~' In one case an intermediate was obtained and was converted to (77) by further treatment with base, The reaction of carbon suboxide with phosphonium ylides has also been investigated as a possible route to 1.2.3.4-tetraenes
(78).51
The nature of the solvent is very important in these reactions and evidence was obtained for the formation of tetraenes, including isolation o f a crystalline sample in one case.
The reactions of
stabilized ylides with N-sulphinyl-p-toluenesulphonamide have been reinvestigated. 52
For keto-stabilized ylides and the
fluorenylideneethylidene ylide (80) a Wittig-type reaction occurs at the SO group of the sulphonamide to give the thione S-tosylimides (79) and (81). respectively.
In the case o f the imine-stabilized
ylide (82) the phosphine oxide elimination step does not take place and the hygroscopic adduct (83) is isolated.
A number of 2-nitrone substituted arylazomethylenetriphenylphosphoranes (84) have been prepared. 5 3 to give imidazo[l,2-b]indazole
These compounds thermolyze
(85) or indazol-2-yl ylides (86)
depending on the ylide substituents.
The related
o-formylarylazomethylenetriphenylphosphoranes (87) thermolyze to give the ylides ( 8 8 ) . which on further heating give 4-oxo-1.4dihydroquinazoline derivatives
(89).
54
Thermolysis reactions of
hydrazono vinylphosphonium salts apparently occur through
7: Ylidesand Related Compounds
317
+
Ph,P=C,
/ Ph COOR2
ButS
-c=c=c=c=c,
/
R’OOC‘
Ph3P=CR’R2
+
O=C=C=C=O
Ph COOR’
+ R 1R 2C=C=C=C=O
\
Ph3P=CR1R2
Ph,PO
+
R1R2C=C=C=C=CR’R2
(781
,
COR2
Ph3P=C
‘R1
________+
TsN=S=O
TsN=S=C,
R’
/
C-R2
II
N Ts (791 R’ / P h3P =c, ,C=NR3 R2 (82) 1
Ph3P-c-C=NR + I R1 I R2
(83)
3
Ts N= S=
/
c,
H
CH
OrganophosphorusChemistry
318
H 1
R = COOMe
+ Ph,P
R2= Me 110 "c
I k
e or Ph
+
R*NO
A
____)
ii
0 (88)
(87)
J
or H +
319
7: Ylides and Related Compounds
contributions of the ylidic form (90) and lead to pyrazoles.55 Triphenyl[(phenylimino)ethylidenelphosphorane
(91) reacts with
carboxylic acids to give acylidenephosphoranes
( 9 4 ) . 56
The reaction
initially forms (92) which rearranges to (93) on heating.
The
addition of an alcohol and further heating gives (94) and urethanes.
Similar reactions of (91) with a-,
y-,
and 6-keto
carboxylic acids provide new routes to maleimides, cyclopentenones and cyclohexenones, respectively,
intramolecular Wittig
reactions of the initially formed adducts.
57
Acylsilanes (96) are readily available from reactions of 1-silyl ylides (95) with the triphenylphosphine-ozone adduct.
58
31P N.m. r. studies o f the photooxygenation at low temperature of l-(methoxycarbonyl)benzylidenetriphenylphosphorane
presence of conformers of the dioxetane (97) . 5 9 cyclic alkoxy ylide
(98)
at 140'
further heating gives (100).60
indicate the Thermolysis of the
gives the phosphorane (99) which on The synthesis of alkynes carrying at
least one electron-withdrawing substituent by pyrolysis of 2-oxoalkylidenetriphenylphosphonium ylides is well known and the method has been extended to the preparation of l-perfluoroalky-nylphosphonates (101).61 It is now reported62 that under FVP conditions (75OoC at lo-'
mm Hg) the method provides a high yield,
general synthesis of simple alkyl or dry1 substituted alkynes.
The
only side reaction observed was the loss of ethene from (102. R'=g-C4Hg)
to give vinyl acetylenes.
The kinetics of formation of
phosphorus ylide-tetracyanoquinodimethane charge transfer complexes have been studied.63
The rate of complex formation is relatively
slow and there is a correlation between the reaction rate and the basicity of the ylide carbanion. The reaction of the transition metal complex (103) with reactive ylides gives alkenes in poor to excellent yields with a stereochemistry dependent on the substituents. 64
An advantage
OrganophosphorusChemistry
320
Ph3P=C=C=NPh
+ + RCOOH * Ph,PCH=C-iPh
I
(91)
+ + Ph,P-CHCO
OCOR
I
O=C-NPh
I
R (92)
Ph,pf-CCONHPh
o=c
I
I
OC R
‘R (93)
+-
Ph,PCHCOR
Ph,P-CHCONPh +
+
R’OOCNHPh
321
7: Ylides and Related Compounds
(95) R
Ar or SiMe,
(96)
Ph \ NC-PPh, MeOOC
h-!,
(97)
$4
NMe2 I ,COOMe o.p=c
'Ef"""'
-
OMe
1LOOC
2 min
R',
R 2= H , Me, E t
, P h , Pr' , e t c
Organophosphorus Chemistry
322
of the method is that the phosphorus by-product is triphenyl-
phosphine rather than the phosphine oxide.
The reaction of the
dioxomolybdenium complex (104) with tributylmethylenephosphonium ylide gives (105). described as a metal phosphorus-substituted carbene. 6 5
A
number of transition metal-ylide complexes have been
synthesized, including (106) a highly active homogeneous catalyst for the polymerization of ethene. 66
Methylenetriphenylphosphorane
reacts with As-Mo cluster compounds to give the bridging ylide complex (107).67
A
variety of complexes, 9.
and (110),69
have been prepared by reactions of the complex (108).
The exocyclic
double bond in (109) is highly reactive towards nucleophilic attack.
The crystal and molecular structures of complexes (111)
have been determined.70
-3- Reactions of Phosphonate Anions In view of their ready conversion to 2-hydroxyalkyl-phosphonates and -phosphinates (and hence alkenes), the report71 of a new diastereoselective synthesis of 2.3-epoxyalkylphosphonates and phosphinates is of interest.
A
structural and conformational study
of the phosphonate anions (112). (113) and (114) has been ~ e p o r t e d . ~ ’The conformations of these anions differ markedly from those of the parent phosphonates. It has been reportedr13 that the geometry of olefins obtained from the reaction of dialkyl 1-(ethoxycarbony1)ethylphosphonates and a-phenylpropionaldehyde can be controlled by choice of the phosphonate ester alkyl groups; diisopropyl ester gives dimethyl ester gives
(z).
(E), while
This has now been confirmed for the
original system and the amount of (El-alkene further increased in favourable cases by the presence of crown ether.74
However, when
the principle was applied to the reactions of long-chain a-phosphonocarboxylates (115) the dependence of stereochemistry on
7: Ylides and Related Compounds
323
+
H I
Ph
-
/
+
Ph
PPh,
(106)
Ph3P=CR3RL
Organophosphorus Chemistry
324
0
It
(OC),Cr [CH,SMe,I
‘
CH-P
+
Ph2PJ2C=CH2
+ (OC)
Ph2
Cr
. i \p/
(108)
‘C=CH2
Ph2 (109)
C , H2(1 08 1
+
Ph2 P
+ ( O C )&Cr
( Ph,P ),CHCH,PPh,
>C H PP h
‘P-CH, Ph2
(110)
/CH2-AU-CH\2, PR2
R2 p,
CH2-Au-CH2
CHCN
CHCOEt
HCOOMe
K+
(112)
COOR’
COORL
I
H2C=CH(CH2),,CH
P(OR3),
II
0 (115)
+
R4CH0 R4 COOR‘
7: Ylides and Related Compounds
325
the ester alkyl group was much less marked and the (E)-product predominated in all cases except for one involving the ester ( 1 1 5 , The alkylidenediphosphonate anions (117) can be
R3=CF,CH,).
generated directly through phosphonylation of the alkylphosphonates (116) using two molar equivalents of LDA as base.75
The anions
(117) react readily with aldehydes to give good yields of (E)-vinylphosphonates ( 1 1 8 ) , often stereospecifically (Scheme 6). Unsymmetrical diphosphonate anions
(e.g. 119) eliminate the most
electrophilic group; (EtO)2P(0) in the case o f (119).
The
previously reported76 olef ination reaction of arylmethylphosphon~ ~ used to diamide anions (120) has been further i n ~ e s t i g a t e dand prepare a variety of substituted (Z)-stilbenes.
The high
stereoselectivity observed in most cases under conditions of thermodynamic control is explained on the basis of the erythro adduct ( 1 2 1 ) being thermodynamically most stable. Improvements are still required in Wittig-type methods for the preparation of tetrasubstituted alkenes since even phosphonate reactions often give low yields.78 of added salts" appeared.
A
further report7'
of the effect
on the phosphonate olef ination reaction has
The addition of stoichiometric amounts of lithium o r
magnesium salts allows the use of triethylamine as the base in reactions o f triethyl phosphonoacetate with aldehydes (ketones do not react). critical.
The nature of the solvent is important but not A
comparison of the use of triethyl phosphonoacetate
anion with the Reformatsky and Peterson olefination reactions of ketones shows that the phosphorus route is preferred or equivalent except in the case of highly hindered ketones.81 The DIBAL reduction of esters to aldehydes in the presence of phosphonate anions appears to solve problems of overreduction to alcohol and provides a good general method of 2-carbon homologation (Scheme 7).8 2
The phosphonate (122), prepared by alkylation of
OrganophosphorusChemistry
326
R’
0
R’ (118) 0 Reagents : i
II
2 L D A , - 7 8 O C , THF; ii ( E t 0 1 2 P C l ; ii i
R2CH0
Scheme 6
R’
0
Ar 2
LI
(1201
(1191
(121 1
I
R’COR~
A
COOEt
H
Reagents
: i , D l B A L (Et0)2P(01CHCOOEt
,
- 7 8 O C ,THF
Li+
Scheme 7
321
7: Ylides and Related Compounds triethyl phosphonoacetate, has been reacted with formalin in the
presence of potassium carbonate to provide a synthesis of the alkene (123). 83
The carbanions generated by treatment of cyclopropyl-
phosphonates with LDA react with aldehydes to give 1-(hydroxymethy1)cyclopropylphosphonates
(124). 84
In most cases the
reaction is highly stereoselective and treatment of the adducts (124) with sodium hydride in the presence of catalytic amounts o f crown ether leads to elimination and formation of the expected alkene (Scheme 8). followed in one case by ring cleavage.
Vinyl
derivatives (126) of phenanthroiine and (127) of bipyridine have been synthesized by reaction of the appropriate diphosphonates with formaldehyde in methanol-methoxide. 8 5
The reaction involves initial
formation of the vinylphosphonate (125) (a similar reaction has been reported for phosphonium salts)86 followed by addition of methoxide and olefination (Scheme 9).
Wittig-type reactions of the
phosphonate-sulphone anion (129) with carbohydrates (128) give the tetrahydropyrans (130) as isomeric mixtures which can be isomerised to the pure 6-isomers by base.87
1.4-Diaryl-1.3-dienes and, in one
case, a tetraene have been synthesized in moderate yield in a one-pot reaction.88
The diphosphonate anion (131), generated from
the appropriate vinylphosphonate and diethylphosphonate anion, was reacted sequentially with aromatic aldehyde (Scheme 10).
2-Keto-
phosphonates (132) and (133). containing an oxygen function at the 5- o r 6-positions, are conveniently prepared by reaction of diethyl
alkylphosphonate anions with, respectively, y- and 6-lactones.89'90
Compounds (132) and (133) can be used directly in
synthesis and also, through oxidation and cyclization, provide a route to cyclopentanones or cyclohexanones (Scheme 11). 89
Moderate
to good yields of cycloalkenols (135) and (136) have been obtained through the reactions of phosphonates (134) with glutaraldehyde and succinaldehyde, respectively, in aqueous potassium carbonate
Organophosphorus Chemistry
328
0
II
30'/0 F o r m a l i n
( E t O ),PCHCOOEt
r
ZC03
Reagents : i , L D A
, -78
"C
I
T H F ; ii
R3CH0 ; iii
N a H , 18-Crown- 6
Scheme 8
0
II
RCH-
RCH,P(OE+),
CH,O-
___)
I
(EtO)
P\
' 0
Rr
eJ OMe
(126)
R
(127)
R =
Me0
CJ
Me0 Reagents : i
HCHO
...
Ill
t---
MeO-; ii
MeOH ; i i i
HCHO
Scheme 9
, MeO-
I
THF
7: Ylides and Related Compounds
329
+ *
0
II-
( Et0I2PCHSO2Ph
O "OMe H
T
0Me
\
(128)
Z = CN,CI
OMe
0 0
0
II -
It
II
+ I
( EtO ),PCXCH,P(OEt)z
Li+
H'
(131 1
X = SO,Ar
Reagents :
I,
ArCHO ;
Ar
or
,
COOEt
LDA ;
III
, ArCHO
Scheme 10
CH,P(OE t 1
X
\
II , 1 1 1
(
(
330
OrganophosphorusChemistry
H0
0
+
CH R 2P( 0 )( O E t )2
I LiCHR P ( O E t ) , + 21
(132) n = 2 n=3
(133)
0
0
It
II
C OCHR2P ( 0 Et )2
/
/
Reagents : i , DMSO
, COC12,
CH2C12, -60 “C
C O C H R 2 P ( O E t),
Et3N ; ii , NaH THF, r . t.
Scheme 11
0
II
(EtO12PCH2X
+
(136) X = C O O E t ,
,
C HO
(CH2)n \
CHO
-
0
II
K2C03 ’L
( E t O )2PCHXCH(OH)(CH2)nCH0
C N ,COMe
OH
(135)n=2 (136)n = 3
33 1
7: Ylides and Related Compounds
solution.91
The first synthesis of a phospho-statine derivative
(138) has been achieved by the stereoselective reaction o f dimethyl methylphosphonate anion with N-trityl-L-phenylalinal (137). 92 3-Phosphonomethyl-A2-isoxazolines
(139), prepared by
cycloaddition reactions of 1-(diethy1phosphono)acetonitrile oxide, provide routes to a variety of A2-isoxazoline derivatives through olefination and alkylation followed by oxidation (Scheme 12). 93 1.3.5-Trienes (142) are obtained in good to excellent yields by olefination with the phosphonate (141). which is available from thermolysis o f the A’-pyrazoline
(140) (Scheme 13). 94
An
alternative approach to the ether ( 1 4 5 ) . involving generation o f an alkylidene carbene and in situ trapping, is provided by the reaction of 4-methyl-3-cyclohexenone with the phosphonate (144) in the presence of alcohol (143) and base.95
A footnote in the paper
suggests that the original routeg6 via a Wittig reaction of (146) is not repeatable.
However, the authors also claim that their product
(145) has a similar ’H n.m.r. spectrum to the product of this Wittig reaction!
The use of LDA as a base in the preparation of
0x0-2-alkylphosphonates from the acylation of alkylphosphonate carbanions leads to increased yields and allows the use of stoichiometric amounts o f phosphonate rather than the excess usually employed . 97
Tr iha logenome thyl thiome thy 1ene bisphosphona tes
( 148 )
have been prepared by the reaction o f methylenebisphosphonate anions (147) with trihalogenomethanesulphenyl chlorides.
’*
Moderate yields
of a-arylakanenitriles (149) have been obtained from the copper(1) catalyzed reaction of dialkyl cyanomethanephosphonate anions with aryl iodides under vigorous conditions. 9 9
4 4.1
Selected Applications in Synthesis
Carotenoids, Retinoids and Related Combounds.- Methods of
Organophosphorus Chemistry
332
I
PhCH2
(137 1
(138)
R Reagents: i , BuLi
ii
, R 1 R 2CO ;
1
iii, R X ; i v I O 2
Scheme 12
0
II
4(EtO)ZPCHXCH=CHCH=CR1R2 (141)
1
i i , iii
R 3CH=CX C H= CHC H =C R' R 2
4 142) Reagents : i
, 100 "C
; ii L D A , THF ; iii
, R3CH0
Scheme 13
333
7: Ylides and Related Compounds
b
CH,OH I
n
+ \I
t 2(R012PCHN2
5 0
II-
( R~OI~PCHCN
cu I 2 00 "c Ar I
+
KOBut*
I
ckO
GHO --+
[ CNi
ArCHP(OR'Iz
3
(145)
R'
I
ArCHCN (149)
OrganophosphorusChemistry
334
synthesis of retenoids have been reviewed. loo In studies directed towards the synthesis of specifically deuterated retinals the reactions of triethyl phosphonoacetate and methoxycarbonylmethylene ylide with hexadeuterioacetone have been investigated.lo'
The ylide
route is preferred since use of the phosphonate leads to deuterium scrambling, presumably due to initial deuterium exchange between acetone and phosphonate anion.
The method has been applied to the
synthesis of [8,10,12,14,19,19,19,Z0,Z0,20-Dlo]retinals using the reaction of the ylide (150) with the perdeuterio aldehyde (151) as a key step.
Cyano-stabilized phosphonates, followed by Dibal
reduction of the nitrile function, can be used to synthesize the 8-, 9-, 12-, and 1 3 - m 0 n o - ~ ~ C - r e t i n a l s . Intramolecular ~~~ olef ination of
the phosphonate (152) (Scheme 14) has been used to prepare (153). a key intermediate in the first reported synthesis of all-trans-18,18.18-trif luororetinal (154).lo3 Standard methods have been used to prepare a variety of 13-modified retinalslo4 and modified retinals bearing non-conjugated positive charges along the polyene chain for use in studies of spectroscopic properties of visual constituents. lo5 The Wittig reaction has been used extensively in syntheses of all-(E)-citreomontanin
iso-citreoviral
(155), I o 6 (+)-citreoviral (156), and
(157). lo7
In an effort to develop
an efficient
polyene (hexaene and heptaene) synthesis a comparison of several potential methods has been carried out.lo8
The approaches used
involving phosphorus-based methods were found to be unsatisfactory due to either side-reactions or low yields.
However, the
dodecapentaenephosphonate (158) has been used to synthesize the hexaene fragment (159) of the aglycone of amphotericin B.lo9 4.2 B-Lactams.-
The now standard intramolecular Wittig
cyclization procedure has been used1l0'll1 to prepare a number of bicyclic trans-substituted B-lactams related to olivanic acids
335
7: Ylidesand Related Compounds
+ DCO D
(150)
I
Reagents : i L i H
THF, H M P A ; ii
(151)
, D I B A L , hexane; iii M n 0 2 CH2CLZ
Scheme 14
OrganophosphorusChemistry
336
OMe
I
Rk 1
(156) R =OH R3=Me , R2=RL=H (157) R ’ = R 3 = H R 2 = O H , RL=Me 0
II
( RO ),P
Et,Sig I
COOEt
L
9 S i Me2Buf
CHO
I
I
MeCH
H H NHAc
0 COOH (160)
7: Ylides and Related Compounds
337
COOR’
COO R’
(1611
(162)
COOR’
Reagents : i O 3 ; i i
MeZS ; iii
,
DBU
Scheme 15
0
OHC*SCH200Me
Reagents : i J P h P=CH3
OHC
’ CHO
; i;
I, ,
S CH2C0 OMc
hv
S c h e m e 16 OH
SCH2Ph
OrganophosphorusChemistry
338
(9. 160).
Of more interest is the use of the
cyclohexa-1.4-diene-derived azetidine-2-one (161) to obtain the
thermodynamically unstable &-substituted 162),110
@-lactams (9.
Following the failure of attempts to synthesize the
appropriate phosphonium ylide intermediates, 6-aza-l-carba-2-cepham-3-carboxylates
(163) have been prepared for
the first time using a phosphonate-mediated cyclization step (Scheme 15) .I1’ 4.3
Leukotrienes and Related Compounds.-
The reaction of
3-formylpropenylidene ylide with aldehyde (164). followed by light-catalyzed iodine isomerisation, has been used to synthesize (165) in almost quantitative yield (Scheme 16).113
Further use of
the Wittig reaction converts (165) into the thialeukotriene A4 (166).
The Wittig reaction has been used to synthesize a variety of
other leukotrienes, e g .
leukotriene B4 (169) from the aldehyde
(167) and the ylide (168),ll4 the acetylenic analogues of leukotrienes A and D,
leukotrienes and lipoxygenase inhibitors
(170) and (171)116 and the compound (172) which displays leukotriene-like activity.’l7
Both Wittig and phosphonate methods
have been used in a total synthesis of lipoxin A.118
Reaction of
the ylide (173) with the aldehyde (175) gives a 1:l mixture of isomeric alkenes (176). while reaction with the corresponding phosphonate anion (174) gives a 3:l preponderance of the required (El-alkene, both reactions give an excellent yield.
However, the
stereochemistry is not important since isomerization with iodine to (11:l)
(E:z) is
easily achieved.
The Wittig reaction has also been used extensively in the synthesis of hydroxyeicosatetraenoic acids (HETEls).
Examples
include the total synthesis of 12-HETE (177), ’19’ lZo 12,20-di HETE (1781,I2O dihydroxy- and epoxyeicosatrienoic acids’”
and 19-hydroxy metabolites of 12(S)-HETE.122
and the 20-
20-Hydroxy (179) and
339
7: YIides and Related Compounds
COOH X
uywc5H11 - (170 1 X = C H Z , Y = S (171) X = S , Y = C H 2
\\\
\
CH( S(CH213COOHI 2
(172)
340
+, Me3Si
-
OrganophosphorusChemistry
-
x
+ OHC
ICH*),COOR
+
(173) X = P h 3 P
II (17L) X = (Me0I2P
H
I
OR I
+OR H
1
( CH2),COOR
OH 11 77)
7: YIides and Related Compounds
341
20-carboxyleukotriene B4 (180) (metabolites of LB4) have been synthesized using the phosphonate ( ~ 1 ) ~to' introduce ~ the C1-Cll side chain.
4.4 Macrolides and Related Compounds.- Phosphorus-based methods have been widely used in macrocyclic ~ynthesis.~' The C-11 to C-25 northern hemisphere fragment (184) of the milbemycins has been prepared using a Wittig reaction of (182) with aldehyde (183) followed by cyclization (Scheme
17)
.Iz4
Cyclization of complex
phosphonates provides a route to various macrocylces, -..the of (185) to prepare (+)-rosaramicin aglycone.
use
The first total
synthesis of (+)-latrunculin B (187) has been achieved through use of a Wittig reaction of the ylide (186) (Scheme 18).lz6
In studies
related to the synthesis of the antibiotic elaiophylin, the preparation of the diene (189) has been achieved by a Wittig reaction of the aldehyde (188). lZ7
Attempts to use phosphonate
olefination gave only low yields of (189). apparently due to an elimination reaction caused by the greater basicity of the phosphonate anion than the ylide.
The applicability of
intramolecular phosphonate-based olefination to the cyclization step in the synthesis of polyene macrolides has been investigated by degradation of amphetericin B followed by conversion to the phosphonate (190) and cyclization to give (191) .Iz8
This approach
allows assessment o f the cyclization method on a model with appropriate stereochemistry and indicates that intramolecular phosphonate-based olefination, which has proved s o useful in the synthesis o f 16-membered ring macrolide antibiotics, will also prove important in the synthesis of the larger ring polyene macrolides. Phosphonate-based cyclization has been increasingly used in macrocyclic terpene synthesis.
In a synthesis of the marine
cembranoid (+)-desepoxyasperidiol the cyclization of the phosphonate (192) was attempted under a variety of conditions without success,
OrganophosphorusChemistry
342
0 ( Me0 I2P II
(CH,),COOH
w
(1791 R = CH,OH (180) R = C O O H
I
H
OR' &(CH21,COOMe
(181 1
+ i- i v _____)
OSiButPh2 OCH2Ph
Reagents : i
BuLi
-78OC ; i i ,
; i i i , MeOH , MeO-; i v , HCL, H 2 0
""'3c. AcO
(183)
Scheme 17
%
y
CHO O ( Me0 1,P
M
e0
343
7: YIides and Related Compounds
R=HN
I
I
R’ (187 1
R e a g e n t s : i, 5.8 K N ( S i M e 3 I 2
, THF,
O°C ;
; I. .I .I , c y c l i z a t i o n ii
k’ S c h e m e 18
OrganophosphorusChemistry
344
OTBDMS MOM0
0si B ut Me,
But Me,S i
I
Oq,(CH BufMe2Si0
,OS i Me, 6 ut
B u Me,S i 0
R
‘Me Me,
0
345
7: Ylides and Related Compounds probably due to the steric consequences of a reaction of the However, the Masamune-Roush conditions
a-branched aldehyde. lZ9
(large excess of DBU and lithium chloride in acetonitrile) provided the required 14-membered cyclic alkene in 30% yield as a mixture of isomers.
The methyl ester of the 14-membered ring sesterterpene
(194) has been synthesized by cyclization of the phosphonate (193). 130
Difficulties were experienced in synthesizing (193) by
alkylation of triethyl phosphonacetate.
These were overcome by
using a two-step procedure, alkylation of dimethyl methylphosphonate anion followed by further reaction with chloroformate to introduce the methoxycarbonyl group.
Phosphonate-based cyclization of (195)
has been used as a key step in the first total synthesis of (-)-bertyadional (196). 13 1 4.5
Pheromones.- Pheromone syntheses involving the Wittig reaction
include those o f (197) (a component of the olive fly pheromonecomplex) ,13’ (198) and ( 1 9 9 ) (which act as self-defensive substances against rice-blast disease)133 and (ZOO) (the pheromone of Drosophila meianogaster) ‘H8 ]octadec-(92)-enoate
Methyl [8,8,ll,11,16,16,17,17(203) has been prepared by the Wittig
reaction of the specifically labelled ylide (201) with the aldehyde (202).135
The reaction o f Grignard reagents with
ketenylidenetriphenylphosphorane (204) has been used to prepare the key phosphonium ylides (e.g. - 205) in syntheses of the sex pheromone components ( L g . 206) and
(%.
207) of the Douglas fir tussock moth
and the peach fruit moth, ~ e s p e c t i v e 1 y . l ~A~s reported previously this reaction provides a convenient method of chain lengthening v i a the potentially difunctional (204). 4.6
Miscellaneous Reactions.-
The Schlosser-Wittig reaction of
ylide (209) with aldehyde (208) and treatment of the intermediate 8-oxido ylide with perchloryl fluoride has been used to construct the 13-fluoro unit (210) in a total synthesis of (+)-13-fluoroprosta-
Organophosphorus Chemistry
346
-
COOEt
COO Et
33 x L i C l ,25'C, MeCN
McOOC
x
fi
COOMe
(193)
( Et0I2P=O
(196) (195)
7: YIides and Related Compounds
341
I
I
OH
D
Ph3P=C=C=0 (201)
D
D
D D - D
m(cH )/C0wPPh3
CH3( C H 2 4
23
(206)
CH3(C H2),C 0 ( CH,
1CH, ),C H
OrganophosphorusChemistry
348
glandin F2 (Scheme 19).137
Other uses of the Wittig reaction in
prostaglandin synthesis include the preparation of o x a p r ~ s t a g l a n d i n s l and ~ ~ a new route to prostaglandin D2.139 The (9E)- and (9Z)-trisporic acids A (212) and B (213) have been synthesized y&i
Wittig reactions of the lactol (211) with
appropriate phosphonium ylides. 1 4 0
A
key step in a total synthesis
of (2)-tirandamycin A (214) is the attachment of the 3-acyl tetramic acid fragment &y (215).141
olefination with the phosphonate dianion
Reactions of the ylide (216; R = H ) with D-ribose and of
the analogous ylide (216; R=Ph3C) with 2.3-0-isopropylidene-D-ribose gave, respectively, (217) and (218)
The stereochemistry of
these products is important since it determines the stereochemistry of ring-closure which, followed by further modification provides a synthesis of showdomycin (219).
These results repute previous
claims143 that reactions of ylides with unprotected D-ribose and D-glucose do not offer routes to alkenes.
The reaction of ylide
(220) with D-ribofuranose derivatives has been used to synthesize a
variety of novel C-nucleosides. 144 Dictyopterene B (221) and its e n a n t i ~ m e r land ~~
R-(-)-dictyopterene
C (223)146 have been prepared.
In the latter
case the synthesis involves reductive olefination of the lactone (222) followed by oxidation, methylenation and cyclization (Scheme
20).
A
Wittig reaction of cyclobutylideneacetaldehyde with cyclo-
butylidenetriphenylphosphorane has been used to prepare dicyclobutylideneethane (224) after the silicon-based method, used previously to prepare the cyclopropyl analogue, failed. 147 Methano-bridged bisdehydroannulenes (225) have been prepared by the Wittig reaction of cyclohepta-1,3,5-triene-l,6-dialdehyde
o r its
vinylogues with 3-methylpenten-2-yn-4-ylidenetriphenylphosphorane followed by intramolecular oxidative c 0 u p 1 i n g . l ~ ~ 1,6-Bis(2-
7: Ylides and Related Compounds
349
OR I
A
CHO
ph3p2z
+
0
0
U
(2081
? 2 4 JHc ( 3Hc
Reagents :
I ,
Toluene
,
-78OC ;
0
ii,
0
B U L I ; i i i , FC103
Scheme
-35OC
19
*, 0 II
C H ( C H 2 1,COC H3
COO H
I2131
350
Organophosphorus Chemistry
-o-%NR
(2151
HO OH ( 2 19)
(220)
7: Ylides and Related Compounds
35 I
... III
0
0
,i v
(222)
Reagents : i
I
DIBAH
, - 7 8 “C;
ii, Ph3P=CH(CH2I3Me , “ S a l t
c h l o r o c h r o m a t e ; i v , Ph3P=CH2 ; v
I
- Free”
; iii , pyridinium
75OC 5 h .
Scheme 2 0
+ CHO 4pph3
-
(226)
OrganophosphorusChemistry
352
formylvinyl)cyclohepta-l~,3,5-triene ( 2 2 6 ) . which can be converted to
the corresponding bis methano[24lannulene
by reductive coupling, has
been synthesized by a double Wittig reaction of cycloheptatriene 1,6-dial.dehyde.’49
The sterol (g,E,E)-triene (227) has been
prepared together with the (g,&E)-isomer ( E ) - c j. nnamy 1t r ip heny 1p ho s p ho r ane
.
by a Wittig reaction using
The p r evi ous 1y r e p o r ted
reaction of ethoxycarbonylmethylenetri-n-butylphosphorane with cyclic epoxides, which leads to ring-contraction, has been applied to 2,3-steroidal epoxides (e.9. - 228) .15’ are ring-contracted alkenes (229).
As
expected the products
However, in some cases the
aldehyde (230) could be isolated and the authors suggest that the mechanism of all these reactions involves initial attack of epoxide oxygen at phosphorus and not attack of ylide carbanion at epoxide carbon as previously proposed. Wittig reactions of the thermally unstable ylide (231). generated in situ by the reaction of 2.2-dichlorohexafluoropropane with triphenylphosphine, have been used to prepare novel ].,I.-bis(trifluoromethy1)alkenes
(232).
A
en route to pyrethroid analogues
number o f naturally occuring polyhydroxystilbenes have
been synthesized using the Wittig reaction. 153
The selectivity of
the Wittig reaction is illustrated by the use of
methylenetriphenylphosphorane to convert chlorophyll 3-vinyl-3-desmethyl chlorophyll
to
without modification of any other
functional group or disruption of magnesium coordination. 154 The total synthesis of the novel, potent antiulcer agent U-68,215 (239) has been achieved using a modified intramolecular
phosphonate olefination as a key step.155
The method involves
reaction of the phosphonate anion (234) with the enol lactone (233) to give initially (235).
However, the authors suggest that (235)
rapidly ring-opens to give (237) which is depKOtOnated by any phosphonate anion (234) still present to give the dianion (236).
353
7: Ylides and Related Compounds
1
Cu(II 1acetate
n = 0,l m =O,l,2
(226)
Organophosphoms Chemistry
354
Bu3P=C HCO 0 R
ROOC
OHC
[Ph3P=C(CF (
1
3 21
231 1
&'
&
RCHO
R\
c=c,
c,
F3
0 H
F3
7: Ylides and Related Compounds
8
+
355
0
II L i (MeO),P C H R (234)
0
CHRP(OMe1,
II
0
(233) (235) R=ICH 1 C
’Hr ‘**OTHP RJ
R
OL i
0 ( Me0l2P=O
0 4p(OM (236) X= H ( 2 3 7 ) X = Li
1238)
1
8
0
(239)
XSR x+PPh, (240)
H (241)
OrganophosphorusChemistry
356
This last compound cannot cyclize to the product (239) unless it reacts with a sufficiently acidic proton source to give (238) and thus any sequence starting with only one equivalent of phosphonate anion would have a maximum yield of 5
0
%
~Support ~ ~ ~for this was
obtained by carrying out a reaction with two equivalents of anion (234) followed by addition of 1 equivalent of glacial acetic acid, a procedure which gave a 70% yield of (239).
Full details of the use
of the vinylphosphonium salts (240) in the synthesis of highly functionalised bicyclo[3.3 .O]octanes (241) have appeared.157 Reaction of the aldehyde (242) with the phosphonate (243) is the key Step in a highly convergent synthesis of the HMG CoA reductase inhibitor (+)-compactin. 15*
The phosphonate (243) was prepared by
alkylation of dimethyl methylphosphonate anion; it is important to use the alkylating agent without a silyl protecting group in this reaction since in the presence of such a group only a low yield of (243) is obtained.
A
variety of stereoisomeric long-chain
1.2.3.4-tetrols (3. 244) have been prepared by the reaction of 1.2.3-protected pentodialdo-1.4-furanoses with pentadecyl- or tridecyltriphenylphosphorane followed by hydrogenation, hydrolysis and reduction,15’
Trans-selective Wittig reactions of long-chain
alkylidene ylides have been used to prepare a number of D-erythrospingosines (245). I 6 O
In a new route to (+)-pilocarpine a key
intermediate (246) has been prepared by olefination using the cyanoalkylphosphonate anion (247) since the corresponding alkoxycarbonylalkylphosphonate failed to give the appropriate alkene on reaction with the aldehyde (248). 16’
The potentially membrane-active
tropan-3-01s (250) have been prepared by Wittig reactions of the 162 tropane-1-carbaldehyde (249). REFERENCES -.-1.
H.J. Bestmann, A.J. K O ~ ,K. Witzgal, and P. Von R. Schleyer, Chem. Beq., 1986,
u ,1331.
7: Yiides and Related Compounds
357
+
R
O
OR’
0
O
C
0
1
L ( 0 Me l2
1
L I C I , DBU , CH3CN
CH,( CH2 ),5( CH OH I3C H, O H (244.) y
2
OH
( 2 4 5 ) n=12,14
COOBut (246)
OHC (247)
Me
Organophosphorus Chemistry
358
H H
CHO
MeN*oAc 1249)
I
MeFo (250)
R = n - Pr, CH2C=CH
359
7: Ylides and Related Compounds
2.
3. 4. 5.
B.J. Walker, in ‘OrganophosphorusChemistry,’ Ed. D.W. Hutchinson and B.J. Walker (Specialist Periodical Reports), The Royal Society of Chemistry, London 1986, Vo1.16, pp.316-318. H. Bock and M. Bankmann, Annew. Chem., Int. Ed. Engl., 1986, 265. W.W. Schoeller and J. Niemann, J. Am. Chem. Soc-., 1986, 1 0 8 , 22. K.J. Dykema, T.N. Truong, and M.S. Gordon, J. Am. Chem. Soc., 1985,
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107, 4535. 6.
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7: Ylides and Related Compounds 75. E.E. Aboujaoude, S. Lietje, N. Collignon, M.P. Teulade, and Ph. Savignac, Tetrahedron Lett., 1985, 26, 4435. 76. J. Petrova, S. Momchilova, and M. Kirilov, Phosphorus Sulfur, 1983, __ 17, 29. 77. J . Petrova, S. Momchilova, and M. Kirilov, Phosphorus Sulfur, 1985, 24, 243. 78. TTJ. Erickson, J. Org. Chem., 1986, 2 , 934. 79. M.W. Rathke and M. Nowak, J. Org. Chem., 1985, LO_,2624. 8 0 . M.A. Blanchette, W. Choy, J.T. Davis, A.P. Essenfeld, S. Masamune. W.P. Roush, and T. Sakai, Tetrahedron Lett., 1984, 25, 2183. 81. R.S. Budhram, V.A. Palaniswamy, and E.J. Eisenbraun, J. Org. Chem., 1986, 51, 1402. 82. J.M. Takacs, M.A. Helle, and F.L. Seely, Tetrahedron Lett., 1986, 27, 1257. Chem., 83, V.T.R. Kumar, S. Swaminathan, and K. Rajagopalan, J.Org. 1985, 50, 5867. 84. T. Hirao, T. Nakamura, M. Hagihara, and T. Agawa, J . Org. Chem., 5860. 1985, 85. G.R. Newkome, G.E. Kiefer, N. Matsumura, and W.E. Puckett, J. Or%. Chem., 1985, 50, 3807. 86. S. Trippett, in 'Organophosphorus Chemistry', Ed. S. Trippett (Specialist Periodical Reports), The Chemical Society, London, 1970, Vol.1, p.34. 87. N . J . Barnes, A.H. Davidson, L.R. Hughes, and G. Proctor, J . Chem. Soc., Chem. Commun., 1985, 1292. 88 . T. Minami, S. Tokumasu, and I. Hirao, Bull. Chem. SOC. Japan, 1985, _-58, 2139. 89. H.-J. Altenbach, W. Holzapfel, G. Smerat, and S.H. Finkler, Tetrahedron Lett.., 1981, 26, 6329. 90. K. Ditrich and R.W. Hoffmann, Tetrahedron Lett., 1985, 26, 6325. 91. M. Graff, A.A. Dilaimi, P. Seguineau, M . Rambaud, and J. Villieras, Tetrahedron Lett., 1986, 2 7 , 1577. 92. J.F. Dellaria. Jr. and R.G. Maki, Tetrahedron Lett., 1986, 27, 2337. 93. 0 . Tsuge, S. Kanemasa, and H. Suga, Chem. Letts., 1986, 183. 94. T. Minami, S. Tokumasu, R. Mimasu, and I. Hirao, Chem. Lett., 1985, 1099. 95. J.C. Gilbert and B.E. Wiechman, J . Org. Chem., 1986, 258. 96. M. Suda, Tetrahedron Lett., 1982, 23, 427. 97. E.E. Aboujaoude, N. Collignon. M.-P. Teulade, and P. Savignac, Phosphorus Sulfur, 1985, 2 5 , 5 7 . 98. G.M. Blackburn and T.W. Maciej, J. Chem. Soc., Perkin Trans.1, 1985, 1935. 99. H. Suzuki, K. Watanabe, and Q. Yi, Chem. Letts., 1985, 1779. 100 M.B. Sporn, A.B. Roberts, and D.S. Goodman (Eds.), 'The Retinoids', Vol.1, Academic Press, 1984. 101 H.J. Bestmann and P. Ermann, Liebigs Ann. Chem., 1985, 2061. 102. T.A. Pardoen, P.P.J. Miller, E.M.M. Van den Berg, and J. Lugtenburg, ~Can. J . Chem., 1985, 63, 1431. 103. T. Taguchi, A. Hosoda, and Y. Koboyashi, Tetrahedron Lett., 1985, 26, 6209. 104. H.J. Bestmann, P. Ermann, H. Ruppel, and W. Sperling, Liebigs Ann, Chem., 1986, 479. 105. G a a s o v and M. Sheves, J. Am. Chem. Soc., 1985, 107, 7524. 106. P. Patel and G . Pattenden, Tetrahedron Lett., 1985, 26, 4789. 107. M.C. Bowden, P. Patel, and G. Pattenden, Tetrahedron Lett., 1985, 26, 4793; 4797. 108. J.M. Williams and G.J. McGarvey, Tetrahedron Lett., 1985, 26, 4891. 109. D. Boschelli, T. Takemasa, Y. Nishitani, and S. Masamune, Tetrahedron Lett., 1985, 26, 5239.
so,
z,
I
Organophosphorus Chemistry
3 62
110. J.H. Bateson, A.M. Quinn, T.C. Smale, and R. Southgate, J. Chem. Soc., Perkin Trans.1, 1985, 2219. 111. T.C. Smale and R. Southgate, J. Chem. S o c . , Perkin Trans.1, 1985, 2235, 112. E.C. Taylor and H.M.L. Davies, J. Org. Chem., 1986, 5 l , 1537. 113. G.A. Tolstikov, M.S. Miftakhov, and A.G. Tolstikov, Tetrahedron Lea., 1985, 2 6 , 3867. 114. C.-Q. Han, D. Di Tullio, Y.-F. Wang, and C.-J. Sih, J. Org. Chem.. 1986, 51, 1253. 115, R.N. Young, E . Champion, J.Y. Gauthier, T.R. Jones, S. Leger, and R. Zamboni, Tetrahedron Lett., 1986, 2 7 , 539. 116. E.J. Corey, M. d'Alarcao, and K.S. Kyler, Tetrahedron Lett., 1985, -26, 3919. 117. A.K. Saksena, M.J. Green, P. Mangiaracina, J.K. Wong, W. Kreutner, and A.R. Gulbenkian, Tetrahedron Lett., 1985, 2 6 , 6427. 118. K.C. Nicolaou, C.A. Veale, S.E. Webber, and H. Katerinopoulos, JAm. Chem. S o c . , 1985, 107, 7515. 119. B.P. Gunn and D.W. Brooks, J. O m . Chem., 1985, 8 0 , 4418. 120 Y. Leblanc, B.J. Fitzsimmons, J. Adams, F. Perez, and J. Rokach, JOrg. Chem., 1986, 51, 789. 121 C.A. Moustakis, J. Viala, J. Capdevila, and J.R. Falck, J. Am. Chem. 1985, 107, 5283. ,.cK 122 * S. Manna, J. Viala, P. Yadagiri, and J.R. Falck, Tetrahedron Lett., 1986, 27, 2679. 123. K.C. Nicolaou, Y.S. Chung, P,E. Hernandez, I.M. Taffer, and R.E. Zipkin, Tetrahedron Lett., 1986, 2 l , 1881. 124. D. Culshaw, P. Grice, S.V. Ley, and G.A. Strange, Tetrahedron Lett., 1985, 26, 5837. 125. R.H. Schlessinger, M.A. Poss, and S. Richardson, J. Am. Chem. SOC., 1986, 108, 3112. 126. R. Zibuck, N.J. Liverton, and A . B . Smith, 111, J. Am. Chem. SOC., 1986, 108, 2451. 127 R.F.W. Jackson, M.A. Sutter,and D. Seebach, Liebigs Ann. Chem., 1985, 2313. 128 K.C. Nicolaou, T.K. Chakraborty, R.A. Dianes, and N.S. Simpkins, JChem. SOC., Chem. Commun., 1986, 413. 129. M.A. Tius and A.H. Fauq, J. Am. Chem. SOC., 1986, 108,1035. 130. M. Kodama, Y. Shiobara, H. Sumitomo, K. Fukuzumi, H. Minami, and Y. Miyamoto, Tetrahedron Lett., 1986, 2 7 , 2157. 131. A.B. Smith, 111, B.D. Dorsey, M. Visnick, T. Maeda, and M.S. Malamas, J. Am. Chem. S o c . , 1986, 108,3110. 132. H.J. Bestmann and M. Schmidt, Tetrahedron Lett., 1986, 27, 1999. 133. A.V.R. Rao and E . R . Reddy, Tetrahedron Lett., 1986, 27, 2279. 134. N.V. Bac, Y. Fall, and Y. Langlois, Tetrahedron Lett., 1986, 27, 841. 135. L. Crombie and S.J. Holloway, J. Chem. SOC., Perkin Trans.1, 1985, 2425. 136. H.J. Bestmann and H. Schmidt, Tetrahedron Lett., 1985, 26, 6171. 137. P.A. Grieco, T. Takigawa, and T.R. Vedananda, J. O m . Chem., 1985, 50, 3111. 138. J. Thiem and H. Luders, Liebigs Ann. Chem., 1985, 2151. 139. Y. Ogawa, M. Nunomoto, and M. Shibasaki, J. Org. Chem., 1986, 5 l , 1625. 140. J.D. White, K. Takabe, and M.P. Prisbylla, J. Org. Chem., 1985, S O , 5233. 141. P. Deshong, S. Ramesh, V. Elango, and J.J. Perez, J. Am. Chem. SOC., 1985, 107, 5219. 142. A.G.M. Barrett, H.B. Broughton, S.V. Attwood, and A.A.L. Gimatilaka, J. Org. Chem., 1986, S l , 495. 143. R.E. Harmon, G. Wellman, and S.K. Gupta, Carbohydr Res., 1910, . 4 l, t
a
I
I
-
-
-1
ILJ.
7: Ylides and Related Compounds
144. T.L. Cupps, D.S. Wise, Jr., and L.B. Townsend, J. Org. Chem., 1986, 51, 1058. 145. D. Doren, E. Kunz, and G. Helmchen, Tetrahedron Lett., 1985, 26, 3319, 146. T. Schotten, W. Boland, and L. Jaenicke, Tetrahedron Lett., 1986, 27, 2349. 147. G. Wickham, G.J. Wells, L. Waykole, and L.A. Paquette, J. O r p ; . 1985, 3485. 148. J. Ojima, E. Ejiri, T. Kato, S. Kuroda, S. Hirooka, and M. Shibutani, Tetrahedron Lett., 1986, 2 7 , 2467. 149. K. Yamamoto, M . Shibutani, S. Kuroda, E . Ejiri, and J. Ojima, Tetrahedron Lett., 1986, 27, 975. 150. J. Drew, G. Gowda, P. Morand, P. Prouex, A.G. Szabo,and D. Williamson, J. Chem. SOC.. Chem. Comun., 1985, 901. 151. M.L. Forcellese, S. Calvitti, E . Camerini, I. Martucci, and E . Mincione, J. Or%. Chem., 1985, 5 0 , 2191. 152. H. Mack and M. Hanack, Angew. Chem., Int. Ed. Engl., 1986, 25, 184. 153. L. Cardona, I. Fernandez, B. Garcia, and J.R. Pedro, Tetrahedron, 1986, 42, 2725. 154. T.J. Michalski, J.E. Hunt, J.C. Hindman, and J.J. Katz, Tetrahedron E., 1985, 26, 4875. 155. P.A. Aristoff, P.D. Johnson, and A.W. Harrison, J. Am. Chem. SOC., 1985, 107, 7967. 156. B.J. Walker, in 'Organophosphorus Chemistry', Ed. D.W. Hutchinson and B.J. Walker (Specialist Periodical Reports), The Royal Society of Chemistry, London 1986, Vo1.17, p . 3 4 2 . 157. A.T. Hewson and D.T. MacPherson, J. Chem. SOC., Perkin Trans.1, 1985, 2625. 158. T. Rosen and C.H. Heathcock, J. Am. Chem. SOC., 1985, 107,3731. 159. A. Kjaer, D. Kjaer, and T. Skrydstrup, Tetrahedron, 1986, 42, 1439. 160. R.R. Schmidt and P. Zimmermann, Tetrahedron Lett., 1986, 27, 481. 161. R.S. Compagnone and H. Rapoport, J. Org. Chem., 1986, 2 , 1713. 162. R. Dharanipragada and G. Fodor, J. Chem. SOC., Perkin Trans.1, 1986, 545. I
m.,
so.
3 63
Phosphazenes BY C.W. ALLEN
1
Introduction This chapter covers the literatures of phosph(v)azenes. The general pattern of development in this area is similar to that observed in previous yearly reviews with additional interest being shown in polyphosphazenes and in a variety of molecular orbital calculations of both linear and cyclic phosphazenes. Reviews are all limited to highly focused accounts and will be quoted in the appropriate sections below. 2 Acyclic Phosphazenes Acyclic phosphazenes (phosphazo derivatives, phosphine imines, phosphoranimines) continue to attract interest. A review of the three coordinate materials, RN=PR'=X has appeared. Several molecular orbital calculations have been reported. An ab initio treatment of the H2PN energy surface suggests that this species is best regarded as having a dative phosphorus-nitrogen double bond rather than a triple bond and the phosphonitrene, once formed, does not rearrange to the thermodynamically more stable isomer because of the high barrier to a 1,2 hydrogen shift.2 Extended basis set SCF calculations (including correlation effects) on (H2N)2PN give good agreement with the observed geometry and again the isomer resulting from the 1,2 hydrogen shift, (NH)2PNH2, is more stable. The (NH ) PN moiety has a highly reactive double bond 2 2 since it is an unprotected nitrene. All isomers are best considered as having a positively charged phosphorus atom with the (NH2)2PN species containing a 4 electron-3 center molecular orbital which is The possialternatively described by the canonical forms la-b. bility of coordination of the phosphonitrene, H2PN, to transition metal fragments has been explored by the use of extended Huckel calculations with behavior similar to that of aminonitrenes being ~ u g g e s t e d . ~An ab initio study of the bonding in the tricoordinate orbital contribution with 71 species HP(=NH)2 indicates a small ~b initio calculations polarization paralleling u polarization.
a
on the iminophosphorane H 3P=NH indicates a situation reminiscent of 3 64
8: Phosphazenes
-
RN=P
+
-NR,
IR
-
365
RN-LNR,
II
EljR
"
b
a
12)
Me
(.)
S
Me3SiCH-
PN=PPh,
P ''
N 2 Me
Me3SiN4
'N(SiMe3)2 ( 5 )
(4)
NEt,
I
MejSiN=P-CH2Si
(Me3Si1,N-P-
R'
I Me3SiN=P-CH(SiMe3)2
I CI
I
Me3
CH2Si Me3
Organophosphorus Chemistry
366
the phosphorus-carbon bond in ylides with a polar P + N bond counterbalanced, in part, by a .rN + P(dT) bond yet retaining significant dipolar (P, +0.73; N, -1.02) character.6 Semiempirical m.0. calculation (PRDDO) on the triphenylphosphazo derivatives, Ph3P=NC H -m,p-R (R=N02,CN,CF3,C1,F,H,CH3,0CH3, NMe2) suggest that *6 4 the uPN orbital is able to compete with fi orbitals in TT bond formation. Extensive spectroscopic data are also available for this series of compounds. Chemical shifts (31P, 15N, 13C) and 'JPc can be correlated with u- substituent constants and 3Jpc with uR-constants. The 13C nmr data indicates that the Ph3PN unit is a poorer donor to the aryl function than is the NH2 group. The oxidation potentials (obtained from cyclic voltammetry) can be correlated with u+ constants and the ionization potentials derived from the m.0. The 31P nmr parameters and structures of several short chain linear phosphazenes have been com8 pared to the corresponding polyphosphazenes (see section 6). The kinetics of the reactions of tributyl- and triphenylphosphines with alkyl azides show that steric hinderance is not a significant factor in the Staudinger reaction.' The reaction of PhNHN=C(N 3 ) C O 2Me with triphenylphosphine leads to the expected triphenylphosphazo derivative which may be cyclized with aldehydes to give triazoles.lo Straightforward applications of the Staudinger reaction lead to the preparation of unprotected sugar phosphinimines," 2-furylethylene (2) derivatives,12 1,3,4,2-oxadiazaphospholine imides (3),l3 bis (triphenylphosphazocarbonyl)amine, HN (CON=PPh3)2,14 and a novel iminophosphorane ( 4 ) with nitrogen atoms in all five positions15 Reactions of ionic phosphorus compounds with azides continue to appear including the first reported Staudinger reaction on an anionic phosphorus (111) species, PhP (CN)2C1-, which provides RN=P (Ph)(CN)2C1-. l6 Further details of the reactions of chlorophosphenium ions, R2NPCl'AlCl4-, with phenyl and trimethylsilyl azide leading to iminophosphonium The reaction of aminoand bis phosphocations have appeared. 17'18 (dialkoxyphosphiny1)diazoacetate with triphenylphosphine provides The reaction of ethyl diazoacetate C (=N-N=PPh3)C02Et. (EtO)2P (0) with the coordinated diphosphine in trans-[W(N2)(Ph2PCH2CH2PPh2)] leads to the dihydrazino derviative Ph2P(=N-N=CHC02Et)CH2CH2PPh2(=N-N=CHC02Et) 2 o The reactions of phosphines with diphenyl 21 diazomethane provides the hydrazinophosphoranes, R3P=N-N=CPh2.
calculation^.^
''
.
367
8: Phosphazenes
The 2+1 cycloaddition of (Me3Si)2NP(S)=CHSiMe3 with trimethylsilylazide leads to a novel three membered ring with a phosphazo substituent (5). The same product is formed by the cycloaddition of sulfur to the corresponding iminomethylene phosphorane.22 The 2+1 cycloaddition of hexafluoroacetone to the appropriate iminophosphine provides 6 . 23 The reaction of the A3-iminophosphine, (Me3Si)2NP=NP(CMe3)2, with bulky alkyl iodides occurs at the less basic, but more accessible, phosphorus atom giving RPN(SiMe3I2N=PI (CMe3)2. 2 4 The reaction of the methylene phosphine, (Me3Si)2NP=CHSiMe3, with diethylamine provides the aminophosphine Me SiNH3 PNEt2(CH2SiMe3) which in turn adds a second mole of dimethylamine to give the novel phosphorus (111)-phosphorus (v) derivative 7 . The aforementioned aminophosphine reacts with carbon tetrachloride to give Me3SiN=P(C1)(NET2)CH2SiMe3 while deprotonation gives the expected anion which may be quenched with Ph2PC1 to give Me3SiN= P (PPh2)(NET2)CH2SiMe3 or with (Me3Si)2NP (C1)CH2SiMe3 as an alternate route to 7.25 The reactions of carbon tetrachloride with aminophosphines of the type (Me3Si)3NP (R)CH (SiMe3) to give the iminophosphoranes ( 8 ) vary with the nature of R. The following pattern of functions in the aminophosphine (R) to those in the iminophosphorane (R') was observed : R=R'=Ph; R=Me, R'=CH and 3 CH2SiMf; R= CH2SiMe3, R'=CH(SiMe3)2; R= CH=CH2, R'=Me SiC=CH2 and 3 Me3SiCHCH2CC13. Upon heating, 8 [R'=CH(SiMe3)21 rearranges to Me3SiN=PCH (SiMe3 ) 2 (=CHSiMe3) 26 The reactions of other halofunctional compounds lead to linear phosphazenes e.g. R2PN(M)R' 11 (M=Li,Na) with dialkylchlorophosphines, R2 PC1, give tetraalkyldiphosphine imines, R2P(=NR')PR2 which rearrange to the isomeric diphosphazanes R2PNR'PR2'I.27 Also, the combination of amidophosphites, (EtO)2PNHC6H 4X with bis(catecho1)chlorophosphorane leads to the imino phosphoranes, 9, which undergo a 1,2 migration to the amides, 10. 2 8 The amidophosphites react with benzimidoyl chlorides to give (EtO)2~ ( = N c ~ H ~cx(=NR) ) Ph. 29 Prototropic rearrangements in aminodiphosphines can be induced by phosphorus alkylation reactions. Thus, the reaction of (Ph2PI2NH with triphenylcarbenium hexafluorophosphate produces Ph2P (HI=N-PPh2 (CPh3)+ and the corresponding ion with a methyl group in place of the CPh3 moiety is formed when methyl trifluoromethylsulfonate is the alkylating agent. In the mixed diphosphine, (CMe3I2PNHPPh2, the identity of the phosphorus atom undergoing attack depends on the nature of the
.
II
368
OrganophosphorusChemistry
alkyl (aryl)ating agent. 30 A variety of reactions with strong bases lead to linear phosphazenes e.g. the treatment of tetrakis(dialkylamino)phosphonium bromides with bases (OH-,NH2-) yields the iminophosphoranes, (R2N)3P=NR.31 The treatment of the aziridino derivatives, (C2H4N),(Et2N)3-nPNH2+ with sodium in liquid ammonia gives the iminophosphoranes (C H N) (Et2N)3-nP=NH ( ~ = 1 - 3 ) ? ~ 2 4 n A particularly noteworthy observation is that the bis(tripheny1reacts with sodium methoxide phosphine)nitrogen (+1) cation (PPN') to give Ph2P(0)N=PPh3. Thus, PPN' cannot always be considered to be a non-participating counter ion.33 Aziridine ring opening occurs upon direct halogenation of the dialkylamino aziridinophosphines, (R N) PNC2H4 to yield the iminophosphoranes, (R2N)2P(X) = 2 2 NCH2CH2X (X=Br, I) which spontaneously cyclize to diazaphospholidinium dihalides. 34 The aminolysis of hexachlorocyclodiphosphazanes, (C13PNC5H4N)2, leads to the 1,3-diaryl-2-oxo-imino-2,4diaminocyclodiphosphazanes, 11. 35 The thermolysis of bis (dimethylamino)phosphoranes leads to the cyclic dications [ (Me2N)2PNMe I 2+ which upon hydrolysis gives (Me2N)2P (0) N (Me)P (NMe2) = NMe. 362 Triphenylphosphine imine, Ph3P=NH, is obtained from the reaction of the thiazylchloride, (NSC1)3 , with triphenylphosphine.37 The thermolysis of dithiomethoxycarbonyl phosphonium iodide [Me3Si) NPMe2C(S)SMe]I gives the iminophosphorane Me3SiN=PMe2C(S)SMe. 3 g 2 The anions derived from deprotonation of R2P(X)NHR' (X=O,S) react I1 with non-metal halides Rn MX (M=Si, Ge, P) to provide either the n expected R2P(X)NR'MRn or the phosphazenes R2P(=NR')SMR - depending on the nature of-the substituents.39 '40 Numerous reactions, involving either transformation or conservation of the phosphazene unit, have been reported. The oxidation of the indanone phosphazene, 12, with singlet oxygen yields the corresponding ketone and triphenylphosphine oxide presumably via a 2+4 cycloaddition of oxygen to the -N=N-N=PPh3 unit which, following nitrogen elimination, forms the dioxetane, 13. 41,42 Reactions of phosphoramidic bromides, (R2N)2P (Br)=NR with aprotic nucleophiles occur at the phosphazene bond e.g. the addition of hexamethylphosphoramide gives (phosphiny1amino)phosphonium bromides, (R2N)2P (0)N (R)P (NMe2)3+Br-, while ethylene oxide gives The corresponding reaction with N-substi(R2N),P(0)N(R)CH2CH2Br. tuted aziridines gives diazaphospholidium bromides which upon reaction with sodium amide give N-vinyl iminophosphoranes, (R2Nl2II
369
8: Phosphazenes
i6h&x P-
P- N - P(0Et
P(0Et
(9)
12
(10)
(121
N= PPh,
0
CMe
'NHMc
Mc3C $C 'R *0 ;
CO, R
CMe3
CMc,
(14)
Me
T
F
e
( 1 5)
h
8
Ni
0
do, R R = SiMe,
(16) R2N
R N
R
(17)
370
Organophosphorus Chemistry
P (=NR)N (R)CH=CH2.4 3 The reactions of trichlorophosphazene-N-phosphoryl dichloride with the sodium salt of trifluoroethanol provide the series, (CF3CH20)3-n C1 P=NP(0)C12 (n_=1,2) and (CF CH 0) n 3 2 3P=NP (0)(OCH2CF3)2. Upon heating , (CF CH 0)C12P=NP (0) C12 is transformed into [C12P ( 0 )I 2NCH2CF3.443 Tie reactions of a-lithiated derivatives of RCH2PPh2=NPh with alkyl halides give the expected RR1CHPPh2=NPh entities while the reaction with benzonitriles gives p-R1C6H4C(NH2)=CRPPh2=NPh.4 5 The quaternization of [ (Me2N)3P=N)I 3P0 with methyliodide gives (Me2N)3P=N]3POMefI-. 4 6 Addition of organolithium compounds to the phosphazene bond in (Me3Si)(R)NP (=NR) followed by treatment with a proton donor gives (Me3Si)(R)NPR' (=NR)NRH.47 The desulfurization of 14 leads to without decomposition of the phosphazene unit. The reactions of a triphenylphosphazo uracil derivative with dialkyl acetylene dicarboxylates in aprotic solvents yields the pyridinedionates, 15, which undergo heterocyclization in protic solvents to give 16.49The presence of the phosphazo group greatly facilitates assignment of the I3C nmr spectra of 15 and 16. The trans-silylation of RR'R"P=NSiMe with hydro3 silanes leads to the replacement of the trimethylsilyl group with the SiMe2C1 and SiC13 functions.50 The reactions of Ph3P=NSiMe3 51 with tungsten hexafluoride provides WF6-n(N=PPh ) (n_=1,2) 3n_ while the analogous reactions with selenium tetrachloride give The reaction of (Ph3P=N)*SeC12 with (Ph3P=N) SeC14-n (g=l,2 ) n antimony pentachloride gives [(Ph3P=N)2SeCll+SbC+-. 52 The reaction of the phosph(II1)azene R2NP=NR (R=SiMe3) with bi(cyclooctadieny1) nickel(0) followed by treatment with bipyridine gives a nickel azadiphosphetine, 17. 5 3 Reaction R2NP (=NR) (R=SiMe3) with methyl lithium followed by treatment with zirconium tetrachloride leads 54 to the zirconacycle, 18. A few applications of acyclic phosphazenes have been mentioned. Derivatives of the type PhCH2PRR1=NR"(R"=H, Me, SiMe3) have been prepared and studied as perfumes. 5 5 The preparation paryl (N,Nbis(f3-chloroethyl)amino)-guanidinophosphates, (C1CH2CH2)2N=P(0)(OC6H4R)N=C(NH2)2, has been reported and it has been found that they exhibit lower toxicity and higher antitumor activity than do the corresponding diarylamidophosphates 56 Poly (methylsiloxanes) are stabilized by C13P=NPC12=NPC13+PC16-.57 The synthesis and use as lubricating agents of perfluoroalkyl monophosphazenes, (RO),-
2,4,6-(Me3C)3C6H21??NC6H2(CMe3)2Me
.
.
8: Phosphazenes
37 1
(Z=O, S; R=perfluoroalkyl; 5 = 1-3; y = 1,2) C13-xP=NP(Z)(OR) C 1 _y ggY havebeen patented. 3 Cyclophosphazenes A review of the applications of HUckel molecular orbital theory to various aspects of phosphazene chemistry, including geometric and electronic structure, reactivity and stability, has appeared. 5 9 More highly focused reviews on natural polyamino phosphazene derivatives6' and the use of the mass spectrometer to probe cyclophosphazene ring-opening polymerization6' are also available. There is renewed interest in theoretical calculations on cyclophosphazenes. The first non-empirical m.0. calculations (STO-3G * and STO-3G ) have been performed on cyclophosphazenes and it was determined that the phosphorus-nitrogen bond lengths can only be adequately reproduced with a basis set which includes phosphorus d functions.62 The recent report of the synthesis of a cyclodiphosphazene (see SPR 17) has generated interest in the electronic structure of these materials. Extended basis set SCF calculations suggest that the dimer, [(NH2I2PNl2, is best considered as having zwitterionic form with an additional tetravalent P+ in a P'Nnitrogen lone pair to phosphorus 3d orbital intera~tion.~The importance of the zwitterionic structure is also indicated in @ initio calculations using pseudopotentials on (H2 PN)-23' A large nitrogen P population and a strong interaction of phosphorus _dxy orbitals (thus favoring the Dewar island model) have been found. No evidence for transannular phosphorus-phosphorus bonding could be uncovered. 6 3 D e l Re calculations for nine cyclophosphazene derivatives have been reported and the total atomic charges are in agreement with 31P nmr chemical shifts, basicity data and first ionization potentials. 64 A theoretical model for exocyclic spirodelocalization, vi;5d?l-Ellbonds, to the phosphorus-nitrogen ring has been proposed. The electrochemical reductions of the spiro(phena1ene) derivatives (19, R=NMr, X=OCH2CF3; 20) have been reported. The fact that the esr spectra of the reduced species shows that at least half, and probably all, of the ring nuclei 65 are esr active lends support to the spirodelocalization model. The exo-endocyclic phosphorus-phosphorus coupling constants, J PP have been reported €or nineteen phosphazenylcyclophosphazenes. These measurements allow for extensions of previous correlations
Organophosphorus Chemistry
372
of solid state structures and solution conformations.66 The infrared spectra of the NH group in polyamines linked to cyclophosphazenes show evidence for some hydrogen bonding, allow for determination of NH acidity and correlations to biological activity have been proposed.67 Interest in the mass spectrometry of cyclophosphazenes continues. Loss of the amino substituent dominates the fragmentation of various dimethylamino derivatives of (NPX2)4(X=C1,F) while bromine atom loss is most significant in the fragmentation of N4P4F8-11XE (X=C1,Br; ;=2,4) 6 8 Gas phase ionmolecule reactions between various ammonium ions or radical cations and (NPC1 ) lead to the appropriate monosubstituted phosphazene derivativ;~?~’ Several investigations of the gas phase polymerization of cyclophosphazenes by mass spectrometry have been reported. The behavior of (NPCl2I4 is complex, including oligomerization up to (NPC12)12 and formation of N4P4;l7+ which is formulated as a cyclotriphosphazene with a NPC12 side chain. Evidence is presented to show that (NPCl2I3 and (NPC12)4 exhibit different gas phase polymerization processes. 70 The oligomerization of [NP(OPh) 3 in the ion source of a mass spectrometer has been examined.712 iimilar investigations on hexaminocyclotriphosphazenes show variable behavior, h. the hexa(ani1ino) derivative only undergoes fragmentation while the piperdino and morpholino derivatives undergo polymerization. As in the case of the hexaphenoxy and hexachloro derivatives, the oligomerization to the hexameric species is v i a the pentasubstituted cyclotriphosphazenium cation.72 The gas phase polymerization of tris (o-phenylenedioxy)cyclotriphosphazene in the mass spectrometer follows a different mechanism wherein a monomer adds to linear phosphazene radical cations.73 Scanning electron microscopy and x-ray crystallography (see section 7 ) studies have shown that the clathration of the tri(o-phenylenedioxy) derivative proceeds via a solid state monoclinic to hexagonal transition which provides improved opportunities for van der Waals attraction as the guest molecules enter 74 the lattice. Scattered reports of the synthesis of the cyclophosphazene ring system from the aminolysis of halophosphoranes continue to appear. The most interesting of these is the synthesis of the first spirocyclic organophosphazenes, [ (CH2)4PNl 3 , 4 , from (CH2)4PC13 and ammonium ~hloride.’~ The use of ammonium carbamate in
.
8: Phosphazenes
373
place of ammonium chloride in the synthesis of (NPC1 ) (n_=3-10) 211 has been reported.76 Measurement of HC1 absorption curves in the reaction of ammonium chloride and phosphorus(v) chloride show three distinct stages of the reaction and allow for kinetic measurements.77 A non-catalytic , two stage , process for the preparation of chlorophosphazene oligomers has been described.78 A s in previous years, most reports concern nucleophilic substition reactions of halocyclophosphazenes. The fluorination of &2,4-N P C1 (NEt2)2 (as monitored by I 9 F nmr and glc) with antimony 3 3 4 trifluoride gives the cis non-geminal difluoride while the use of potassium fluorosulfate gives the geminal difluoride. The tetrafluoro derivative, cis-2,4-N3P3F4(NEt2)2 can be obtained from treatment of the non-geminal difluoride with potassium fluorosulfate or the geminal difluoride with antimony trifl~oride.~’ A detailed study of the reactions of N3P3C15N=PPh3 with aziridine leading to the series N3P3 (NPPh3)C15,n (NC2H4)_n (n_=1-5) has appeared.80 The trans non-geminal derivative is favored (but not exclusively) at the mono stage of substitution. The non-geminal preference continues until the tris stage of substitution where only the geminal derivative is obtained. The fluoro derivative, N 3 P 3 F 5N=PPh3, is unreactive towards aziridine even under drastic conditions. The enzyme (reverse transcriptase) inhibiting activity of N3P3(NPPh3) (NC2H4)5 is much higher than that of N3P3(NC2H4)6.80 A study of isomer dependent cytostatic activity of a broad range of aziridinylcyclophosphazenes has shown that nongeminal bis derivatives of (NPC12)3,4 are potent tumor inhibitors in contrast to the geminal and mono substituted derivatives.81 DNA damage by trans-2,4-N3P3 (NC2H4) (NHMe) occurs V J crosslinking while with trans-2,6-N4P4(NC H ) (NHMeI6 both single strand breaking and cross-linking occurs.8 2 2 ilthough cumulative bone marrow toxicity induced by 2,2-N3P3(NC2H 41 4 (Pyr)2 (Pyr=pyrrolidinyl) leads to death in mice, the corresponding effect was absent when trans-2,4-N3P3 (NC2 H4 ) 2 (NHMe) was administered.83 The prepar14 ation of the C-14 labeled aziridinyl derivative, [NP(N C2H4l2I2NP (NC2H4)NC4H8C, has been noted.84 The reactions of (NPC12) with amine substituted polymers85 or carboxylic acid terminated polymers and diamines86 can be used to incorporate the cyclophosphazene into polymeric systems. The residual chlorine atoms in tris(hydroxyphenoxy)chlorocyclotriphosphazene have been allowed to
OrganophosphorusChemistry
374
6 #+
N
E
(E=O,NMe; X = CI ,0CH2CF,)
R = OCH,CF, (20)
(19)
R = OCH2CF3 (21)
-N-
N
II
FP-
CP M
CP
F2
ll N
'Ru
I =PF
' c p\
N
(M = Ru ,Fe 1
(22)
8: Phosphazenes
375
react with propyleneimine to give a material which is converted to a cross-linked polymer on heating.87 Interest in the reactions of phosphazenes with bifunctional reagents continues. The two ring assembly, N3P3C15NH(CH ) NHN3P3C15 ( g = 5 - 1 0 ) is obtained from 2n Mixed the reaction of N P C 1 with the appropriate diamines. 3 3 6 dispirocyclotriphosphazenes,N3P3C12 [NH (CH ) NH] [NH(CH ) NH] 2m_ 211 ~ # I J= 2,3,4) , have been prepared from the monospiro derivative and the diamine.*’ The reactions (NPC12) with the difunctional reagents NH2 (CH2lBNH2 (n=2,3), HO (CH ) OH (n=2,3 ) and MeNH (CH2)20H 2 n lead to the monospiro derivatives, N P C1 [X(CH ) XI (X=O,NH,NMe), 2 n 4 4 6 which can be then converted to the dimethylamino or methoxy derivatives. The compounds with two methylene units in the spirocyclic unit are particularly unstable. The reaction of (NPC12) with 2-bis(hydroxymethy1)carborane leads to the novel monospiro The reactions of 1 ,9-disubstituted phenalenes derivative 2 2 . with (NPCl2I3 lead to the spiro derivatives 19 (X=Cl). Only the amino derivative (19. E=NMe) can be derivatized with the trifluoroethoxide ion; the corresponding reaction with 19 (E=O) leads to disruption of the spirocyclic unit to form the monosubstituted derivative 20. Alkylation of 19 (E=NMe) gives the cationic species There has been an increase in the number of reports of the reactions of oxygen bases with cyclophosphazenes. A complete report of the reactions of N 3 P 3 X 5 N=PPh3 (X=F,Cl) with sodium methoxide to yield the series N3P3 (NPPh3)(OMe)nX5-Q (X=F,Cl; n=1-5) has appeared. Replacement of the chlorine-atoms gives isomers in unequal proportions, the &-2,4 derivative being the major product for “1 while the geminal isomer is formed when ~ = 3 . The corresponding reactions of the fluoro derivatives give geometrical isomers in roughly equal proportions. Although the chlorine atom at the ZPClNPPh3 center is fairly reactive, the corresponding displacement of a fluorine atom does not occur until all other fluorine atoms are displaced.9 2 The reaction of N3P3C15NPPh3 with excess methoxide ion gives, in addition to the expected pentamethoxy derivative, two hydroxy derivatives, N3P3(NPPh3)(OMe)5-n (OH) ( ~ = ,l2) which exist in the oxophosphazadiene form. Similar reactions of N3P3(NPPh3) (NMe2)C14 give a tetramethoxy derivative and N3P3 (NPPh3)“Me2) (OMe)30H. In both cases the monohydroxy derivatives are present as & and trans isomers.93 The conditions for the preparation of N 3 P3 C15OAr (Ar=C6H5, _p-BrC6H4, -p-MeC6H4) have been optimi~ed.’~The synthesis of the hexakis-
**
d5
OrganophosphorusChemistry
376
(methylacryloylethoxy)cyclotriphosphazene, N3P3(OCH2CH20C(0)C(Me)= CH2)695 and its use as a dental resing6 have been described. The reaction of (NPCl2I3 with octafluoropentoxytrimethylsilane is reported to give octafluoropentoxy derivatives. A series of mixed trifluoroethoxy-phenoxy derivatives of (NPC1,I3 have been Phase-transfer prepared and studied as fire resistant fluids. catalysis has been used in the preparation of (NP(OPh)2)3.99 The synthesis of the salt [N3P3(0NC H ) 16+(C1-)6 from (NPC12)3 and pyridine N-oxide has been reported.‘0° The pentakis allyloxy derivative, N3P3(OCH2CH=CH2)5(OCH2CHBrCH2Br) , has been prepared and grafted to cellulose by treatment with Ce(1V) .lol The reaction of sodium silicate with 2,4-N3P3C12(NMe is proposed to give siloxy-bridged cyclophosphazene polymers. f02 The interaction of N3P3(0Ph) C1 with the hydroxyphosphazenes, N3P3(0Ph)50H gives 5 POP-bridged cyclophosphazenes. The POP bridge in [N3P3(OPh)5 1 2O can be cleaved by nucleophiles to give N3P3(0Ph)5X(X=C1,F,0H,0Ph, OMe) l o 3 Patents on the preparation of condensed poly (alkoxyphosphazenes), low molecular weight oligomers, have been granted.lo4-lo6 Fewer papers than in previous years are available on organometallic reactions of cyclophosphazenes. The preparation of (NPMe2)6-12 from (NPF2)6-12 and methylmagnesium bromide and the characterization of (NPMe2)9-12 by X-ray crystallography (see section 7 ) makes this the largest known series of cyclic compounds with full structural characterization.lo7 Full details of the reactions of (NPC12)3 with methyl or t-butyl lithium and excess propan-2-1 have been reported. Mixtures of cylcic derivatives of various types, Q. alkylated, bicyclics and alkoxy hydrido derivatives are obtained in 80 to 90% yield.l o 8 The reaction of the transannular organometallic derivative 2,6-N4P4F6[(C5H4)2Ru] with a mixture of mono and dilithiated ruthenocene gives 23 (M=Ru) and the bis transannular derivative ( 2 4 ) . The fluorine atoms in 24 cannot be replaced by reaction with the methoxide ion. The reaction 2,6-N4P4F6[(C H ) Rul with (LiC H ) Fe only gives the iron 5 4 2 5 4 2 analog of 23 (M=Fe). I o 9 Reactions at the exocyclic position of cyclophosphazene derivatives represent a means f o r widely expanding the range of available phosphazenes. The synthesis of covalently bound cyclophosphazene heme complexes starts with N3P3(0Ph)5C1 which is converted to N3P3(OPh),NMeCH2CH2CN. Following reduction of the
’’ ’*
.
8: Phosphazenes
377
cyano function to the amine, coupling with porphyrins (a modified picket fence hemin and a protohemin chloride 3-(l-imidazolyl) propylamide) containing a carboxylic acid substituent leads to N 3P3 (OPh)5NMe (CH2)3NHC (0) R (R=(CH)2C ( 0 )NHC6H4 porphyrin, (CH2) porphyrin) 'lo The reduction of N3P3 (OPh)50C6H4CH0 followed by coupling with 4-nitro-2-dicyanobenzene leads to N3P3(0Ph)5OC6 H 4 CH,0C6H3(CN)2 which on treatment with cuprous bromide and substituted phthalonitriles give the copper phthalocyanine derivatives ( 2 5 ) which are non-aggregated in solution.11' The copolymerization of N3P3F5C(OEt)=CH2 with styrene or methyl methacrylate gives fire resistant copolymers with the cyclophosphazene as a substituent on the carbon-chain backbone. Reactivity ratio data and the derived Alfrey-Price parameters indicate that the major perturbation of the olefinic center is through the u electron withdrawThe hexallylamino derivative, ing effect of the phosphazene. '12 N P (NHCH2CH=CH2) undergoes photo reactions with polythiols.'13 3 3 The acylation of g-nitroaniline can be effected by a (NPC12)3 pyridine-N-oxide mixture in acetic acid. The reaction is first The reactions of N3P3 (OCH2CF3)50Na with order in phosphazene. sulfonyl chlorides lead to the sulfonates N3P3(0CH2CF3)50S02R which in turn react with organic acid chlorides to give phosphaPhoszene esters, N3P3 (OCH2CF3)50C (O)R, of varying stability.'15 phazene esters can also be prepared by the reaction of N3P3(0Me)5OH with acid chlorides and in turn may be converted to amides V I reaction with primary amines. The conversion of N 3P3C14 (NH2)2 to N 3P3C15NPPh3 by reaction with Ph3PC12 has been optimized. The monophosphazo derivative can also be prepared by the reaction of the diamine with triphenylphosphine in carbon tetrachloride or via a Staudinger reaction of triphenylphosphine with N3P3C15N3. The coordination of TaF5 to N3P3(OPhI6 in the 1:l addition compound is in a monodentate fashion through the nitrogen atom."* The few remaining miscellaneous patents include the use of
.
amidophosphazenes as soil urease inhibitors1lg the treatment of fibers with alkoxy, aryloxy or thioalkoxy phosphazenes to produce low friction and antistatic properties12* and the preparation of vinyloxyphosphazenes and their potential as comonomers in addition 121 polymerization. 4 Cyclophospha (thia)zenes Calculations at the MNDO and Hartree-Fock-Slater levels suggest
OrganophosphorusChemistry
378
that the five membered N2S2P ring, 26, is a stable, 6 a electron system. The reaction of 27 (X=Cl) with triphenylantimony leads to the radical (NPPh2)2(NS): The esr spectrum of this radical was obtained and ab initio calculations indicate that although the II system is highly polarized towards the NSN fragment, orbitals on the phosphorus atoms allow for delocalization of spin density from sulfur to phosphorus centers.123 The low temperature electronic absorption and preresonance Raman spectra of 28 and 29 have been observed. Details of the electronic spectra of 28 and 29 have been calculated from the Raman data. 124 The 6,6-spirocycleI 30, is obtained from the solid state thermolysis of 27 [X=C1,Br,I,N3 or NR (R=Me2, Et2, C5Hlo)I, 31, 32 or 33. In the case of the amino derivatives of 27, 34 is isolated and shown to be an intermediate from 27 to 30. The reaction of 27 (X=C1) with sodium azide yields 30, 32 and the new phospha(thia)zene, 35.125 Phospha(thia)zenes with four coordinate sulfur atoms continue to exhibit interesting chemical and biological properties. The reactions of NPC12(NSOX)2 (X=Ph,Cl,F) with the aliphatic difunctional reagents NH2 (CH2)2, 3YH (Y=NH, 0) give the spirocyclic derivatives NP [NH (CH2)2, 3Y1 (NSOX)2. The 31P nmr chemical shifts of these materials undergo a large change when included in the spiro ring. 126 The Friedel-Crafts reaction of (NPC12)2NSOC1 with monosubstituted benzenes, C6H5R (R=Me, OMe, Et, i-Pr, C1, Br, I) provide a route to (NPC12)2NSOC6H4R. For R=Me, OMe ortho-and paraisomers of the aryl ring were obtained while only the para-isomer was obtained for the remaining derivatives. In the Friedel-Crafts reaction of cis-(NPC12)(NSOC1)2 with chlorobenzene, five of the six possible NPC12 (NSOC6H4C1) isomers were isolated.127 The biological activity of the aziridino derivative [NP(NC2H4)2]2NSO(NC2H4) (SOAz) continues to be of interest. Although no detectable evidence for single strand breaks or DNA cross-linking was observed,82 significant bone marrow toxicity in mice has been noted.83 5 Miscellaneous Phosphazene-containing Ring Systems The reactions of phosphorus(II1) isocyanates, R2PNC0, with Measurements aldehydes lead to oxazaphospholines (36.128 12' of dipole moments and Kerr effects show that the orientation of the aryl groups in the aryl phosphatriazenes 37 (R,R'=Ar) is not coplanar with triazene ring. 130 The reactions of imidoylamines, RfC(=NH)N=CRfNH with PC15 give the chloro monophospha-s-triazenes 37 (R=C7F15, C3F70CF (CF3)CF20CF (CF3) ; R'=Cl) Similar syntheses
.
8: Phosphazenes
379
R
R
s-s X (26)
(27)
(28)
(29)
3 80
Organophosphorus Chemistry
can be effected using C6H5PC15 to give the monophenyl derivatives. The fragmentation patterns observed in the mass spectrometry of these materials have been presented.131 The reaction of (RO)2P ( 0 ) C (CH=CH2)=C=CMe2 with Et2NC (Ph)=NP (OEt) gives the complex heterocycle 3 8 . 132 The preparation of the borato phosphazenes 39 (X=F, Cl,Br,I) appears in a patent. 133 The dimerization of PhCH=NP (OR) leads to the diazadiphosphorine 4 0 . 134 The reactions of perfluoro amidines, RfC(=NH)NH2 with PhPC13-N=PPhC12 give the diphospha-2triazenes 41 (M=CRf; X=Cl) which undergo reaction with the azide ion and triphenylphosphine to give 41 (M=CRf; X=NPPh3). The mass spectrometry of the new compounds is discussed in The reactions of 41 (M=CRf; X=Cl) and 37 (R=Rf' R'=Cl,Ph) with phenyl thiol have been studied with the aim of preparation of anticorrosive and antioxidative fluids.136 The first cyclophosphazene with an endocyclic metal atom ( 4 1 , M=WC13) is obtained from the reaction of tungsten hexachloride with [H2NPPh2NPPh NH21 C1. 137 2 The nucleophilic degradation of white phosphorus with lithium bis(dipheny1phosphino)amide gives the fascinating phosphorus rich 138 cyclophosphazenes 4 2 . 6 Poly (phosphazenes) This section is devoted to polymers containing open-chain phosphazenes. Cyclolinear and cyclomatrix phosphazene polymers are covered in section 3. Reviews are limited to a discussion of the fluoralkoxy and aryloxy phosphazene polymers produced by the Ethyl corporation139 along with two brief reviews in Japanese covering current inorganic polymer research in Japan14' and structure, phase transition and applications of poly (phosphazenes) 14' Fundamental work on the ring-opening polymerization of cyclophosphazenes has appeared. The use of mass spectrometry to probe gas-phase polymerization of cyclophosphazenes was discussed in section 3 . The application Raman spectroscopy and laser light scattering to the study of both melt142 and solution143 polymerization of (NPC12)3 has been described. On line monitoring of the
.
~
-
melt polymerization gives data including gP and \ in situ for this process. 142 These techniques show that in the solution polymerization the molecular weight of (NPC1 1 remains relatively 211. constant during polymerization and that rates can be measured directly.143 The application of these and other methodologies has been applied to the boron trichloride catalyzed solution polymerization of (NPC12)3. The boron trichloride does not require water
38 1
8: Phosp hazenes
X
( 35)
(36)
X
I
Organophosphorus Chemistry
382
as a cocatalyst, is inhibited by arylphosphates and can be involved in initiation, catalysis and inhibition steps depending on concentration. A high yield of uncross-linked polymer with moderate molecular weight and wide polydispersity is obtained.144 Various patents on the formation of (NPC1 ) continue to appear. 2; The borato phosphazene, 3 8 , acts as a catalyst for this process. 133 A two step polymerization involving formation of oligomeric phosphazenes and their subsequent treatment with ammonium chloride has been noted. 145 The elimination of P0Cl3 from C12P (0)NPCl3 appears to be a good route to linear phosphazene polymers. 146 Treatment of the oligomeric materials Cl(PC1 N) POCl with linear PN salts147 2 1 1 or with PC15 followed by ammonium chloride348 also gives poly(phosphazenes). The interest in preparation of other poly(phosphazene) derivatives continues. The direct reaction of elemental phosphorus, ammonia and ammonium chloride in carbon tetrachloride leads to [(NH2)2PN]n which is claimed to be of value in chemotherapy. The meit polymerization of 22 and subsequent treatment with trifluoroethanol leads to a stable poly (phosphazene) The reaction of (NPC1 ) with diallylamine followed by treatment 2 n with alkoxy, aryloxy, amino or mercapto functions gives rubbery polymers.150 Mixed aryloxy/alkoxy phosphazenes, which have low Tg values and good smoke values in burning tests, can be prepared. 151 Patents describing improvements in the preparation of alkoxy or aryloxy poly(phosphazenes) include the sodium dispersion for the alcoholate preparation,152 solvent extraction to removal of metal halides153 and the use of solvents in which the metal chlorides are insoluble. 154 There is increasing interest in chemistry occurring at side chain positions of poly(phosphazenes). A series of polymers with etheric substituents, [NP(OR)2l and [NP(OR) (OR' 1 (R=OCH2CF3, Y 9 0(CH2)20Me, 0(CH2CH20)2CH3, 0(CH2CH20)12CH3), h a 6 been prepared. These materials are of potential biomedical interest and their salts are excellent solid state electrolytes.155 The lithium salts are good electrolytes for thin film batteries showing high ionic conductivity and high lithium transport numbers. 156 Other etheric phosphazenes where the phosphorus-nitrogen chains are cross-linked by oligo(oxyethy1enes) function as pseudo crown ethers and are active catalysts for nucleophilic substitution reactions.157 Alumina particles coated with [NP (OPh) 1 undergo 2 2 reactions at the phenoxy site. The aminophenoxy unit, which is
.
-
383
8: Phosphazenes
prepared by a nitration, reduction sequence, is activated by reaction with cyanogen bromide, nitrous acid or glutaric dialdehyde. Treatment with enzymes gives immobilized glucose-6-phosphate or trypsin. The bound enzyme retains activity and remains linked to the phosphazene through several catalytic cycles. lS8 Poly (phosphazenes) with covalently bound heme units have been prepared by routes identical to those used for preparation of the cyclotrimeric model systems (see section 3 ) . The electrochemical reduction of these species has been studied and the oxygen carrier ability has been probed by electronic spectroscopy and iron-57 Mossbauer specPoly (phosphazenes) with copper phthalocyanine side troscopy chains have also been prepared by the routes used to prepare the cyclotrimeric analogs (see section 3 ) . The oxidation potentials of these species are equivalent to those of the free copper phthalocyanine. Due to the fact that there is no significant interphthalocyanine contact, the electrical conductivity is in the semiconA full report of the hydroformylation behavior ductor range. of cobalt phosphines bound to poly(phosphazenes) has appeared. The reaction of dicobalt octacarbonyl with [NP(OPh)l.7(0C H P6 4 Ph2)o.3]G gives three different phosphine bound cobalt carbonyls. The initial hydroformylation activity of the heterogeneous catalyst is equal to that of homogeneous catalysts but deactivation occurs Poly (allylaminophosphavia carbon-phosphorus bond cleavage. (R=allyl, diallyl; R'=n-C H9 , piperidino) zenes) , [NP(NHR)( N H R ' ) ] are photocurable upon treatment with polythiols-I1' The use of 3aminopropyltriethoxysilane as a curing agent for poly(aminophos160 phazenes) has been mentioned. The solid state conformations of macromolecular phosphazene chains can be successfully modeled using short chain oligomers. In both cases, intramolecular non-bonded contacts are important in solid state stacking of chains.* Nmr relaxation studies of poly[bis(trifluoroethoxy)phosphazenel, PBFP, show that sample prehistory effects phase composition and phase dynamics. Poly alkoxy and aryloxyphosphazenes have been discussed as examples of condis (conformationally disordered) crystals which are a newly Two crystalline phases of polyrecognized type of mesophase. [di(4-isopropylphenoxy)phosphazenel have been identified by X-ray fiber diffraction. In each case, the side group location is the major structural determinant. The observation that the melting point, enthalpy of melting and crystallinity of melt crystallized
.'''
.
Organophosphorus Chemistry
384
PBFP increases as the temperature of prior annealing above the melting point increases has been taken to indicate that crystallization occurs in the mesophase region. Solution cast films of poly[bis(p-f1uorophenoxy)-phosphazenel show a thermally reversible transformation between a crystalline (hexagonally packed chains) and a mesophase. Cooling of the mesophase gives another The spherulitic form of crystalline form (planar &/trans) PBFP has been studied by electron scanning microscopy showing a morphology consisting of cospherical aggregates which change on heating. 166 Extensive structural and optical studies on PBFP show three polymorphic forms and a mesoform. The thermotropic transitions in these materials have been correlated to chain extension and folding.167 The kinetics of the transformation from two dimensional to a three dimensional structure in poly[bis(pmethylphenoxy)phosphazenel on passing through the mesophase has been studied by wide angle and small angle X-ray scattering.168 Low angle polarized light scattering and Z-ray studies on poly(phosphazenes) show that with alkyl groups in the side chain, chain crystallization occurs with long chain alkyl groups while with aryl groups both side chain and main chain effects are The thermal analysis of poly (diorganophosphazenes) important.16' show that Tg increases as the symmetry of the side group decreases and that the melt transition and crystallinity vanish if the backbone symmetry is removed. All of the organophosphazenes decompose in the range of 3 5 0 to 400° with (NPMe ) being the most 211 stable material.170 It has been found that poly[bis(4-benzoylphenoxy)phosphazene] is an efficient, reversible, triplet state energy donor thus inducing photoreactions in suitable acceptors.171 The photochemical iodine doping of.poly[bis(p-toly1amino)phosphazene] produces stable samples with specific conductivities which are two orders of magnitude greater than the undoped polymers 172 The addition of trinitrofluorenone to poly [bis(2naphthoxy)phosphazene] transforms the polymer to a strong photoconductor with high sensitivity.173 The thromboresistance of PBFB (in dogs) is higher than polyfethylene)or poly(tetraf1uoroethylene) 174 Solutions of PBFP with 0.16 mole percent residual chlorine atoms in blood serum show a viscosity decrease over a three month period, presumably due to hydrolysis, but no detrimental effect on the biological properties of the medium were 175 observed.
.
-
.
.
385
8: Phosphazenes
Applications of poly(ph0sphazenes) continue to be announced, particularly in the patent literature. The flame retardant properties of aryloxyphosphazene elastomers,176 poly (phenylphosphazene isothiocyanate)ethylenimine,177 along with the effects of a broad range of phosphazene polymers on the combustibility and smoke formation in epoxy resins17' have been pointed out. Processes for poly(ary1oxy or alkoxyphosphazene) foam production are available. 1 7 9 f 1 8 0 Increased interest has been shown in poly(phosphazene) membranes for the separation of gases181-184 and
.
fluids 185 The use of the commercial poly(phosphazene) fluoroelastomer, PNF, as a permanent soft liner for removable dentures has been proposed. 186 The use of naphthalenic derivatized plasticizers €or poly (phosphazenes)187 and the use of poly (phosphazenes) for the low-temperature vulcanization of chloroprene rubbers188 have been noted. Bis (perfluoromethyl)phosphazenes, [ (CF3)2PN] (;=3-100) give good heat resistance and flexibility to epoxy resins.189 7 Molecular Structures of Phosphazenes The following structures have been determined by X-ray diffraction. All distances are in picometers and angles in degrees. Compound C13P=NC( CF3) [O(CH2CH,)2N]3P=N
4
Reference
Comments PN 150.5(3);
190
L P N C 142.9(3)
P=N 159.1( I ) ; PN 164.2( 1)-1.66.3(
1)
P=N 158.9(2) ; L PNPexo148.3(2)
191 15
no PN data reported
49
16 (R=C2H5)
no PN data reported
49
WF4(N=PPh ) 3 2
PN 159.4(6); &s-0
51
15 (R=C2Hs)
Ph3P=NSeC1 3 (Ph P=N) 2SeC12 3 Ph3PNPPh20N( 10)
h
PN 160.0(4);
L SeNP
137.1(3)
52
PN 160.6(4);
LSeNP 124.5(3)
52
Average PN 158.2;
33
PNP 138
54
18
PN endocyclic 160.5(9); exocyclic 164.1(9)
17
P=N 155.6(2); PN endocyclic 170.0(3) 177.2(3), exocyclic 173.8(3), 175.9(3)
OP( C12)NPC13 OP ( C12)NP (C1 NPC13
161.9(9)
PN 158.0(8) , 151.9(8) PN 154.6(9), 154.3(9), 153.7(9),
53
8 158.9(9)
8
Organophosphorus Chemistry
386
Compound
Comments
Reference 8
[ C13PNP(C12)NP ( C12)NPC13]+PC16-
PN 149.8(5), 152.7(3)
157.2(5),
OP (OPh)2NP(0Ph)
PN 159.6(4),
152.5(4)
OP (NHPh)2NP (NHPh)
PN 161.0(2), 157.7(2) PNH 162.9 (2)-165.5 ( 3 )
8
PN 158('1), 157(1), 161(1) 156(1); PMI 162(1)-167(1)
8
21
8
PN 159.3(6); LNPN 116.7(22); L PNP 136.1(43)
107
PN 159.2(6); NPN 116.4(22); LPNP 138.2(52)
107
PN 159.6(5); 1: NPN 116.6(21); L PNP 134.8(45)
107
PN 159.6(5); NPN 116.3(22); L PNP 132.8(40)
107
PN endocyclic 156.7(4)-158.5(3); exocyclic 166.7(3), 167.1(3), planar N3P3 PN 152(1)-159(2)
65
PN 155.5(8),
158.1(8)
74
PN endocyclic 157.6(4)-161.0(4); PNPPh , 158.9(1), 155.7(5); PN exocyzlic (NC H ) 168.0(4)172.4(7) ; New2dPh3 conformation
80
74
24
PN 155.9-157.2(3); Average L PNP 109 134.2; boat conformation
30
PN(PNP fragment) 158.4(4)159.5 ( 4 ) PN(PNS fragment) 159.2(4)160.8(4) Planar P SN rings 2 3 PN (PNP fragment) 156.9 (6)158.7 (6) PN(PNS fragment) 160.8(5)162.2 (5) P2S2N4 rings puckered
125
PN endocyclic 160.8(5) ,161.3(6)
126
PN 157.3; Skew boat; cis-phenyl groups
192
33
125
3 87
8: Phosphazenes
Comments
Compound
Reference
[NP(n-C3H5) (i-C3H7)] (NSOPh)2
PN 1 6 1 . 0 ( 4 ) , 160.6(4); t w i s t boat; trans-phenyl groups
193
[NPI(i-C3H7) ] (NSOPh)
PN 1 6 1 . 0 ( 6 ) , 1 6 0 . 8 ( 6 ) ; t w i s t b o a t ; trans-phenyl groups
194
PN 1 5 6 . 8 ( 6 ) , 157.9(4) t r a n s - C6H4C1
127
PN e n d o c y c l i c 1 5 7 . 6 ( 1 2 ) , 1 5 9 . 8 ( 7 ) ; e x o c y c l i c 160.9(9) ; e x o c y c l i c N pyramidal
195
2
-
PN e n d o c y c l i c 1 5 8 . 9 ( 9 ) , 161.7(10);195 e x o c y c l i c 167.0 (10) ; e x o c y c l i c N pyramidal
PN 1 6 4 . 0 ( 7 ) , 1 6 6 . 3 ( 7 ) , 159.6(6); Planar r i n g
158.7(7),
f i b e r d i f f r a c t i o n s t u d y , two phases
137 163
References
26,
1 H. Germa and J. Navech, Phosphorus S u l f u r , 1986, 327. 2 M.T. Nguyen, M.A. McGinn,and A.F..Hegarty, J . Am. Chem. SOC., 1985, 107, 8029. 6494. 3 R . A h r i c h s and H . S c h i f f e r , J. Am. Chem. S O C . , 1985, 4 G. T r i n q u i e r and G . B e r t r a n s , I n o r & . Chem., 1985, 24, 3842. 5 W.W. S c h o e l l e r and C . L e r c h , I n o r g . Chem., 1986, 576. Can. J. 6 D. Gonbeau, G . P f i s t e r - G u i l l o u z o , M.-R. M a r i e r e s , a n d M. Sanchez, -Chem., 1985, 63, 3242. Chou, L . Throckmorton, 7 M. Pomerantz, D.S. Marynick, K . Rajeshwar, W.-N. E.W. T s a i , P.C.Y. Chen,and T . Cain, J . Org. Chem., 1986, 51, 1223. 8 H.R. A l l c o c k , N.M. T o l l e f s o n , R.A. Arcus,and R.R. W h i t t l e , J. Am. Chem. SOC., 1985, 107,5166. 9 M.P. Ponomarchuk, L . S . Sologub, L.F. Kasukhin,and V.P. Kukhar, J. Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1532. --10 L . Bruche, L. G e r a n t i , a n d G . Z e c c h i , S y n t h e s i s , 1985, 304. 1985, = , 5 7 . 11 J. Kovacs, I . P i n t e r , A. Messmer,and G . Toth, Carbohydr. 12 D. Vegh, M. K r i z , J . Kovac, A. F u l i e r o v a , a n d R. Kada, C o l l e c t . Czech. Chem. Commun., 1985, 50, 1415. 1 3 A. Razhabov a n d 3 . M . Yusopov, J. Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 667. 14 M.N. G e r t s y u k and L . I . Sarnarai, J. Org. Chem. USSR (Engl. T r a n s l . ) , 1985, 21, 1436. 15 D. Schomburg, U . Wermuth,and R . S c h m u l t z l e r , Phosphorus S u l f u r , 1986, 26, 193. 16 A. B a c e i r e d o , G . B e r t r a n d , J . P . Majora1,and K.B. D i l l o n J . Chem. SOC., Chem. Commun., 1985, 562. 17 M.R. Marre-Mazieres, M. Sanchez, R . Wolf,and J . B e l l a n , E .J. Chim., 1985, 3 , 605. 18 M.R. M a z i e r e s , M. Sanchez, J . B e l l a n , a n d R . Wolf, Phosphorus S u l f u r , 1986, 26, 97. -
107,
25,
=,
388
19 20 21
22 23 24
25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51
Organophosphorus Chemistry
P.S.Khokhlov, B.A. Kashemirov, A.D. Mikityuk, Yu.A. Strepikheev,and A.L. Chimishkyau, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1984, 54, 2495. R. Herrmann and A.J.L. Pomberio, _ Monatsh. 429. _ _ -Chem., 1986, J . Bellan, M.R. Marre-Mazieres, M. Sanchez,and J . Songstad, Comptes rendus, 1985, 785. E. Niecke, J . Boeske, B. Krebs,and M. Dartmann, Chem. Ber., 1985, 3227. E . Niecke, D. Gudat, W.W. S c h o e l l e r , a n d P. Rademacher. J . Chem. Soc.. __ Chem Commun. , 1985, 1050. L.N. Markovskii, V . D . Romanenko, E.O. K l e b a n s k i i , A . N . Chernega, M.Yu. Antipin, Yu.T. Struchkov,and I . E . Boldeskul, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 193. L.B. L i and R.H. Neilson, Inorg. Chem., 1986, 2,358. R.R. Ford and R.H. Neilson, Polyhedron, 1986, 643. V.L. FOSS, Yu.A. V e i t s , T.E. Chernykh,and I.F. Lutsenko, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1984, 54, 2386. --S.K. Tupchienko, T . N . Dudehenko,and A.D. S i n i t s a , J. Gen. Chem. USSR (Engl. 55, 1063. T r a n s l . ) , 1985, S.K. Tupchienko, T.N. Dudehenko and A.D. S i n i t s a , J . Gen. Chem. USSR (Engl. __ T r a n s l . ) , 1985, 55, 691. A.M. Caminade, E . Ocando, J . P . Majoral, M. C r i s t a n t e , a n d G . B e r t r a n d , Inorg. Chem., 1986, 712. A.P. Marchenko, G.N. Koidan and A.M. Pinchuk, J. Gen. Chem. USSR (Engl. T r a n s l . ) 1984, 2405. I.S. Zaltsman, G.N. Koidan, A.P. Marchenko,and A.M. Pinchuk, J . Gen. Chem. 2498. USSR (Engl. T r a n s l . ) , 1984, -D . J . Darensbourg, M . P a l a , a n d A.L. Rheingold, ~ Inorg._ Chem., 25, 125. _ 1986, _ V.V. Miroschichenko, A.P. Marchenko,and A.M. Pinchuk, J . Gen. Chem. USSR 1798. (Engl. T r a n s l . ) , 1985, -E.H.M. Ibrahim, E.M. Aba-Ella, R.S. Farag, A.E. A r i f i e n , I n d i a n J. Chem., S e c t . A., 1985,- 24.- 232. T K G e n y a , A . P . Marchenko,and A.M. Pinchuk, ---J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 624. M.B. Hursthouse, N.P. Walker, C.P. Warrens,and J . D . Woollins, J . Chem. Soc., Dalton T r a n s . , 1985, 1043. ___D.W. Morton and R.H. Neilson, Phosphorus S u l f u r , 1985, 315. V.L. FOSS, Yu.A. V e i t s , V.A. Leksunkin,and M.V. Gurov, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1458. Yu.A. Veits, V.L. FOSS, V.A. Leksunkin and M.V. Gurov, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 1459. -~ T. Akasaka, R. Sato, Y . Miyama,and W. Ando, Tetrahedron L e t t . , 1985, 843. T. Akasaka, R. Sato,and W. Ando, J . Am. Chem. Soc., 1985, 5539. A.P. Marchenko, V.V. Miroshichenko, A.A. Kudryavtsev and A.M. Pinchuk, J. _ Gen. Chem. _ __ _ _USSR _ _(Engl. _ _ T_r a-n s l . ) , 1984, 54, 2400. A. Quassini, R. DeJaeger,and J. Heubel, 2 . Anorg. A l l g . Chem., 1985, 531, 188. J. Barluenga, F. Lopez,and F. P a l a c i o s , J . Chem. Res., Synop., 1985, 211. G.N. Koidan, A.P. Marchenko,and A.M. Pinchuk, J. Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1453. V.D. Romanenko, V.F. Shulgin, V.V. Skopenko,and L.N. Markovskii, -J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 476. --~ M. Yoshifugi, K. Shibayama, K. Toyota, N. Inamoto,and S. Nagase, Chem. L e t t . , 1985, 237. H. Wamhoff, W. Schupp, A. K i r f e 1 , a n d G . W i l l , J. Org. Chem., 1986, 51, 149. W. Wolfsherger, Chem. -Ztg., 1985, 227 ( C s m x s t . , 9 8 6 , 148966 f ) H.W. Roesky, U. Seseke, M. Noltemeyer, P.G. Jones,and G.M. S h e l d r i c k , J. Chem. SOC., Dalton T r a n s . , 1986, 1309.
117,
301,
118,
1,
5,
54,
3,
55,
5,
55,
26,
107,
109,
.
~~
104,
3 89
8: Phosphazenes
H.W. Roesky, K.L. Weber, U . Seseke, W. P i n k e r t , M. Noltemeyer, W . Clegg
52
and G . M . S h e l d r i c k , J . Chem. SOC., D a l t o n T r a n s . , 1985, 565. S h e r e r , R . W a l t e r , a n d W.S. S h e l d r i c k , Angew. Chem. I n t . Ed. E n g l . , 1985, 525. L.N. Markovskii, V . D . Romanenkov, V.F. S h u l ' g i n , A.V. Ruban, A.N. Chernega, M.Yu A n t i p i n , a n d Yu. T . Struchkov, 3 . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1555. R . Muenstedt and U. Wannagat, ~Monatsh. Chem., 1985, 7. 1.1. Kuzmenko, -Farm. Zh. (K i e v ) , 1985, 7 1 (Chem. A b s t . , 1985, 103, 2 1 5 4 0 8 ~ ) . M. R i e d e r e r , U.S. US4564693 (Chem. A b s t . , 1986, 150215d). A . Q u a s s i n i and R . DeJaeger, F r . Demande FR 2548188 A 1 (Chem. - _ _Abst., 1985, 103, 8 8 0 8 4 j ) . N.L. Paddock, -___-I n t . Rev. Phys. Chem., 1986, 2, 161. J.-F. L a b a r r e , __-Top, C u r r . Chem., 1985, 173. P . T r a l d i , M . G l e r i a , G . A u d i s t o , S . Daolio,and E. Vecchi, --Comm. Eur. Commu n i t i e s , [ R e p . ] EUR, EUR 9421, Mass Spectrom. Large Mol., 1985, 303 (Chem. Abst., 1 9 8 r E 7 7 8 m a r R . C . Haddon, Chem. Phys. L e t t . , 1985, A 2 i , 372. G . T r i n q u i e r , J . Am. Chem. S O C . , 1986, 108, 568. C . M i h a r t , S . Raduly and Z . Simon, Rev. G m . __ Chim., 1983, 857 (Chem. A b s t . , 1984, 23595). R . C . Haddon, S.L. Mayo, S . V . C h i c h e s t e r , a n d J.H. M a r s h a l l , J . Am. Chem. S O C . , 1985, 107, 7585. M. B i d d l e s t o n e , R . K e a t , H . G . P a r k e s , H . Rose, D . S . R y c r o f t , a n d R.A. Shaw, Phosphorus S u l f u r , 1985, 25, 25. R. M a t h i s , M. W i l l s o n , F . M a t h i s , J.-F. L a b a r r e , G . Guerch, R . Lahana, A . Mahmoun,and F. S o u r n i e s , Spectrochim. Acta, P a r t A, 1985, G , 573. T . T . Bamgboye and O.A. Bamgboye, Org. Mass. Spectrom., 1985, 487. M. Gleria, S . D a o l i o , A.M. Maccioni, E. Vecchi,and P . T r a l d i , Org. Mass. Spectrom., 1985, 2, 686. M. G l e r i a , G . A u d i s i o , S . D a o l i o , E . Vecchi, P. T r a l d i , a n d S . S . Krishnamurthy, J . Chem. S O C . , D a l t o n T r a n s . , 1986, 905. M. G l e r i a , G . A u d i s i o , S. D a o l i o , P . T r a l d i , a n d E . Vecchi, J . Chem. SOC., 1547. D a l t o n_T r a n_ s . , 1985, ~ _ M. Gleria, G . A u d i s i o , S . D a o l i o , E . Vecchi,and P . T r a l d i , Org. Mass. Spectrom., 1985, 498. S. D a o l i o , P . T r a l d i , E . Vecchi,and M. G l e r i a , Org. _ _Mass Spectrom., 1985, 20, 492. H.R. A l l c o c k , M.L. Levin,and R.R. W h i t t l e , I n o r g . Chem., 1986, 41. R.C. O l i v a r e s and Y.L. Cantu, Revue Roamaine d e Chemie, 1985, 525. J . R e t u e n t and F . M a r t i n e z , Chem. I n d . (London), 1985, 597. E . Devadoss, J . Polym. Mater., 1984, 1, 170. H.M.Li, U . S . U S m 5 m e m . Abst:, 1986, 34464k). T . T . Bamgboye and O.A. Bamgboye, Spectrochim. Acta, P a r t A, 1985, G, 981. K.C.K. Swamy, M.D. Poojany, S.S. Krishnamurthy,and H. Manohar, -J . Chem. S_ O ~_. D ,_a l-t o n Trans., 1985, 1881. A.A. v a n d e r Huizen, T. W i l t i n g , J . C . van d e Grampel, P. L e l i e v e l d , A. van d e r Meer-Kalverkamp, H.B. Lamberts,and N.H. Mulder, J . Med. Chem., 1986, 1341. J . G . Z i j l s t r a , S . d e Jong, J . C . van de Grampel, E.G.E. d e V r i e s , a n d N . H . Mulder, Cancer R e s e a r c h , 1986, 46, 2726. N.H. Mulder, E . G . E . d e V r i e s , H. Timmer-Bosscher,and J . C . van d e Grampel, Eur. _ J. Cancer l i n ._O n_ col_ . , 1986, 195. _ _ C_ ~ G . V . Bornovalova, L.F. L i n b e r g , E.G. Tikhonova,and T . S . Safonova, Khim. 109782~). -Farm. 1985, 19, 583 (Chem. A b s t . , 1986, _ _ _ _Zh., _ R.E. Meyers, U.S. US 45351478 (Chem. A b s t . , 1985, 103, 143227k). R.E. Meyers, U.S. US 45337268 (Chem. A b s t . , 1985, 103, 1 4 2 9 6 6 ~ ) . E . Devadoss and C.P.R. Nair, Polymer, 1985, 6, 1895. ~~
53 54
55 56 57 58 59 60 61
O.J.
24,
116, 104,
129,
~
62 63 64 65
101,
28,
~
~
66 67 68 69 70
20,
~~
71 72 73 74 75 76 77 78 79 80 81
82 83 84 85 86 87
0,
5, 30,
104,
3,
22,
104,
Organophosphorus Chemistry
390
88 89 90 91
92 93 94 95 96 97 98 99 100 101 102 103
104 105 106 107
108 109 110
111 112 113 114 115 116 117 118
P. C a s t e r a , J . P . Faucher, G. Guerch, R. Lahana, A. Mahmoun, F. S o u r n i e s , 29. and J.F. Labarre, Inorg. Chim. Acta, 1985, M. Willson, L . L a F a i l l e , G . Comenges,and J.F. Labarre, Phosphorus S u l f u r , 1985, 25, 273. V . C h a z r a s e k h a r , S. Karthikeyan, S. S, Krishnamurthy, and M. Woods, I n d i a n J . Chem., S e c t . A, 1985, 379. -V.V. Korshak, N . I . Bekasova, M.P. P r i g o z h i n a , E.G. Bulycheva,and S.V. Vinogradova, Vysokomol. Soedin. S e r . B y 1985, 847 (Chem. Abst., 1986, 104, 168963f). E . K . Swamy and S.S. Krishnamurthy, Inorg. Chem., 1986, 920.
108,
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2,
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.
103,
103,
107,
Macromolecules.
31,
391
8: Phosphazenes
119 120 121
122 123 124 125 126
127 128 129
R . Medina and J . M . S u l l i v a n , D e f . P u b l . , U . S . P a t . O f f . T US 105605H (Chem. A b s t . , 1985, 103, 177559k). I . Noda, Jpn. Kokai Tokkyo Koho J P 60/173168 A2 (Chem. Abst., 1986, 104, 13141bd). C.W. A l l e n , K . Ramachandran, R . Bright,and J . C . Shaw, US 605317 A0 (Chem. Abst., 1985, 103, 7 1 9 6 ~ ) . 0. Treu J r . and M. T r s i c , J . Mol. S t r u c t . , 1985, 133, 1 . R.T. Oakley, J . Chem. S OC . , Chem. Commun.,1986, 596. Y . Y . Yang and J . I . Zink, I n o r g . Chem.?, 1985, 4012. T . Chivers, M . N . S . Rao,and J.F. Richardson, Inorg. Chem., 1985, 24, 2237. V . Hoeve, K.S. Dhathathreyan, J . C . van de Grampe1,and F. Van Bolhuis, 293. Phosphorus S u l f u r , 1986, F . J . Viersen, E. Bosma, B. d e R u i t e r , K.S. Dhathathreyan, J . C . van de Grampe1,and F. van Bolhuis, Phosphorus S u l f u r , 1986, 26, 285. R . I . Tarasova, T.A. Dvoinishnikova,and M . V . Alparova, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 739. R . I . Tarasova, T.A. Dvoinishnikova, N . I . S i n i t s y n a , L.A. Vasyakina and V.V. Moskva, I z v . Vyssh. Ucheben. Zaved., --Khim. Khim. Teknol., 1985, 28, 39 (Chem. Abst., 1986, 8 8 6 8 4 a r S.B. Bulgarevich, N.A. Ivanova, P.P. Kornuta, N.V. K o l o t i l o , T . A . Yusman, D.Ya. Movshovish, V.A. Kogan,and O.A. Osipov, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 142. K . J . L . Paciorek, J . H . Nakahara, M.E. Smythe, D.H. H a r r i s , a n d R.H. K r a t z e r , J. F lu o r i n e Chem., 1985, 28, 441. Z.A. Bredkhina, N . G . Khusainova, Yu.Ya. Efremov, R.L. Korshunov,and A.N. Pudovik, J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1710. D.F. Graves, U.S. US 45240526 (Chem. Abst., 1985, 71827f). L . I . Nesterova and A.D. S i n i t s a , J . Gen. Chem. USSR (Engl. T r a n s l . ) , 1985, 55, 1064. K.J.L. P a c i o r e k , D.H. H a r r i s , M.E. Smythe, J . H . Nakahara,and R.H. K r a t z e r , J . F l u o r i n e Chem., 1985, 28, 387. K . J . L . Paciorek, D.H. H a r r i s , J.H. Nakahara, M.E. Smythe,and R.H. K r a t z e r , J. _ F l_ u o_ r i n_ e Chem., 1985, 28, 399. _ H.W. Roesky, K.V. K a t t i , U . Seseke, M. W i t t , E. E g e r t , R . Herbst,and G.M. S h e l d r i c k , Angew. Chem. I n t . Ed. Engl. 1986, 25, 477. A. Schmidpeter and G. Burget, Angew. Chem. I n t . Ed. Engl., 1985, 580. H.R. Penton, Kautsch. Gummi, K u n s t s t . , 1986, 39, 301 (Chem. Abst., 1986, --104, 2 2 6 1 3 1 ~ ) . K. Murakami, Kino Zairyo, 1985, 5, 5 (Chem. Abst., 1985, 1239405). T. Masuko, Kob u n s h i , 1985, 932 (Chem. Abst., 1986, 51295~). D.-C. Lee, J . R . Ford, G . F y t a s , B . Chu,and G.L. Hagnauer, Macromolecules, 1986, 19, 1586. B. Chu and D.-C Lee, Macromolecules, 1986, 1592. M.S. S e n n e t t , G . L . Hagnauer, R.E. S i n g l e r , a n d G . Davies, Macromolecules, 959. 1986, H.M.Li, U . S . US4551317A (Chem. Abst., 1986, 187113~). R. DeJaeger, M. H e l i o u i , a n d E. P u s k a r i c , U.S. US 45445368 (Chem. Abst., 34521b). 1986, G.S. Lum, H.M. L i , F.A. P e l t i g r e w , U.S. US 4522798A (Chem. Abst., 1985, 103, 88376f). F.A. P e t t i g r e w , H.M.Li,and G.S. Lum, U.S. US 4522797A (Chem. Abst., 1985, 103, 3 7 8 9 7 ~ ) . H.A. Lehmann, H. Schadow, B. Thomas, W. Topelmann, K . D o s t a l , L . Meznik, E . Herrmann,and S . Albrecht, Ger. (East) DD 226291 A 1 (Chem. Abst., 1986, 104, 1 4 7 6 6 9 ~ ) . W.L. Hergenrother and A.F. Halasa, U.S. US 4558103A (Chem. Abst., 1986, 104, 8 9 2 4 7 ~ ) .
24,
26,
3,
130
131 132 133 134 135 136
137 138 139 140 14 1 142 143 144 145 146 147 148 149
150
103,
24,
103, 104,
34,
2,
19,
104,
104,
392
Organophosphorus Chemistry
151 F.A. Peltigrew and H.R. Penton, U.S. US 4567229 A (Chem. Abst., 1986, 104, 187469r). 152 G.M. Sulzer, R.W. Riley, Jr.,and D.H. Thomas, Em. Pat. Appl. EP 159020 A2 (Chem. Abst., 1986, 104, 69351~). 153 M.K. Juneau, U.S. US 4576806 A (Chem. Abst. , 1986, 104, 209498d). 154 H.R. Penton, U.S. US 4514550 A (Chem. Abst., 1985, 103, 6898r). 155 H.R. Allcock, P.E. Austin, T.X. Neenan, J.T. Sisko, P.M. Blonsky,and D.F. Shriver, Macromolecules, 1986, 19, 1508. 156 P.M. Blonsky, D.F. Shriver, P. Austin,and H.R. Allcock, Polym. Mater. Sci. Eng., 1985, 2, 118. 157 V. Janout, P. Cefelin, D.R. Tur,and S.V. Vinogradova, Polym. Bull., 1986, 15, 311. 158 K R . Allcock and S. Kwon, Macromolecules, 1986, 2, 1502. 159 R.A. Dubois, P.E. Garrou, K.D. Lavin and H.R. Allcock, Organometallics, 1986, Iy460. 160 V.A. Kovyazin, G.I. Mitropol'skaya, V.M. Kopylov and M.A. Dolgikh, U.S.S.R. SU 1164241 A1 (Chem. Abst., 1985, 103, 142555d). 161 V.M. Litvinov, V.S. Papkov,and D.R. Tur, Vysokomol. Soedin., Ser. A, 1986, 28, 289 (Chem. Abst., 1986, 104, 187159q). 162 B. Wunderlich and J. Grebowicz, Polym. Sci. Technol. (Plenum),1985, 28, 145. 163 S.V. Meille, W. Porzio, G. Allegra, G. Audisio,and M. Gleria, Makromol. Chem., Rapid Commun., 1986, 7, 217. 164 V.S. Papkov, V.M. Litvinov, 1.1. Dubovik, G.L. Slinimskii, D.R. Tur,and S.V. Vinogradov, Dokl. Akad. Nauk SSSR [Phys. Chem.], 1985, 284, 1423. 165 S. Matsuzawa, K. Yamaura, T. Tanigami,and M. Higuchi, Colloid polvm. a, 1985, 263, 888. 166 M. Kojima and J.H. Magill, Sen'i Gakkaishi, 1986, 42, 111 (Chem. Abst., 1986, 104, 187231g). 167 M. Kojima and J.H. Magill, Polymer, 1985, 26, 1971. 168 J.H. Magill and C. Kiekel, Makromol. Chem., Rapid Commun., 1986, 1, 287. and V.P. Shibaev, 169 I.B. Sokol'skaya, Ya.S. Freidzon, V.V=hervinskii Vysokomol. Soedin., Ser. A, 1986, 28, 300 (Chem. Abst., 1986, 104, 207994~). 170 J.J. Meister, P. Wisian-Neilson,and R. Neilson, Polym. Mater. Sci. Eng., 1985, 52, 528. 171 M. Gleria, F. Minto, S. Lora, L. Busulini,and P. Bortolus, Macromolecules, 1986, 19, 574. 172 G. Beggiato, G. Casalbore-Miceli, G. Giro,and S. Lora, Eur. Polym. J., 1986, 22, 245. 173 P. DiMarco, G. Giro, M. Gleria,and S. Lora, Thin Solid Films, 1986, 135, 157. 174 D.R. Tury V.V. Korshak, S.V. Vinogradova, N.B. Dobrova, S.P. Novikova, M.B. Il'ina and E.S. Sidorenko, hcta Polym., 1985, 36, 627. Slonimskii, M.N. Il'ina, 175 D.R. Tur, V.V. Korshak, S.V. Vined-.L. 1.1. Dubovik, N . I . Provotorova, N.B. Dobrova,and E.V. Smurova, Acts Polym., 1986, 37, 203. Chem. Abst., 1986, 104,70080r. 176 -SU 1154293 A1 177 S.I. Golina, G.I. Mitropol'skaya,and S . N . Glushakov, U.S.S.R. (Chem. Abst. , 1985, 103, 142942~). 178 -Chem. Abst., 1986, 104,89673h. 179 W.B. Mueller, U.S. US 4536520 A (Chem. Abst., 1986, 104, 6680j). 106109~). 180 W.B. Mueller, U . S . US 4535095 A (Chem.Abst., 1985,-=, 181 M.A. Kraus and M.K. Murphy, Eur. Pat. Appl. EP 149988 A2 (Chem. Abst., 1985, 103, 1615802). 182 M. K a j s r a , PCT Int. Appl. WO 85/1669 A1 (Chem. Abst., 1985, 103, 161482~). 183 M.K. Murphy, Eur. Pat. Appl. EP 150699 A2 (Chem. Abst., 1985, 103, 216563d). ~2 184 F. Fujita and M. Hirakawa, Jpn. Kokai T o k k y ~ 0 ~ 6 0 / 1 6 6 0 0(Chem. Abst., 1986, 104,90039n).
393
8: Phosphazenes
185 M.A. Kraus and M.K. Murphy, Eur. Pat. Appl. EP 150700 A2 (Chem. Abst., 1985, 103, 179417m). 186 L. Gettleman and L.M. Ross, Polym. Mater. Sci. Eng., 1985, 53, 770. 187 A.E. Oberster and J.C. Vicic, U.S. US 4567211 A (Chem. Abst., 1986, 104, 150221~).
Chem. Abst., 1985, 103, 7575v. 188 -189 Hitachi, Ltd., Jpn.Kokai Tokkyo Koho JP 60/60128 A2 (Chem. Abst., 1985, 103, 161480s). 190 M.Yu. Antipin, Yu. Struchkov,and E . S . Kozlov, J. Struct. Chem. (Engl. Transl.), 1985, 26, 5 7 5 . 19 1 G.O. Nevstad, C. R#mming,and J. Songstad, Acta Chem. Stand., Ser. A, 1985, A39, 691. 192 A. Meetsma, A.L. Spek, H. Winter, C. Cnossen-Voswijk, J.C. van de Grampel, and J.L. DeBoer, Acts Crystallogr., Sect.C: Cryst. Struct. Commun., 1986, C42, 365. 193 A. Meetsma, A.L. Spek, H. Winter, J.C. van de Grampe1,and J.L. DeBoer, 368. Acta Crystallogr., Sect. C: Cryst. Struct. Commun., 1986, 194 A. Meetsma, A.L. Spek, R. Olthof-Hazekamp, H. Winter, J.C. van de Grampel, and J.L. DeBoer, Acts Crystallogr., Sect. C: Cryst. Struct. Commun., 1985, C41, 1801. 195 T.S. Cameron, J . F . Labarre, F. Sournies, J.C. van de Grampe1,and A.A. van de Huizen, J . Chim. Phys. Phys.-Chim. Biol., 1985, 82, 941.
s,
Physical Methods BY J. C. TEBBY
T h e a b b r e v i a t i o n s n 2 , n', n 4 , n', a n d n6 r e f e r t o t h e c o - o r d i n a t i o n number of phosphorus a s opposed t o t h e commonly used valency term, A , w h i c h d o e s not d i s t i n g u i s h b e t w e e n p h o s p h o n i u m s a l t s , p h o s p h i n e o x i d e s etc. a n d p e n t a - c o v a l e n t p h o s p h o r a n e s . C o m p o u n d s i n e a c h subsection a r e usually dealt with in t h e a b o v e order. I n t h e formulae, the letter R represents hydrogen, alkyl or aryl, X represents a n electronegative substituent, Ch represents chalcogenide (usually oxygen a n d sulphur), and Y and Z a r e used t o r e p r e s e n t g r o u p s o f a m o r e v a r i e d n a t u r e . A s in p r e v i o u s v o l u m e s t h e terminology apical and radial has been retained f o r the s t e r e o c h e m i c a l d e s c r i p t i o n o f s u b s t i t u e n t s o n 'n a t o m s t h a t p o s s e s s t r i g o n a l b i p y r a m i d a l g e o m e t r y , so t h a t t h e t e r m s a x i a l a n d equatorial can be reserved to describe the conformational p r e f e r e n c e s o f s u b s t i t u e n t s o n n4 a t o m s o f a n y e l e m e n t in s i x membered and related rings. T h e non-IUPAC nomenclature "phosphane" is u s e d f o r n3 p h o s p h o r u s c o m p o u n d s i n g e n e r a l , r e s e r v i n g t h e t e r m "phosphine" for phosphanes which possess three carbon o r hydrogen substituents and the term "phosphite" f o r phosphanes which possess three alkoxy o r aryloxy substituents. T h e number of theoretical studies involving phosphorus compounds and their reactions has grown sufficiently to warrant a separate section this year. T h i s now f o r m s section 1 of t h i s chapter. Theoretical studies relating t o specific physical m e t h o d s will be f o u n d i n t h e a p p r o p i a t e s e c t i o n a s usual. In addition, studies of the kinetics of equilibria and reactions involving organophosphorus compounds have been reviewed and this a p p e a r s in section 1 1 at t h e end of t h i s chapter.
1
Theoretical Studies
A b i n i t i o NO c a l c u l a t i o n s o n t h e b o n d i n g o f t h e d i p h o s p h e n e (1, X = HI i n d i c a t e d t h a t t h e PP n - b o n d is s i g n i f i c a n t l y s t r o n g e r t h a n t h a t f o r SiSi a n d is s u f f i c i e n t t o p r o d u c e a p l a n a r m o l e c u l e w h i c h
Y =
394
9: Physical Methods
395
e v e n p e r s i s t s in t h e a n i o n r a d i c a l w h e r e t h e b o n d o r d e r 15 o n l y 1.5. T h e PP b o n d r o t a t i o n a l b a r r i e r is e s t i m a t e d t o b e 63.5 kcal m c l - ' A t h e o r e t i c a l s t u d y of w h i c h is v e r y s i m i l a r t o d i i m i n e (HN=NH).' the cycloaddition reactions of dienes with two coordinate molecules ( l ) , ( 2 ' ) a n d ( 3 ) s h o w e d that t h e a m i n o s u b s t i t u t e d c o m p o u n d s ( 1 - 3 , X = NR2) are electron-donating towards the dienes, whereas others had e l e c t r o n - a c c e p t i n g properties.' The energies and properties of d i p h o s p h i n e ( 1 , X = Y = H) a n d c y c l o p o l y p h o s p h i n e s (PHj3-6 h a k e b e e n e s t i m a t e d by a b i n i t i o m e t h o d s t 3 T h e s t r u c t u r e o f i m i n o p h o s p h i n e sulphides and their desulphurisation have been studied using similar methods.' Ab initio calculations have been applied to a number o f p h o s p h i n e s . T h e b o n d i n g in t h e p h o s p h i r e n e (4) a p p e a r s t o i n v o l v e whereas the s i g m a d e l o c a l i s a t i o n a n d a E-II A-n interaction,' inversion barriers o f primary and secondary phosphanes ( 5 ) increase T h e barriers to w i t h r i s e i n e l e c t r o n e g a t i v i t y o f X a n d Y.6 n i t r o g e n i n v e r s i o n in d i f l u o r o a m i n o p h o s p h i n e h a v e a l s o b e e n studied.' Studies of hyperconjugation and the molecular orbitals of phospholane indicated increased electrophilicity of the antibonding o r b i t a l s o n t h e e n d o c y c l i c b o n d s t o phosphorus." The conformations of teraalkyldiphosphines and di-t-butylphosphines have b e e n s t u d i e d u s i n g e x t e n d e d H u c k e l calculations' a n d m o l e c u l a r mechanics," r e s p e c t i v e l y . T h e a n o m e r i c e f f e c t i n v o l v i n g t h e PH2 g r o u p is g r e a t l y a t t e n u a t e d r e l a t i v e t o nitrogen. T h i s is attributed to the poorer r-donation properties a n d lower MNDO c a l c u l a t i o n s a r e e l e c t r o n e g a t i v i t y o f s e c o n d r o w elements." a l s o reported on the circumbulatory rearrangement o f cyclopentadienephosphines ( 6 ) . The sigmatropic arrangement with r e t e n t i o n is f a v o u r e d f o r t h e f l u o r i d e (6, Y = F ) but i n v e r s i o n o c c u r s w h e n Y is trirnethylsilyl.'' Two s t u d i e s o f a3 A 5 m o l e c u l e s h a v e b e e n r e p o r t e d . One c o n c e r n e d t h e d i i m i n o p h o s p h a n e ( 7 ) a n d its dimers,'= t h e o t h e r c o n c e r n e d t h e r e a c t i o n o f m e t a p h o s p h a t e w i t h p r o t o n donors.'' T h e r e h a v e b e e n a b i n i t i o s t u d i e s of t h e b o n d i n g f o r a s e r i e s o f i m i n o a n d a m i n o p h o s p h o r u s molecules," and for the phosphonium y l i d e s (8).16 T h e a n i o n c h a r a c t e r of t h e y l i d i c c a r b o n is intermediate between that of olefinic and substituted carbanions. Polarisation o f the HJP group has a stabilising effect. T h e i n f l u e n c e of t h e s u b s t i t u e n t X o n t h e i n v e r s i o n o f t h e c a r b a n i o n a n d a l s o the tendency o f the molecule t o dissociate to carbene and CNDO/S MO c a l c u l a t i o n s o n t h e p h o s p h i n e is a l s o discussed."
396
Organophosphorus Chemistry
x\
P= P Y '
x\
x\
P=cYz
P=N
\Y
Ph
PR
Ph
\/ RCEP
Ph2P' NC-C,
It
-P= P 'C-CN
II
,PPh2 P= P
//
(9)
Ph
(11)
Ph
CO, R (BU'S)~C=P /
But But
(12)
(13) t
BU - P
Et -Me /p Ph (151
w
Et
P
\
(16)
Ph (17)
9: Physical Methods
397
conformational preferences of 1,3,2- and 1 , 3 , 5 - d i o x a p h o s p h o r i n a n e s includes a n estimate of coupling effects." T h e role o f d-orbitals and the phosphoryl electron pair in the stabilisation of ethyl phosphonate free radicals has been studied.'' A theoretical study of model pentacoordinate phosphoranes H4PX was directed at estimates of geometries, electron densities and apicophilicities of X . T h e order for ligand apicophilicities is as fOllOWS.'~ C1 > C N > F > CZCH > CH3 > OH > 0- > S- > NHz > BHz
2
Nuclear Magnetic Resonance Spectroscopy
- Phosphorus-31 n.m.r. continues to expand its application in the medical and biological fields2" and is now being applied to soil a n a l y ~ i s . ' ~ T h e problems involved in the use of FT " P n.m.r. for quantitative determinations have been discussed.22 Samples of phosphinic carboxylic acids were cooled to -40°C for quantitative estimations."
2.1 Biological and Analytical Applications.
2.2 Chemical Shifts and Shielding Effects. 2.2.1
Phosphorus-31. Positive shifts a r e downfield of the reference
85% phosphoric a c i d , and are usually given without the appellation
p+p.m. of n' and n' compounds. Phosphaalkyne chemistry has taken a large step forward. Five new compounds ( 9 , R = P h , T m s , 1-adamantyl, iso-propyl, neo-pentyl) have been characterised and found to possess a range of chemical shifts between -51.4 and -66.0." The so-called hydrobromide derivatives have shifts much further downfield ( 0 - 512' and thus there must be some doubt now on the validity of their proposed structures. Many new types of phosphalkenes have been prepared. Their chemical shifts vary from -141.5 for the cyclic polyphosphine to -62.6 for the diamino compound (11, Y = H ) 2 7 , to -10.7 for the phosphinophosphaalkene (11, Y = PBu",'' moving downfield to 287.7 for the dithio compound ( 1 2 ) , " and to 312 for the Dewar analogue (13, R = Pr'),30 and at lowest field, 350 to 367 for the halides (14, Hal = F , B r , I ) . 3 1 6~ of n3 compounds. A number of three membered phosphorus heterocycles have been described.32 All resonate well upfield e 3 . -171.8 6p
398
Organophosphorus Chemistry
f o r t h e C i s - p h o s p h i r a n e ( 1 5 1 , -181.5 f o r t h e t r a n s - i ~ o m e r ~ a~ n,d -188.1 f o r t h e p h o s p h i r e n e (16>.34 V a r i o u s t r i f l u o r o m e t h y l t e r t i a r y p h o s p h i n e s h a v e b e e n p r e p a r e d by D i e l s - A l d e r r e a c t i o n s . T h e y h a v e c h e m i c a l s h i f t s in t h e r a n g e -20 t o +40.35 W h i l s t a r e c o r d d o w n f i e l d s h i f t (152.5) w a s o b s e r v e d f o r t h e b i c y c l i c p h o s p h i n e (17),3h the underlying reasons f o r the very large deshielding effect o b s e r v e d f o r t h i s t y p e o f c o m p o u n d h a v e yet t o b e d e t e r m i n e d . A n u m b e r o f A 5 n3 c o m p o u n d s (18) h a v e c h e m i c a l s h i f t s i n t h e r a n g e 127 t o 178.37 A t h e o r e t i c a l s t u d y s u p p o r t s t h e s u g g e s t i o n m a d e in t h e last v o l u m e t h a t t h e s e c o m p o u n d s a r e r e p r e s e n t e d a s phosphonium ylides with the negative charge distributed between the t w o sp' c a r b o n a t o m s b o u n d t o t h e p h o s p h o r u s atom.38 6 p o f n4 c o m p o u n d s . Transmission of substituent effects in a r y l d i m e t h y l p h o s p h i n e b o r a n e s h a v e b e e n s t u d i e d by n.m.r.39 A detailed investigation of the 3 1 P chemical shift t r e n d s o f phosphoryl compounds showed that inductive and resonance effects of s u b s t i t u e n t s h a v e a d i r e c t e f f e c t w i t h -I a n d +R e f f e c t s c a u s i n g shielding according t o t h e relationship below. T h e chemical shift
w a s a l s o l i n e a r l y r e l a t e d t o t h e c h a r g e o n p h o s p h o r u s a s m e a s u r e d by t h e PK. l i n e i n t h e X-ray e m i s s i o n The relationship b e t w e e n t h e PO s t r e t c h i n g f r e q u e n c y a n d p h o s p h o r u s c h e m i c a l s h i f t f o r a series of diphenvlphosphoazolides and diphenylphosphoryl ammonium cations has also been ~ t u d i e d . ~ ' Equilibria involving ring o p e n i n g o f c y c l i c p h o s p h o n a t e s ( 1 9 ) t o g i v e t h e a c i d s (20) h a s t h r o w n s o m e d o u b t o n t h e e x i s t e n c e 0.f t h e t a u t o m e r s (21).42 T h e anomeric contribution to the conformational preferences o f the diphenylphosphinoyl group in cyclohexane compounds h a s been e s t i m a t e d t o b e 3 kcal m o 1 - 1 . 4 3 A t h e o r e t i c a l NO s t u d y o f p h o s p h o n i u m s a l t s s h o w e d t h a t t h e paramagnetic component of the magnetic screening constant is dependent on the electronegativity of the phosphorus substituents. The multiplicity of the phosphorus bonds and the resonance integrals of the u components was also disc~ssed.~' Whereas ylides generally give signals upfield of the corresponding salts, the phosphonate a n i o n s , eg (22) w h i c h h a s 6 p 40, r e s o n a t e d o w n f i e l d o f t h e b i s ( d i e t h o x y p . h o s p h o n y l ) m e t h a n e w h i c h h a s SP 1 9 . 4 5 It is p o s s i b l e t h a t f o r these molecules, a larger inbalance o f substituent e l e c t r o n e g a t i v i t i e s is c a u s i n g a n e n h a n c e m e n t o f t h e p a r a m a g n e t i c contribution.
9:Physical Methods
399
Isotope effects on phosphorus n.m.r. signals a r e proving invaluable f o r the study of mechanisms, stereochemistry and assignments. A deuteriomethyl isotope effect of 0.25 was utilised for the study o f a reverse Menschutkin reaction.4b Oxygen-18 isotopic shifts have been used to study the mechanism of phosphinate esterification,” the formation of ~ ~ r o p h o s ~ h aand t e ~the ~ stereochemistry of some phosphoranilidate r e a c t i o n s a 4 ? Substitution of sulphur-34 and suphur-36 in phosphorothioate ( 2 3 ) induced upfield shifts which were used to show that the P-S bond order is about o n e s 5 ’ Oxygen isotope shifts have also been used in the study o f adenosine phosphates and the configurational analysis of nucleosides and nucleotides.” 6~ of n5 and nb compounds. - T h e products o f the reaction of a phosphoranide with aryl azides ( 6 p = -91.5) have been assigned the novel five coordinate structure (24).52 The structure can also be represented a s the amide (25) with a neutral phosphorus atom. T h e large temperature dependence o f the shifts of the bicyclic a m i n o t e t r a o x y p h o s p h o r a n e ( 2 6 ) has been attributed to a n equilibrium with a n* s ~ e c i e s . ’ ~ Similar equilibria, involving chlorotropy, have been proposed for some chlorophosphorates.54 T h e oxygen-18 isotopic shift in oxyphosphoranes is greater for the radial oxygen than for the longer apical bond. This was used to follow the An permutational isomerism by variable temperature 3 t P n.m.r.’5 interesting correlation between the chemical shifts of a wide range o f related phosphonium cations, n5 phosphoranes and nb anions has been reported and may be of use to predict the chemical shifts of new compounds.’b 2.2.2
Carbon-13. T h e molecular structure o f phosphinothioformamides (27) and their chalcogenides have been studied in the solid and liquid states.” The I 3 C n.m.r. spectra of solid methylphenyl phosphonium salts have been studied using high power decoupling cross-polarisation and slow magic angle rotation. Dipolar coupling and shielding anisotropy cause unequal intensity of spinning side bands. The scalar coupling enabled magic angle rotation to distinguish two sets o f sub-spectra.58 2.3 Shift Reagents and Liquid Crystals. - T h e chiral shift reagent ( 2 8 ) allows the enantiomeric excess of phosphine oxides to be measured. F o r example the methyl signal of ethylmethylphenylphosphine oxide in the presence of one equivalent of reagent gives
OrganophosphorusChemistry
C(TmsI2
+/ R-
pK Y
/c-Tms
Me
Me
OH
I cooTp*CH/
CO,R
(EtO)
//O
P
'CH ( EtO l2 P
Ph
(20)
(19)
(18)
/
(21)
(22)
CI
CI
I
123)
q-, N/R -Me
0-P-0
cN3=N-Ar CI
CI (25)
(26) Y
I
S
NO2
(27)
(28
OTms
9: Physical Methods t w o doublets separated by 5.5 H z . ~ S~ e e also S e c t i o n T h e use of Europium shift reagent in combination with t o study chelation to phospholipids.60 N.m.r. s t u d i e s of liquid crystal media showed that sulphonate counter ions induced abrupt changes in the coupling of methylphosphonate."
401 2.4 below.
EDTA w a s used phenyl dipolar
2.4 Valence I s o m e r i s m , Restricted Rotation and Permutational Isomerism. - T h e variable temperature spectra of bicyclic tetraphosphines ( 2 9 ) has been analysed in terms of valence isomerism involving the corresponding tuo coordinate open-chain isomers.b2 A report on a b initio NO calculations of the inversion barriers for a series of methyl phosphines includes a discussion of the electronic consequences of steric e f f e c t s e h 3 Inversion barriers of 1,2diphosphinobenzenes are in the range 100 - 110 k J mo1-'.b4 T h e ring inversion barrier for a dibenzophosphorin h a s a l s o been measured.b' Restricted rotation in a series of ditert-butylphosphines (30; R = H, A l k , P h etc) has been studied using molecular mechanics calculations." Rotation about the P-N bond in phosphonyl acetamides has a barrier of dG' 16.3 hcal mol-' 3 1 P N.m.r. spectroscopy with the aid of a chiral shift r e a g e n t , s h o w e d that pseudorotation of oxyphosphoranes (31) involves a t.b.p. intermediate with a diradial five-membered ring.67 T h e t-butyloxyphosphoranes (32, R = t-Bu) had significant barriers to pseudorotation compared with the trifluoroethyl a n a l o g u e s (32, R = CH2CF3).'" S o m e tricyclic diazatrioxyphosphoranes have been shown t o have barriers of 11 - 12 kcal m o l - 1 . b 9 A study of pseudorotation in solid h e x a c h l o r o c y c l o d i p h o s p h a z a n e w a s performed by a multipulse spin-locking technique.70 Permutational isomerism o f six-coordinate t r i f l u o r o d i a m i n o p h o s p h o r a t e s and d i a m i n o t e t r a o x y p h o s p h o r a n e s have been shown to occur by a dissociation mechanism involving a n' intermediate." 2.5 Spin-Spin Couplings. -
3 1 P Relayed and double quantum filtered correlation spectroscopy has n o w been used for the assignments o f the n.m.r. s i g n a l s o f a short DNA
lH-'H
2.5.1 J(PP).
T h e characteristic very low values of the direct PP couptings for 1 , 2 - d i p h o ~ p h e t e n e s ~h~a s been attributed t o compensating effects of ' J P P . " Inner projection o f the polarisation projector (IPPP) has been used to study through-space
402
OrganophosphorusChemistry
(proximate) and through-bond contributions t o ? J P p in ( b i s d i f l u o r o p h o s p h i n o ) a m i n e 7 ' a n d c&-1,2-diphosphinoethylene176 is concluded that overlap of t h e lone pair of electrons of both phosphorus a t o m s constitute a very efficient pathway for transmitting spin information associated with the Fermi contact term.
It
2.5.2
J(P0) a n d J(PN)). T r e n d s in ' J ( P i 7 0 ) h a v e b e e n u s e d t o s t u d y t h e protonation of phosphoryl tribromide, phosphoryl trifluoride a n d difluorophosphoric acid. Nitric acid had a greater protonation power than Hammett acidity functions This coupling has been t h e subject of a semiempirical s u m over s t a t e s theoretical S ~ U ~ Y * "
T r e n d s i n 'J(P"N) a n d 6'" for a series of triphenylphospha(h')azenes (33) w e r e u s e d w i t h 1 3 C a n d " P n.m.r. d a t a , c y c l i c v o l t a m e t r y a n d MO c a l c u l a t i o n s t o e v a l u a t e t h e n a t u r e o f t h e b o n d i n g t o ~ h o s p h o r u s . ' ~ D i p h o s p h o r y l a m i d e s (34)80 a n d a d i a z a p h o s p h o r i n dithione"' w a s a l s o s t u d i e d by "N n.m.r* spectroscopy. 2.5.3 J(PC). V a l u e s o f 'J(PC) f o r a s e r i e s o f 40 h a l o m e t h y l d i h a l o p h o s p h i n e s (35) a n d t h e i r d e r i v a t i v e s w e r e i n t h e r a n g e 17 t o 78 Ht f o r t h e n3 c o m p o u n d s a n d 97 t o 1 4 1 Hz f o r t h e n' c o m p o u n d s r 8 2 T h i s c o u p l i n g v a r i e d f r o m 151 t o 224 f o r a s e r i e s o f p h o s p h o r y l a t e d o x i m e s (361, b e i n g h i g h e s t f o r t h e E isomer^.'^ I t a l s o c o r r e l a t e d w e l l w i t h 6 t i 3 C > f o r a d a m a n t y l p h o s p h o r y l derivatives." T h e very l a r g e c o u p l i n g s ( 1 9 5 t o 236 H z ) f o r p h o s p h o n a t e c a r b a n i o n s h a v e b e e n studied using INDO-SCPT calculations. T h e results indicated that t h e c o u p l i n g s a r e p o s i t i v e f r o m a p o s i t i v e c o n t a c t t e r m but t h a t a n e g a t i v e o r b i t a l t e r m a l s o p l a y s a n i m p o r t a n t part."' Two-and threebond couplings continue t o play a n important role in t h e s t e r e o c h e m i c a l a s s i g n m e n t s o f c y c l i c compounds," and a l k e n y l p h o s p h o n a t e s e a 7 A '3C n.m.r. s t u d y o f t h e e l e c t r o n i c a n d s t e r i c effects in arylalkylthiophosphates included a n a n a l y s i s o f J ( P 0 C ) trends.''
2.5.4 J(PH). T h e c h a n g e s i n 'J(PH) o f h y p o p h o s p h o r o u s a c i d w h e n i t is e n g a g e d i n c h e l a t i o n , h a s b e e n studied.'* The high value for 'J(PH) f o r t h e r a d i a l h y d r o g e n o f 'n c o m p o u n d s r e l a t i v e t o t h e apical hydrogens has been used t o estimate apicophilicities. The r e s u l t s i n d i c a t e d t h e a p i c o p h i l i c i t y t r e n d R O > H > RNH.*'
9: Physical Methods
403
T h e geminal c o u p l i n g o f s o m e a z o l o o x a p h o s p h o l e n e s is r e p o r t e d t o correlate with Vicinal c o u p l i n g s h a v e b e e n u s e d in t h e c o n f o r m a t i o n a l a n a l y s i s o f a v a r i e t y o f c o m p o u n d s s u c h as d i o x a p h o s p h o r i n a n e ~ . ~p~h o s p h o r i n a n e s ( i n c o m b i n a t i o n w i t h C N D 0 / 2 calculation^),^^ a n d b r o m o p h o s p h o r i n a n e s cin c o m b i n a t i o n w i t h d i p o l e m o m e n t measurements).94 T h e v a r i o u s c o u p l i n g s f o r 1,l-vinylidened i p h o s p h o n i c a c i d a n d its s a l t s h a v e a l s o b e e n measured."
2.6 A n i s o t r o p y , M a g n e t i s a t i o n Transf,er, R e l a x a t i o n a n d C I D N P . - S i x p h o s p h o n i c a c i d s h a v e c h e m i c a l s h i f t a n i s o t r o p i e s o f 149 - 182 a n d a s y m m e t r y p a r a m e t e r s o f 0 . 1 - 0.5.96 T h e r a t e s o f c e r t a i n e x c h a n g e p r o c e s s e s a r e s u i t a b l e f o r s t u d y by t h e m a g n e t i s a t i o n t r a n s f e r technique. A DANTE pulse sequence w a s used to selectively invert a n a r r o w signal f o r t h e s t u d y o f p h o s p h o l i p i d e x c h a n g e in r e v e r 5 e m i c e l l e s c o n t a i n i n g p r a e s o d y n i u m s h i f t r e a g e n t in t h e a q u e o u s core.97 Relaxation times of aminophosphonic acid diastereomers are very similar.98 Longitudinal and transverse relaxation rates were used t o s t u d y c o m p l e x a t i o n d u r i n g t h e d e c o m p o s i t i o n o f acetylphosphate." T h e v a l u e o f TI f o r l i t h i u m a r y l p h o s p h i d e s s u p p o r t e d t h e d i m e r i c s t r u c t u r e w i t h a P--Li--P link.6k M e t h y l e n e b i s p h o s p h o n i c a c i d h a s a Tl v a l u e o f 3 . 5 5 . l o o A general m e t h o d f o r s e p a r a t i n g intra- a n d inter-molecular t e r m s o f d i p o l e r e l a x a t i o n u p o n s e l e c t i v e d e u t e r i a t i o n u t i l i z e d t h e G i e r e r W i r t z f o r m u l a , It was s h o w n that i n t h e a b s e n c e o f a PH bond t h e internal t e r m predominate5.'O1 Weak CIDNP effects were observed for the thermolysis o f the azophosphate ( 3 7 ) ' 0 2 - A variety of dichlorophosphanes h a v e n.q.r. 3 5 C l r e s o n a n c e s w h o s e a v e r a g e f o r e a c h c o m p o u n d c o r r e l a t e l i n e a r l y w i t h t h e total T a f t c o n s t a n t s . l o 3 T h e s p e c t r a o f a number of polyfluoroaryl hexach orophosphazenes have been A r1.q.r. s t u d y o f p e n t a f l u o r o p h e n y l studied.lO' t e t r a c h l o r o p h o s p h o r a n e s i n d i c a t e d that t h e o r g a n i c g r o u p p r e f e r s t h e a p i c a l p o s i t i o n o f t h e t . b + ~ . ' ~ T~ h e e f f e c t o f p r e s s u r e o n c y c l o t r i p h o s p h a z e n e s a n d c y c l o t e t r a p h o s p h a z e n e s h a s b e e n s t u d i e d by n.q.r. s ~ e c t r o s c o p y . ~ ~ ~ 2.8 N u c l e a r Q u a d r u p o l a r R e s o n a n c e
Organophosphorus Chemistry
404
XYP,
'0 O L p 'ORL g
Ph3P=N
0
0
II
0 (E t 0I2P-N "
Y2P-C=NOH
Hal2 P-CXYz
I R (36)
(35)
+oMe
(37)
(Et 0) PO*
PR2
(39)
(411
(40)
QI H
(42)
(431
9: Physical Methods 3
405
Electron Spin Resonance
Electrochemical reduction of a diphosphene gave the first three e l e c t r o n P-P a-bond a n d a n e.s.r. s p e c t r u m , ap = 43.5 G , e x h i b i t i n g v e r y d i f f e r e n t l i n e widths."' Pyramidal inversion and methyl r o t a t i o n o f t h e t-butyl r a d i c a l h a s b e e n s t u d i e d by a b i n i t i o calculation^.'^^ T h e e.s.r. s p e c t r u m o f t r i m e s i t y l p h o s p h i n e r a d i c a l c a t i o n p e r c h l o r a t e , g e n e r a t e d by e l e c t r o c h e m i c a l o x i d a t i o n w a s c l o s e t o t h o s e p r e v i o u s l y reported.'09 Electrochemical oxidation o f t e t r a a r y l d i p h o s p h i n e s g a v e r a d i c a l c a t i o n s w i t h a p = 170 - 175 G."OThe s p e c t r a o f r a d i c a l c a t i o n s o b t a i n e d by t h e g a m m a r a d i a t i o n of tertiary phosphines and trialkyl phosphites were studied with the The molecular and a i d o f s e m i e m p i r i c a l MNDO SCF calculations."' e l e c t r o n i c s t r u c t u r e s o f t h e d i m e r i c s p e c i e s M e b P 2 + . a n d Me, P 2 - * h a v e a l s o b e e n t h e s u b j e c t o f a t h e o r e t i c a l 5tudy.'" T h e e.s.r. spectrum of the diethoxy phosphoryl radical ( 3 8 ) w a s a strongly p o l a r i s e d d o u b l e t w i t h ap = 696 G . % l 3 E.s.r. s h o w e d that )(-ray irradiation o f tetraalkyldiphosphine d i p h o s p h i d e s g a v e p h o s p h o r a n y l r a d i c a l s w i t h t.b.p. s t r u c t u r e s (39)."' A structure has been assigned to rhosphinylhydrazyls (40). T h e d i m e t h y l a m i n o r a d i c a l w a s p a r t i c u l a r l y persistent."' The e.s.r. p a r a m e t e r s o f t h e e l e c t r o g e n e r a t e d p y r a z i n e r a d i c a l c a t i o n s ( 4 1 ) h a v e b e e n recorded."' The spectra of a stable furanyl p h o s p h a t e r a d i c a l adduct"' and a phenalene radical anion which involves injection o f spin density into half a n attached c y c l o p h o s p h a z e n e ring,'l8 a r e r e p o r t e d .
4
Vibrational Spectroscopy
T h e m e t h o d of e l i m i n a t i n g t h e i n f l u e n c e o f a t o m i c a b s o r p t i o n in FT infra-red s p e c t r o s c o p y h a s b e e n d e s c r i b e d u h i c h i n v o l v e s a n a t t e n u a t i o n technique."' 4 . 1 Assignments. - Electric modulation of vibrational rotational
Ringb a n d s o f p o l a r m o l e c u l e s i n c l u d e d a s t u d y o f phosphine.'20 bending (puckering) transition frequencies have been measured for T h e PO t h e p h o s p h o l e n e ( 4 2 ) f o r t h e g r o u n d a n d e x c i t e d states.I2' d e f o r m a t i o n b a n d f o r t h e s u l p h i d e (43) h a s b e e n a s s i g n e d . 1 2 2
Organophosphorus Chemistry
406
- An infra-red spectroscopic study of triphenylinteraction a s the cause phosphonium difluoride indicated a P'---Fof splitting and weakening of the HFz- band at 1208 cm-'.1z3 T h e carbonyl band o f carboxylic acids is split by the addition o f hexamethylphosphoramide. T h i s has been attributed to the formation of &-and trans-associates.'24 Hydrogen bonding between phenol and various phosphites, such as (44; Y = O E t , NEt2) have been studied.12' I n addition there have been several studies of phosphoryl compounds. Basicity scales have been plotted using V O and ~ aCo for methanol in phosphoryl and thiophosphoryl The P=O stretching frequency of phosphorylamides have been correlated with inductive effects. This included a study of n.m.r. methods of measuring basicity.'27 The phosphoryl group of 2-phosphaadamantane was found to have above normal basicity towards phenols.128 A c a r b a m o y l m e t h y l p h o s p h i n i c acid w a s studied in some detail by i.r. S P ~ C ~ ~ O S C O ~ Y . ' ~ ' 4.2 Bonding.
4.3 Stereochemistry. - There has been a far infra-red spectroscopic study o f ethylphosphine,I3" and in combination with z-ray fluorescence, further work completed on the conformational analysis of d i a l k y l p h e n y l p h o s p h i n e s . 1 3 i T h e influence o f water on the conformational equilibria of trimethyl phosphate has received attention.I3' There has been a low temperature solid state a n d matrix isolation study of methyl p h o s p h o r o d i c h l o r i d a t e , i 3 3 and a conformational study of polymorphic modifications of diphenylphosphinyl acetic acid h ~ d r a 2 i d e . l ~ ~ T w o heterocyclic systems have been investigated - the 1,3,2-dioxaphosphepene (45) and its oxide,13' 1,3,2-dioxaphosphorinanes and their oxides, sulphides and selenides (46).i369'37Three ring vibrations were involved in the conformational study of the amides (46,Y = N R 2 ) . 1 3 7
5
Electronic Spectroscopy
5.1 Absorption Spectroscopy. - T h e u + v . spectra of triarylphosphines
indicate that the phosphino group has a strong +M effect on a 4-nitrophenyl ring but that the phosphorus atom a c t s as barrier t o conjugation between aryl rings bound to phosphorus.'38 An additional band appearing in s o m e spectra is attributed to a charge
9: Physical Methods
407
t r a n s f e r e x c i t a t i o n b e t w e e n d o n o r a n d a c c e p t o r a r y l rings.'" U.V., i.r. a n d n . m + r + s p e c t r a o f t h e d i p h o s p h o n a t e s (47) h a v e b e e n r e ~ 0 r t e d . l ~ T~h e i n t e n s i t y o f t h e s e c o n d a r y b e n z e n o i d b a n d at s. 262 n m f o r t h e 1 , 3 , 2 - d i o x y p h o s p h o r i n a n e s ( 4 6 ; Y = OPh) was u s e d to a s s e s s t h e e x t e n t o f p-T c o n j u g a t i o n a n d t h u s t h e c o n f o r m a t i o n a l preference of the phenoxy groups.t36 I
5.2 F l u o r e s c e n c e . - A f u r t h e r r e p o r t o n t h e u s e o f n a p h t h a l e n e phosphorus compounds for fluorescence derivatization concerns the d e p e n d e n c e o f f l u o r e s c e n c e on t h e t y p e a n d p o s i t i o n o f s u b s t i t u e n t s o n t h e n a p h t h a l e n e rings.'" It h a s b e e n f o u n d t h a t t h e diphenylphosphinyl group enhances the fluorescence properties of b i p h e n y l s ( 4 8 ) but r e d u c e s t h e f l u o r e s c e n c e p r o p e r t i e s o f naphthalenes.t42 The fluorescence and photoisomerisation o f d i p h e n y l p h o s p h i n y l s t i l b e n e s has also been studied.*43 5.3 C i r c u l a r D i c h r o i s m . - T h e a b s o l u t e c o n f i g u r a t i o n o f t h e m - h y d r o x y p h o s p h o n a t e ( 4 9 ) w a s e s t a b l i s h e d t h r o u g h its n e g a t i v e C o t t o n e f f e c t a t 2 1 5 nm.'44
5.4 P h o t o e l e c t r o n a n d X-ray S p e c t r o s c o p y . - T h e p h o t o e l e c t r o n s p e c t r u m o f t h e n' p h o s p h a a l k e n e (50) w a s s i m i l a r t o t h a t o f t h e c o r r e s p o n d i n g i m i n e . Its f i r s t i o n i s a t i o n p o t e n t i a l was a t 9 . 6 9 e v e i 4 ' P r e d i c t i o n s o f t h e r e a c t i v e b e h a v i o r o f i m i n o p h o s p h a n e s (51) a n d t h e c o r r e s p o n d i n g m e t h y l e n e a n a l o g u e 5 c a n b e m a d e on t h e b a s i s o f t h e l i n e a r r e l a t i o n s h i p b e t w e e n t h e i r optical t r a n s i t i o n s a n d ionisation P h o t o e l e c t r o n s p e c t r o s c o p y a n d MO c a l c u l a t i o n s o f p h o s p h i r a n e s i n d i c a t e l o w s y m m e t r y a n d small e n e r g y s e p a r a t i o n b e t w e e n b a s i c orbital e n e r g i e s o f t h e P-C, P-S a n d P-N u bands o n one side and the lone pair of electrons o n phosphorus or h e t e r o a t o m o n t h e o t h e r . T h e r e is a s t r o n g m i x i n g f o r m o s t m o l e c u l a r o r b i t a l s a n d t h e r e f o r e l o c a l i s a t i o n p r o p e r t i e s o f HOMO w a v e f u n c t i o n s d e p e n d o n t h e substituents.'47 T h e p.e. s p e c t r a o f d i m e t h y l p h e n y l p h o s p h i n e i n d i c a t e s that t h e m o s t f a v o u r e d A study o f the c o n f o r m a t i o n d o e s not a l l o w P-n conjugation.'4a p h o s p h a n e (52: A r = C a F 5 , Y = O M e ) a n d o t h e r p e n t a f l u o r o p h e n y l compounds has been -X-ray f l u o r e s c e n c e s p e c t r a o f t e r t i a r y p h o s p h i n e s (52: A r = P h , Y = a l k y l ) i n d i c a t e d t h a t w h e n t h e PY2 g r o u p is in t h e best g e o m e t r y f o r p-T c o n j u g a t i o n t h e i n t e r a c t i o n is still o n l y 25% o f t h a t o f t h e dimethylamino groupbt3'
Organophosphorus Chemistry
408
(47)
Me-P=CH2 (50)
(481
RZN-P=Y
/R Z‘
Ar-PY2
(51)
(52)
Ph ‘C=PfUY Tms’
(53)
(54)
(55)
Z-N,
f7 ,N-Z
P
(59)
I
NEtZ
(60)
(61)
9: Physical Methods
6
409
Diffraction
6.1 X-ray Diffraction. - T h e crystal structures of a number o f
cyclic organophosphorus compounds have been reviewed'"' 6.1.1
n2 Compounds. T n e molecular structure o f a number of twocoordinate P = C compounds have been described. The group at B o n n have examined three methylene phosphaalkenes ( 5 3 ; Y = P h , iPrlN, tBu2P). T h e P=C bond length in the phenyl compound w a s 165 pm.'" and (13),30together with a T w o cyclic compounds ( 5 4 ) ' " phosphaallyl cation (55),'53 complete t h i s group. T h e structure of two P=P compounds have been determined. O n e w a s the diphosphaalkene ( I ; X = Y = CTmsJ)ti'4 the other w a s the diphosphoniaphosphide (56) "
.*
6.1.2
n3 Compounds. T h e phosphorus a t o m in the bicyclic tertiary phosphine ( 5 7 ) has been shown t o have a pronounced pyramidal arrangement,lS6 similar to the diphosphinine ( 5 8 ) . 1 ' 7 The the structures of the ten-membered cyclic 1,2-diphosphine ( 5 9 1 , ' ' ' and a lithio dibenzotriphosphole,l6' have been mono-oxide ( 6 0 ) , " ' determined. Reports on a dichlorophosphane derivative of a b i p h e n y l , l b l a benzotriphosphazane (61, Z = PS(NEt2 ) z ) , ' " 1 , 3 , 2 - d i a z a p h o s ~ h i n a n e , ~and ~ ~ a d i a z a d i ~ h o s p h e t i d i n e ' ~have ~ also appeared., T h e first trimethylenephosphate (62) has a planar PC3 group with three very similar C P C bond ang1es.16' S t u d i e s o f the charge distribution will be interesting.
6.1.3 n4 Compounds. A number a quaternary phosphonium salts have been studied. They include a diethylphospholanium iodide,lb6 a diphenylphosphorinanium bromide,I6' a 1,4-diphosphac y c l ~ h e x a d i e n e , ' ~a ~ 2,2-diphosphonia ethyl ether,'69 1 - ( t r i p h e n y 1 p h o s p h o n i a ) e t h y l a m m o n i u m bromide,"' a s well a s methyl The a n d i o d o m e t h y l t r i p h e n y l p h o s p h o n i u m trinitromethanide.17' molecular structures o f the stabilised ylide (63)172a n d the s p i r o ylide (64)'73 have a l s o been determined. S t u d i e s o f nk c o m p o u n d s possessing three P-C bonds a r e presented below. I n a d d i t i o n to a diazaphosphole oxide,"' the internal molecular motions of triphenylphosphine oxide h a v e been analysed,l7' and the anomeric interaction o f a d i p h e n y l P h o s p h i n o y l - l , 3 - d i t h i a n e T h e structures o f t w o sulphides h a v e been e x a m i n e d ,
Organophosphorus Chemistry
410
a n ethylene 1 , l - b i s ( d i p h e n y 1 p h o s p h i n e s u l ~ h i d e ) ' ~and ~ the phosphorinanone (65).178 Other compounds in this group which have been studied include a m i n o t r i p h e n y l p h o s p h o n i u m chloride,"' two triphenylphosphazenes,"' a bis(triphenylphosphonia)imide,'al the bis salt (66),la2 and a germyl phosphonium ylide."' A variety o f compounds have been examined which a r e in the phosphinic acid class. They include a phenyl cyclopentyl ester,Ia4 a phosphinothioic anhydride,I8' a d i p h e n y l p h o s p h i n a m i d e , I a 6 a red b i s ( d i - t - b u t y l t h i o p h o s p h i n a m i d e ) and its selenide analogue,"' the anisylphosphorinane (67),Iaathe thioamide (68),18' and the phospholenium amide (69, Y = i-Pr2N).*'O Phosphonic acid derivatives a r e also well represented. Phosphonic acid analogues of aspartic a c i d , glutamicacid C-benzy1g1ycine,191 and the phosphorinane (70)'92 have been studied, a l s o the oxime (71)19' a phosphonopiperidinol - with a very distorted chair structure,Iq4 the phosphonate (72),19' a pyrazole,Lq6 a t h i o c a r b a m o y l p h o s p h o n a t e , 1 q 7 and two iminobis(methylphosphonic acids).'" Additionally there have been studies o f the new bicyclic sulphur heterocycle (73),199 the oxazaphospholidine (74)200and a triaminophosphetanium aluminium betainea2' X-ray crystallographic studies of phosphoric compounds abound. Some concern phosphates such a s naphthyl and quinolyl phosphates,202 a n d alkylammonium phosphate betaine,*" a 1,3,2-dioxaphosphorinane resolving agent (75),204a glycosyl phosphatet2" and a fructofuranose 1 , 6 - d i p h o s ~ h a t e . ~ ~Three ~ thiophosphates have been examined, one containing a germyl group,zo7 another a chelated arsenic group,2oa the other a dithiaphosphepin, which has a pseudo chair conformation+z0' Many amides have also been investigated. They include a guanidine derivative of 1 , 3 , 2 - d i o ~ a p h o s p h o l e n e , ~ ~ ~ three sulphoximides (76),2'' a 2 - a m i n o - l , 3 , 2 , - d i o x a ~ h o s p h o r i n a n e ~ ' ~ a related sydnonimine,2'3 the fluoride (77),2'4 a ribitol thiophosphorylamide,21' and two 2 , 1 , 3 - b e n z o p h o s ~ h a d i a z i n e s . ~ ~ ~ There have been several studies o f cyclophosphazenes and closely related compounds. T h e first cyclodiphosphazene to be reported h a s all four P-N bonds equal in length,217 other studies include three cyclo- triphosphazenes,2'a - one o f which contains a cyclotetrasiloxane three large ring phosphazenes (NPMe2 2220 and two unusual spirocycl e s (PhPNI4 S3N4 and (Ph2PN)eSNz T h e structure o f the t r i s - m o r p h o l i n o p h o s p h i n i m i n e (78) has a l s o been d e t e r m i n e d r Z Z 2 e Z 2 '
9: Physical Methods
41 1
SePh
Li+
Ph,P =C
/ \
COPh C0,Me
(64)
(63)
(62)
Ph P + 3 \
PH
/
Ph3P+
Tms
Me
Me
M
/
(67)
(66)
(65)
(/ O N Lj pP o0 i3 H 2
P+
H
y2
(70)
(69)
(68)
Ph --‘C -C H=NOH
I
OMe
(72)
(71) RNH
0
0
\//
P-N
(73)
II
/R
MeSN-
0, ’0
(74)
po,
P(OR I2
II
0
‘OH
(75)
(76)
Organophosphorus Chemistry
412
n' Compounds. T h e number of five co-ordinate structures that have been reported over the past year has diminished even further. A trigonal bipyramidal structure was found for the bicyclic trioxamidophosphorane ( 7 9 ) . 2 2 3 6.1.4
6 . 2 Electron Diffraction. - Three gas-phase molecular structures
have been determined by electron diffraction. They a r e the hypophosphite (80)224trifluorophosphine sulphide,225 and dichlorotrifluorophosphorane.22*
7 Dipole Moments, Herr Effects, Polarosraphv and Conductance
7.1 Dipole Moments and Kerr Effect. - T h e structures of two conformers of ethyldifluorophosphane have been determined using a combination of dipole moments and microwave spectroscopy.227 Dipole moments have been used to study the different twist angles of allenic phosphonates (81),22'and also to deduce the stereochemistry of 1 , 3 , 2 , 5 - d i o x a b o r a p h o s ~ h o r i n a n e ~ ~ ~ ~ Combined dipole moment and Herr effect studies a r e regularly used by Russian workers for the conformational analysis of phosphorus heterocyclesr'35*230 In a study of the interaction o f phenol with phosphoryl groups the Kerr effect was used to evaluate not only the extent of hydrogen bonding but also the influence o f changes in polarity and polarisation upon stability constants.*" I n a similar study the orientation of the aryl groups of 1,3,5-triazaphosphorines (82) were shown to be less coplanar than biphenyl in the gas phase.'32 7 . 2 Polarosraphy and Conductance. - A polarographic study of
trialkyl phosphites, thiophosphites, and related compounds showed that only the P-S bond is reductively cleaved at a dropping mercury electrode to give alkyl sulphide and ~ h o s p h i d e . ~Conductometric ~~ titrations of trialkylphosphines with bromine, iodine and iodine bromide showed the formation o f highly conducting 1:2, 1 : l and 2:l adducts. T h e latter two were isolated.234 Redox reactions o f b i s ( m e t h y 1 e n e ) p h o s p h o r a n e s ( 1 8 ) are irreversible and cyclicvoltametry oxidation peaks a r e independent o f s u b ~ t i t u t i o n . ~ '
413
9:Physical Methods
8
Mass Spectroscopy
T h e doubly charged mass spectra of eleven organophosphorus compounds w e r e o b t a i n e d u s i n g m e t h a n e as a t a r g e t gas. MO c a l c u l a t i o n s w e r e used t o e s t i m a t e s t r u c t u r a l p a r a m e t e r s a n d e n e r g i e s o f p r o m i n e n t i o n s s u c h as ( 8 3 ) . A p p e a r a n c e e n e r g i e s r a n g e d f r o m 23 t o 38 eV.23' There has been a mass spectrographic study o f trifluoromethyl( d i f l u o r o m e t h y 1 e n e ) ~ h o s p h i n e ~ ~a'n d a c o m p a r a t i v e s t u d y o f t r i m e t h y l phosphite and dimethyl methylphosphonate. T h e molecular ion of the l a t t e r w a s s h o w n t o u n d e r g o i s o m e r i s a t i o n t o t h e r a d i c a l c a t i o n (84) prior to dissociatione2" D i e t h y l t h i o p h o s p h i n i c e s t e r s (85) a n d ( 8 6 ) c a n be d i s t i n g u i s h e d by m a s s s p e c t r o m e t r y , t h e l a t t e r g i v i n g m o r e a b u n d a n t m o l e c u l a r i o n s a n d a l o w a b u n d a n c e o f t h e i o n (87). T h e p o t a s s i u m salts o f t h e p y r o p h o s p h o n i c a c i d s g a v e FAB s p e c t r a f r e e f r o m m a t r i x interferance.238 Chemical ionisation induced c o m p e t i n g a n d c o n s e c u t i v e h e t e r u l y t i c r i n g c l e a v a g e in t h e m a s s s p e c t r a o f t h e o x i d e s (88).239T h e b a s e p e a k s o f i m p h o s a n d c y c l o p h a n e w e r e q u i t e d i f f e r e n t a n d b a s e p e a k s a p p e a r e d at m/z 131 a n d 21 r e s p e c t i v e l y . 2 4 0 T h e m a s s s p e c t r a of p h e n y l p h o s p h o n a t e s a n d p h o s p h a t e s s u c h as (89) h a v e b e e n reviewed.24'
9
Acidities. Basicities and Thermochemistry
T h e r e h a s b e e n a MO s t u d y o f t h e s t e r e o e l e c t r o n i c e f f e c t s in m e t h y l p h o s p h i n e s ( 9 0 ) . S t e r i c e f f e c t s w e r e f o u n d t o c o n c e n t r a t e in t h e HOMO a n d a c c o u n t e d f o r h a l f t h e s u b s t i t u e n t e f f e c t s o n t h e pK, v a l u e s , w h i l s t e l e c t r o n i c e f f e c t s o n t h e HOMO w a s The relative basicities o f p o l y m e t h o x y t r i a r y l p h o s p h i n e s have been i n e considerably m e a s u r e d . T r i s ( 2 , 4 , 6 - t r i m e t h o x ~ ~ h e n ~ l ) ~ h o s ~ hwas m o r e b a s i c t h a n p i p e r i d i n e . 2 4 3 T h e b a s i c i t i e s o f P-N c o m p o u n d s h a v e b e e n r e v i e w e d a n d t h e i r c o r r e l a t i o n w i t h P-N b o n d l e n g t h s in~estigated.'~~ A method for determining the basicities of phosphoryl compounds h a s b e e n d e c r i b e d w h i c h is b a s e d o n " P n.m.r. c h e m i c a l s h i f t measurement and a two phase system consisting of a n organic solvent T h e gas-phase protonation of aliphatic a n d 12M s u l p h u r i c acid."' p h o s p h i n e o x i d e s h a v e b e e n d e t e r m i n e d by c y c l o t r o n r e s o n a n c e . T h e r e was a g o o d c o r r e l a t i o n o f pK. w i t h K a b a c h n i k c o n s t a n t s a n d MO
OrganophosphorusChemistry
414
( TmsO),
PH
But N=C=CH
*r(ril*r
L
'P(OR1,
N$p"
0
0
(82)
(81)
(80)
OH I 12+ POCH, 6~~P+ (OM ( 8 3)
R2
0
II
0
EtzP-SR
?I
Et 2P-OR (86)
( 85)
(84) R
I
Et2PHS+
(87)
(88)
(89)
9: Physical Methods
415
c a l c u l a t i o n s i n d i c a t e d that f o r a m i d a t e s o x y g e n p r o t o n a t i o n is f a v o u r e d o v e r n i t r o g e n p r o t o n a t i o n by a b o u t 100 k c a l . m o l - ’ . 2 4 6 The pK, v a l u e s o f d i m e t h y l t h i o p h o s p h i n a t e s h a v e b e e n d e t e r m i n e d . 2 4 7 Protonation of a t e t r a a m i n o m e t h y l e n e p h o s p h o n i c acid was studied u s i n g p ~ t e n t i o r n e t r y . ~ ~ ’T h e a c i d i t y o f t h e P-H b o n d o f d i e t h y l . 2 4 9 The carbon p h o s p h o n a t e c o r r e s p o n d e d t o a PK, o f 2.5 a c i d i t i e s of m e t h y l e n e g r o u p s a c t i v a t e d by p h o s p h o r y l g r o u p s a n d phosphonium groups have been studied. Modified o c - constants have The b e e n d e r i v e d f r o m t h e u q c o r r e l a t i o n o f PK, v a l u e s e 2 ” acidifying effect o f phosphonium groups and the enhancement caused by m i c e l l a t i o n h a s b e e n i n v e s t i g a t e d . 2 5 1 I t h a s b e e n s h o w n that t h e h y d r o x y p h o s p h o r a n e ( 9 1 ) h a s a pK. o f 9 - 10 a n d is in r a p i d e q u i l i b r i u m w i t h its c o n j u g a t e a n i o n a n d t h e ring opened alcohol . 2 3 2 The heats o f ionisation and neutralisation of amino and hydroxylic bis and tris phosphonic a c i d s have been investigated.253 C a l o r i m e t r y in c o m b i n a t i o n w i t h U.V. a n d n.m.r+ s p e c t r o s c o p y w a s used to study the adducts of fluoroalkyl carboxylic acids with diethyl phosphonate.25‘ The heats of formation of the t - b u t o x y t r i p h e n y l p h o s p h o r a n y l radical was consistent with the p h o s p h o n i u m s t r u c t u r e (92).2’5 T h e r e h a s b e e n a thermal a n a l y s i s o f t h e adducts of phosphonic and phosphoric acids with semicarbazide,256 and the heats o f solution and heats o f reaction in t h e methylation o f triphenylphosphine have been studied with regard t o ’ solvent effects, transfer thermodynamic quantities and various extended Bronsted treatments.257
10
Chromatography
10.1 Gas L i q u i d C h r o m a t o g r a p h y . - T h e t h e r m o d y n a m i c s o f t h e m o l e c u l a r a s s o c i a t i o n o f tri-n-octylphosphine o x i d e a n d h a l o a l k a n e s h a v e b e e n s t u d i e d e 2 ’ * T h e r e h a s b e e n a g.1.c. a n a l y t i c a l s t u d y o f t h e d e g r a d a t i o n p r o d u c t s o f tri-n-butyl phosphate,2’9 t h e p y r o l y s i s products of quaternary phosphonium salts,260 and bifunctional amines after derivatisation with methyldichlorophosphane and sulphur.261 Cyclophosphamide a n d related compounds have been the subject o f several studies262 including g.c.mrsb263 Plant extracts containing ethyl p h o s p h o n a t e a n d p h o s p h a t e s h a v e b e e n a n a l y s e d by g.1.c. a n d h.p.1 .c.264
Organoph osphoms Chemistry
416
10.2 Thin Layer Chromatography. - The technique has been applied to the determination o f tricresvl phosphate in edible oils,263 and insecticides in tobacco leaves.266
10.3 Liquid Chromatography. - Diasteriomeric phosphonodipeptides have been separated by ion exchange column chromatography.267 H.p.1.c. has been used for the analysis of a variety of biologically active phosphorus compounds1 such as aminoacid phosphate esters,2b8 phosphinothrycinlZ6’ inositol t r i p h o s ~ h a t e , ~ ”fructose diphosphate,27’ pyridoxal and A T P . 2 7 J
11
Kinetics
T h e kinetics of deuterium isotope exchange between diphenylphosphine and t-butylthiol have been studied by ‘ H n*m.r. ~ p e c t r o s c o p y . ~A~ ~ negative temperature coefficient w a s observed for the reaction o f a perfluoroalkyl phosphite with a fluorinated aldehyde.27’ The kinetics for the reaction of alcohols with phosphoryl trichloride bore strong similarities t o those of carboxylic acid derivatives.276 An interesting report desribed the solvolysis of arylhydroxymethylphosphonates. It was shown that a phosphoryl group does not prevent carbocation formation on a n immediately adjacent carbon atom.277 There have been a number of hydrolysis studies. T h e mechanism o f alkaline hydrolysis of phenyl dimethylthiophosphinate has been compared to that of phenyl acetate.278 Evidence for the formation o f five coordinate oxyphosphorane intermediates in the alkaline hydrolysis of aryl d i p h e n y l t h i o p h o s p h i n a t e s is based on the lack o f development o f negative charge on the leaving group in the transition
9: Physical Methods
417
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221. 222.
T.
-
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231. 232.
570 U . U.
P r e z h d o , Khim. Fiz.1 19851 0, 651. S. S. B u l g a r e v i c h , N. A. I v a n o v a l P. P. K o r n u t a l N. U. K o l o t r l o , T . A.
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L a t y p o v a , B. U . M e l ’ n i k o v , G. U Z a m a l e t d i n o v a , E. S. B a t y e v a , a n d A. N. P u d o v i k , Zh. Obshch. Khim.3 1985, 5 5 3 10001 G. S. H a r i s and J . S. McKechnie, P o l y h e d r o n , 1985, 4, 115. J. R. A p p l i n g , G. W . B u r d i c k y a n d T . F. Morant Org. Mass. Specrom.1 1985,
z,
343. 236. 237 f
M. B i n n e v i e s ~ J. Grobepand D. L e Wan, P h o s p h o r u s S u l f u r , 1985, 2 , 349. J . R. H o l t z c l a w , J . R. W y a t t r a n d J . E. Campana, Org. Mass Specrom., 1985,
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D. W. H u t c h i n s o n and G. Semple, Org. Mass Spectrom.! 1985, 0, 143. P. S , K u l k a r n i , U. N. Gogte, A. S. Modak, S. 0. S a h a s r a b u d h e + a n d B. D. T i l a k , Org. Mass SDectrorn.3 1985, 454. U . U . M i k a i l o v , U. N. U o l k o v , E. A . A r i p o v r a n d G. R. N a r m e t o v a ~ Chem. A b s t r . , 1985, 103, 141262. P. A. Manninen, Ann. Acad. S c i . Fenn., S e r . A 2 3 1985, 203, 203. E. Magnusson, A u s t . J. Chem., 1985, 38, 23. M. Wada, S. H l g a s h i z a k i t a n d A. T s u b o i , J . Chem. Res., SynoD.1 1985, 38. J. G. R i e s s , P h o s p h o r u s S u l f u r , 1986, 27, 93. U. U. Y a s h k i n , N. M. M e s h c h e r y a k o v ~ M. E. I g n a t o v r B. I.L a s k o r i n , U . G. Yagodin,and E. G. I l ’ i n r Zh. Obshch. Khim.9 1985, 551 1421. J. C . B o l l i n g e r r R. H o u r l e t , C . W. K e r n , D. F e r r e t , J . Weberrand T. Yvernault, J . Am. Chem. S O C . ~ 1985, 107, 5352. R. D. Cook a n d M. M e t n i l Can. J. Chern., 19851 63, 3155. R. Kh. Samakaev, Pi. N. D y a t l o v a , A. M. Evseev, L . S. N i k l o a e v a s a n d T . A . M a t k o v s k a y a , Zh. f i n a l . Khim., 1985, 40, 429. E. S. L e v i s and L. G . Spears, J . Am. Chem. Soc.1 19851 107, 3918, M. I. K a b a c h n i k a n d T. 4 . M a s t r y u k o v a r Zh. Obshch. Khrm.1 1984, 3,2161.
Organophosphorus Chemistry
424
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108, 2416.
Chem., 1986, 1352. H. McGallr J. Am. Chem. Soc.,
1986,
254.
A. V. Barsukov, N. A. K a s l i n a , B. U . Zhadanov, T. H. Malkovskaya, I. A. Polyakova, G. F. Yaroshenko, N. ti. Dyatlova,and A. V. Kessenikht Zh. Obshch. Khim., 1985, 21803: V . P. V a s i l ’ e v , L. A. Kochergina,and T. D. O r l o v a , Zh. Obshch. K h i m . ~ 1985, 551 809; V. P. V a s i l ’ e v , L. A. Kochergina, T. D. Orlova,and M. V. Rudomino~ Zh. Obshch. Khim.1 1984, 3, 2437. V. I. K r u t i k o v ~S. F. A l e i n i k o v s a n d A. N. L a v r e n t ’ e v , Zh. Obshch. Khim.,
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N. N. Nurakhmetov, B. A. Beremzhanovr A. Tashenov,and R. Sh. Erkasov, 1460. Zh. Obshch. K h i m . ~ 1985, Y. K o n d o ~ A. t a n k a - a n d S. Kusabayashi, J. Chem. Soc.1 P e r k i n Trans., 1985,
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R. Cesar C a s t e l l s and A. Miguel N a r d i l l o , J. S o l u t i o n Chem., 1985, &lr 87. M. Acost F l o r e s and M. C a s s i r Chury, Rev. SOC. Quim. Mex.1 1984, 281 123. S. J. Abraham and W. J . C r i d d l e , J. Anal. A p p l . P y r o l y s i s . , 19851 1, 337. K. Jacob, G. Schnablrand W. Uogt, Chromatographiat 1984, 19, 216. E. A. De B r u i j n , P. A. L e c l e r c q ~ a n dU. R. Tjaden] HRC C C , J. Hiqh R e s o l u t . Chromatosr. Chromatos. Commun.~ 1986, 9 , 89: E. A. De B r u i j n ~P. A. L e c l e r c q and U. R. Tjaden, e r o c . I n t . Symp. C a p i l l a r y Chromatogr.1 6 t h ~19851 599: A. E l - Y a z i g i and C. R. M a r t i n , J. Chromatogr., 19869 374, 177. E. A. A r i p o v , V. U. M i k a i l o v , a n d G. R. Marmetova, Uzb. Khim. Zh., 19851 11. P. Saindrenan, G. D a r a k i s r a n d G. Bompeix, J. Chromatoqr.1 1985, 347, 267. M. N. Krishnamurthyl S. R a j a l a k ~ h m i ~ a n0.d P. Kapur, J. Assoc. O f f . h a l . Chem., 1985, 68, 1074. T. H. P e t r o v a and 0. K . Ostroukhova, Tabak (MOSCOW)I 19861 14. B. L e j c z a k ~P. K a f a r s k i , a n d P. M a s t a l e r z , J. Chromatogr., 1985, 324, 455. I). W. McCourt, J . F. Leykamsand B. D. Schwartzr J. Chromato9r.1 1985, 323,
9. ti. P. F i e d l e r ~A. Plagaland R. Schuster, J. Chromatosr., 1986, 353, 201. J. L. Neek and F. N i c o l e t t i r J. Chromatogr., 1986, 3511 303. K. Kogohr Osaka Daigaku I s a k u Zasshi, 1984, 3, 211. J. B. Ubbinkr W. J. Serfontein,and L. S. De U i l l i e r s , J. Chromatogr., 1986, 375, 399. J. M. Ryder, J. A s r i c . Food Chem.1 1985, 33, 678. A. Wawer and I.Wawer, React. K i n e t . C a t a l . L e t t . , 19841 3 ,167. S. F. A l e i n i k o v , V. 1. K r u t i k o v , I. N. Rogozina,and A. N. L a v r e n t ’ e v , Zh. Obshch. Khirn.3 1985, 55, 576. N. N. Lebedev, B. V. Mamurintand V. P, Savel’yanov, Zh. Obshch. Khirn.1 198S1 55, 550, 543, 546. X. Creary and T. L. U n d e r i n e r t J. Ors. Chem.1 1985, 2165.
-
U. A.
B a r a n s k i i , G.
D. E l i s e e v a , E. L. Zhdankovich,and M. G.
I z v . Akad. Nauk SSSR, Ser. Khim., 279.
R. D. Cook and L. Rahhal-Arabis
Voronkov,
1984, 2476. Tetrahedron L e t t . ,
19851 3,3147.
Author Index I n t h i s i n d e x t h e number g i v e n i n p a r e n t h e s i s i s t h e C h a p t e r number of t h e c i t a t i o n and t h i s is f o l l o w e d by t h e r e f e r e n c e number o r numbers of t h e r e l e v a n t c i t a t i o n s within t h a t Chapter
Aaron, H.S. ( 4 ) 30 Aba-Ella, E.M. ( 8 ) 35 A b d e l - G a l i l , F. ( 1 ) 1 9 3 , 240 Abdel-Halim, F.M. ( 1 ) 220, 221 Abdou, W.M. ( 2 ) 3 5 ; ( 9 )
68 Abdul-Masih, M.T. ( 6 ) 216 Abdulwajid, A.W. ( 6 ) 6 8 Abed, O.H. (1) 2 2 2 ; ( 7 ) 24 A b e l l , K.W.Y. ( 5 ) 31 A b e l s o n , J . ( 6 ) 280, 341 A b i c h t , H.-P. (1) 2 9 , 46 Abiyuov, B.D. ( 9 ) 194 Aboujaoude, E.E. ( 5 ) 55, 5 9 ; ( 7 ) 75: 97 A b o u l - e l a , F. ( 6 ) 147 Abraham, S . J . ( 1 ) 2 3 0 , 2 3 1 ; ( 9 ) 260 Abramov, I . A . ( 1 ) 1 4 1 , 142 Abramova, T.V. ( 6 ) 283 Abu-Orabi, S. ( 1 ) 384 Acevedo, O.L. ( 6 ) 189 Acheson, R.M. ( 5 ) 3 9 ; ( 9 ) 216 Acost F l o r e s , M. ( 9 ) 259 Adam, S. ( 6 ) 381 Adamiak, R.W. ( 6 ) 2 7 3 , 380 Adams, J. ( 7 ) 120 Ades, C. ( 1 ) 266 A d r i a n , F.J. ( 9 ) 113 Aganov, A.V. ( 9 ) 9 2 , 1 3 6 Agarwal, K. ( 6 ) 1 7 3 Agashkin, O.V. ( 9 ) 1 7 8 Agawa, T. ( 5 ) 5 0 ; ( 7 ) 8 4 Agbossou, S. ( 2 ) 57 Agrawal, S. ( 6 ) 115 A g u i l a r , M.A. ( 3 ) 13
A h l e r s , H. (3) 25 Ahmad, M.M. (1) 213; ( 9 ) 181 Ahn, K.D. ( 8 ) 1 1 3 Ahrichs, R. (8) 3 Aitken, R.A. ( 7 ) 62 Akasaka, T . ( 7 ) 5 9 ; ( 8 ) 4 1 , 42 A k e l a h , A . ( 1 ) 1 9 3 , 240 A k h l e b i n i n , A . K . ( 9 ) 213 Akhmedzade, D.A. ( 1 ) 161, 162; ( 4 ) 56, 57, 59, 6 0 Akhmetkhanova, F.M. ( 2 ) 43 Akpan, C.A. (1) 313 Aksenova, T.B. ( 4 ) 6 8 Akutagawa, S . (1) 54 A l a r i o , F. ( 1 ) 114 A l b e r n e s e , J.A. ( 9 ) 39 A l b e r t , K . ( 9 ) 57 Albrecht, S. ( 4 ) 31; ( 8 ) 149 A l c o c k , N.W. ( 1 ) 367 A l d e r , L. ( 9 ) 1 4 3 Alderfer, J.L. (6) 191, 260, 377 Aldwegg, M. ( 6 ) 308 A l e i n i k o v , S.F. ( 9 ) 254; ( 9 ) 275 A l e k s a n d r o v a , N . A . ( 4 ) 37 Alemagna, A. ( 7 ) 5 3 , 5 4 Alewood, P.F. ( 5 ) 1 2 A l e x a n d e r , C.A. ( 1 ) 4 8 A l ' f o n s o v , V.A. ( 4 ) 4 9 , 50; ( 9 ) 233 A l i , A.A.M. (9) 9 A l i , R. (1) 187 A l i g , B. (1) 128 Allcock, H.R. (1) 118; ( 8 ) 8, 7 4 , 109-111, 155, 156, 158, 159; (9) 218
425
A l l e g r a , G . (8) 1 6 3 A l l e n , C.W. ( 8 ) 1 1 2 , 1 2 1 A l l e n , L. ( 6 ) 348 A l l s p a c h , T. ( 1 ) 3 2 1 , 3 2 2 ; ( 9 ) 24 A l o n i , Y. ( 6 ) 1 6 3 Alparova, M.V. ( 8 ) 127, 128; ( 9 ) 134 Al-Rawi, J . M . A . ( 2 ) 5 6 ; (9) 86 A l r i c h s , R . ( 9 ) 13 A l t , H.G. ( 1 ) 8 Altenbach, H.-J. ( 7 ) 89 A l t e r m a t t , R. ( 6 ) 139 Altman, S. ( 6 ) 3 4 7 , 348 Alvarado-Urbina, G. ( 6 ) 154 A l y e a , E.C. (1) 11 Amann, P. ( 1 ) 26 Ambrose, B . J . B . ( 6 ) 298 Aminova, R.M. ( 9 ) 9 3 Amrani, Y. (1) 114 Anders, E. ( 7 ) 4 6 Anderson, D . J . ( 6 ) 1 4 3 Anderson, N.L. (1) 9 5 Anderson, P.M. ( 6 ) 81 Anderson, T.P. (5) 1 4 0 , 142 Ando, T. (5) 1 2 3 Ando, W. ( 7 ) 5 9 ; ( 8 ) 4 1 , 42 Andra, K. (1) 160; ( 4 ) 55 Andrew, S.S. (5) 1 3 7 Andriamizaka, J . D . ( 1 ) 352 A n d r i a n a r i s o n , M. ( 9 ) 154 Ang, H.G. (1) 9 , 1 3 9 , 140 A n g e l e t t i , E. ( 1 ) 242 Angelov, Kh.M. (5) 1 2 7 ; (9) 87 A n g e r e r , W. (1) 1 7 2
Organophosphorus Chemistry
426 Antberg, M. ( 1 ) 50 Antczak, K. ( 5 ) 101 Anthony, D.D., ( 6 ) 229 Antipin, M.Yu. ( 1 ) 331; ( 4 ) 102; ( 8 ) 24, 54, 190; ( 9 ) 150, 159, 166, 201, 203, 212 Anzai, M. ( 8 ) 9 5 , 96 Apal'kova, G.M. ( 1 ) 146; ( 9 ) 161 Appel, R . ( 1 ) 271, 273, 282, 294, 299, 306-309, 312, 314-317; ( 4 ) 105; ( 7 ) 6 ; ( 9 ) 33, 37, 62, 151, 158, 165 Appelt, A. ( 1 ) 43-45 Appling, J . R . ( 9 ) 235 Arai, M. ( 6 ) 40 Arbuzov,'B.A. ( 1 ) 245, 380-382; ( 2 ) 47; ( 4 ) 2; ( 9 ) 9 2 , 9 4 , 135, 136, 174, 215, 229, 230 Arcus, R.A. (8) 8 Arduengo, A.J. ( 4 ) 94 Arenz, T. ( 7 ) 12 Argyropoulos, N.G. ( 7 ) 44 A r i f , A.M. (1) 287, 288, 339, 347, 348, 355; ( 4 ) 107 A r i f i e n , A.E. ( 8 ) 35 Aripov, E.A. ( 9 ) 240, 263 Arison, B. ( 6 ) 16 A r i s t o f f , P.A. ( 7 ) 155 Armour, M.-A. ( 5 ) 66 Arnold, J.R.P. ( 6 ) 76, 80 Arshinova, R.P. ( 9 ) 1 7 , 135-137, 229, 230 Arzoumanian, H. ( 7 ) 65 Asaka, M. ( 6 ) 121 Ashbrook, C. ( 6 ) 193 Ashe, A . J . ( 1 ) 135, 384 Ashinadze, L.D. ( 9 ) 125 Ashley, G.W. ( 6 ) 94 Ashton, W.T. ( 6 ) 16 Asirvatham, E. (7) 32, 33 Askham, F.R. ( 1 ) 49 Asknes, G . ( 3 ) 11 A s s e l i n e , U. ( 6 ) 161 Atherton, F.R. ( 5 ) 104 Atherton, J.I. ( 7 ) 62 Atmadja, J. ( 6 ) 292 Atoh, M. ( 1 ) 27 Ator, M.A. ( 6 ) 9 2 , 9 3 Atrash, B. ( 5 ) 112; ( 9 ) 23 A t t w e l l , D. ( 6 ) 5 Attwood, S.V. (7) 142 Audisio, G. ( 8 ) 6 1 , 7072, 163 A u r e l i a n , L. ( 6 ) 180 A u s t i n , P.E. ( 8 ) 155, 156 Ayad, M. ( 5 ) 129
Ayed, N. ( 2 ) 56; ( 9 ) 86
B a r t l e t t , P.A. ( 5 ) 8 Barton, D.H.R. ( 1 ) 227; (2) 9 Barton, J . K . ( 6 ) 366-368 Baas, P.D. ( 6 ) 354 B a r t s c h , R. ( 1 ) 328 Baasov, J . (7) 105 Baryanoff, B.E. ( 5 ) 51 Baba, A. ( 1 ) 125; ( 3 ) 45 Baryeva, E.S. ( 4 ) 71 Bac, N.V. ( 7 ) 134 Basil, J . D . ( 7 ) 70 Baccar, B. ( 5 ) 129 Basso-Bert, M. ( 1 ) 41 Baceiredo, A. ( 1 ) 5 , 6 , B a t a i l , P. (1) 214; ( 9 ) 337; ( 4 ) 95; ( 7 ) 16; ( 8 ) 16; ( 9 ) 52, 217 168 Bach, S.A. ( 6 ) 169 Bateson, J . H . ( 7 ) 110 B a c h e l l e r i e , J.-P. ( 6 ) Batyeva, E.S. ( 4 ) 3 6 , 4 9 , 50, 72; ( 9 ) 233 305 Badanyan, Sh.0. (5) 131 Baudler, M. ( 1 ) 19-22, 32-36, 138; ( 3 ) 10; ( 9 ) Badrudin, B. ( 9 ) 115 32, 147 B a i l e y , J . M . ( 6 ) 227, 228 Bauer, D.P. ( 1 ) 53 Baindur, S.R. (6) 278 Baker, B.F. ( 6 ) 333 Baumgartner, R. ( 1 ) 8 Bausk, E.V. ( 6 ) 151 Baker, J . C . ( 6 ) 100 Balcom, B.J. ( 9 ) 97 Bax, A. ( 6 ) 370 Baldy, A. ( 7 ) 65 Baxter, S.G. (1) 355; ( 4 ) 107 Balgobin, N . ( 4 ) 74; ( 6 ) 107 Bayard, B. ( 6 ) 187 B a l i t s k a y a , O.V. ( 9 ) 53 Bayev, A.A. ( 6 ) 317 Balszuweit, A. ( 4 ) 1 3 , Baylor, D.A. ( 6 ) 54 17, 34; ( 5 ) 52, 60 Bays, J.P. ( 9 ) 18 B a l t h a z e r , T.M.' ( 5 ) 99 Bazbouz, A. ( 1 ) 216 B a l z a r i n i , J. ( 6 ) 44, 45 Bazin, H. ( 6 ) 129 Bamgboye, O.A. ( 8 ) 6 8 , 79 Beachley, O.T. ( 1 ) 78 Bamgboye, T.T. ( 8 ) 6 8 , 79 Beardsley, G.P. ( 6 ) 264 B a n f a l v i , G. (6) 225 Beaucage, S.L. ( 6 ) 3 4 , Bankmann, M. ( 1 ) 276; ( 7 ) 123 Beaver, B.D. (7) 20, 21 3; ( 9 ) 145 Bannwarth, W. ( 4 ) 88; (6) Becher, R. ( 1 ) 21 104 Beck, D . J . ( 6 ) 364 B a r a i , V.N. ( 6 ) 185 Becker, C.R. ( 6 ) 153 Bararn, G . I . ( 6 ) 249 Becker, G. ( 1 ) 130, 322; Baranetskaya, N . K . ( 1 ) 2 ( 9 ) 24 Baraniak, J. ( 5 ) 19; ( 6 ) Becker, W. ( 1 ) 322; ( 9 ) 24 57 B a r a n s k i i , V.A. ( 9 ) 278 Been, M.D. ( 6 ) 345 Barclay, L. ( 9 ) 97 Beggiato, G. ( 8 ) 172 Barendt, J . M . ( 4 ) 58; ( 9 ) Behe, M.J. ( 6 ) 199 162 Behnam, G.Q. ( 9 ) 86 B e j e r , B. ( 6 ) 110 Barget, G. ( 9 ) 26 Barker, M.F. ( 6 ) 14 Bekasova, N . I . ( 8 ) 91 Barluenga, J. ( 1 ) 386; Bekker, A.R. ( 4 ) 68; ( 5 ) ( 3 ) 42; ( 8 ) 45 65; (9) 195 Barnes, N . J . ( 7 ) 87; ( 9 ) Belakhov, V.V. ( 5 ) 2 133 B e l e t s k i i , I.P. ( 9 ) 1 4 Barone, A.D. ( 4 ) 83 B e l l a n , J. ( 1 ) 265, 332, Barr, R.G. ( 6 ) 358 333; ( 4 ) 111; ( 8 ) 1 7 , Barrans, J. ( 1 ) 378; ( 4 ) 18, 21 101 B e l l e a u , B. ( 5 ) 143 Barreau, M. ( 7 ) 48 Belmont, S.E. (1) 366 Barrett, A.G.M. ( 7 ) 142 B e l ' s k i i , F.I. (5) 84 Barry, C.N. ( 2 ) 20 B e l t r a n , A.M. ( 5 ) 21 Barstow, L.E. ( 6 ) 150 Benage, B. ( 9 ) 18 Barsukov, A.V. (5) 96, Benight, A.S. ( 6 ) 208 Benkovic, S.J. ( 6 ) 201 97; ( 9 ) 253 B a r t h , V. ( 1 ) 271; ( 9 ) 62 Bennamara, A. ( 1 ) 225;
427
Author Index (7) 14 B e n s e l e r , F. (6) 127 B e n t r u d e , W.G. ( 2 ) 4 2 ; ( 6 ) 4 4 , 45 Benziman, M . ( 6 ) 1 6 3 B e r c h a d s k y , Y . ( 9 ) 115 B e r d n i k o v , E.A. ( 5 ) 1 2 5 ; ( 9 ) 95 Beremzhanov, B.A. ( 9 ) 256 Beres, J. ( 6 ) 44, 45 Bergmann, P. ( 1 ) 283 B e r l i n , K . D . (5) 14; ( 9 ) 209 B e r n h a r d t , F.C. ( 9 ) 36 B e r r a d a , M . ( 5 ) 42 B e r r y , D.E. ( 1 ) 181 B e r s e n e v a , L.S. ( 1 ) 1 4 4 ; ( 5 ) 13 B e r t h e l o t , M . ( 9 ) 126 B e r t r a n d , G. ( 1 ) 5 , 6 , 132, 337; (4) 9 , 95; ( 7 ) 16; ( 8 ) 4 , 16, 30; ( 9 ) 5 2 , 217 B e s s e n b a c h e r , C. (9) 116 Bessmann, M.J. ( 6 ) 216 Best-Belpomme, M. ( 6 ) 9 9 Bestmann, H.J. ( 7 ) 1 , 1 2 , 2 9 , 3 0 , 56-58, 1 0 1 , 1 0 4 , 1 3 2 , 136; ( 9 ) 1 6 B e t s c h , D.F. ( 6 ) 401 B e t t e r m a n n , G . ( 1 ) 212 B e t z , A . ( 9 ) 187 B e v e r i d g e , K . A . ( 1 ) 181 Beynon, J.H. ( 6 ) 4 3 Bhatnagar, N.Y. ( 2 ) 9 B h a t t a c h a r y a , S. ( 6 ) 225 B i , Y. ( 9 ) 88 B i a l a , E. ( 6 ) 124 B i a s t o c h , R . ( 1 ) 23-25 B i d d l e s t o n e , M. ( 8 ) 6 6 B i e b e r i c h , M.J. ( 8 ) 9 8 Biernat, J. (4) 90 B i l d s t e i n , B. ( 1 ) 1 7 8 B i n d e r , D. (1) 261 B i n n e w i e s , M. ( 1 ) 279; ( 4 ) 9 8 ; ( 9 ) 236 B i r y k o v , I . P . ( 9 ) 103 B i s b a l , C. ( 6 ) 187 B i s c h o f f , R . ( 6 ) 387 B l a c h e r , R.W. ( 6 ) 206 B l a c k b u r n , G.M. ( 5 ) 80, 120, 122; (7) 98 B l a i r , P. ( 9 ) 225 B l a k e , K.R. ( 6 ) 174-176 B l a k e l y , W . f . ( 6 ) 266 B l a n c h e t t e , M.A. ( 7 ) 80 B l a n q u e t , S. ( 6 ) 9 9 , 233 B l e c h s c h m i t t , K . ( 7 ) 67 B l o c k e r , H. ( 6 ) 3 0 3 , 318 Blonsky, P.M. ( 8 ) 1 5 5 , 156 Bloom, J . D . ( 3 ) 36
Blumenkopf, T.A. ( 5 ) 67 B o b s t , A.M. ( 6 ) 194 Bock, H . ( 1 ) 276; ( 7 ) 3 ; ( 9 ) 145 Bodner, M . ( 6 ) 392 B o h s h a r , M . ( 3 ) 26 Boekemeier, W . ( 6 ) 339 Boer;, R.T. (1) 3 8 , 103 B o e s e , K . ( 7 ) 69 B o e s e , R . ( I ) 284, 285, 290 Boske, J . ( 1 ) 318; ( 8 ) 22; ( 9 ) 189 Boggs, J . E . ( 9 ) 7 B o h l e , D.S. ( 1 ) 289 Bohlen, R . ( 2 ) 1 0 , 4 1 , 42; (5) h Roisdon, M.T. ( I ) 378: ( 4 ) 100 B o l a n d , W . ( 7 ) 146 B o l d e s k u l , I.E. ( 1 ) 331; ( 4 ) 102; ( 8 ) 24; ( 9 ) 1 5 9 , 1 6 6 , 201, 212 B o l e s , T.C. ( 6 ) 310 B o l i k a l , D . (1) 223, 236, 237; ( 9 ) 251 Bollinger, J.C. (3) 17; ( 9 ) 1 2 7 , 246 Bornpeix, G . ( 9 ) 264 Bond, D . R . ( 9 ) 202, 211 Bondarenko, N . A . ( 1 ) 1 4 Bone, R. ( 6 ) 98 Bone, S.A. ( 2 ) 1 5 B o n n e t , M.C. ( 2 ) 57 Bord;, J. ( 2 ) 11 Borisenko, A . A . ( 1 ) 7 , 179; ( 4 ) 3 9 , 5 1 , 5 2 , 54; ( 9 ) 1 6 3 B o r i s o v , E.V. ( 4 ) 6 8 ; ( 9 ) 213 Borisov, G. (3) 4 Borm, J . ( 1 ) 262, 269, 270 B o r n o v a l o v a , G.V. ( 8 ) 8 4 B o r t o l u s , P. ( 8 ) 1 7 1 Bosch, M.P. ( 3 ) 39 B o s c h e l l i , D. ( 7 ) 1 0 9 Bosma, E. (8) 126 B o s n i c h , B. ( 1 ) 1 7 BOSO, B. (8) 110 Bostedor, R . ( 6 ) 16 Bosyakov, Yu.G. ( 9 ) 178 B o t s t e i n , D. ( 6 ) 203 B o t t i n - S t r z a l k o , T. ( 5 ) 118; ( 7 ) 72; (9) 42, 45, 85 B o u c h e r , H. ( 1 ) 17 Boudin, A. (2) 6 , 7 B o u l a y , F. ( 6 ) 243 B o u l o s , L.S. ( 5 ) 7 Bourson, J . ( 3 ) 1 4 ; ( 9 ) 142
Bowden, M.C. ( 7 ) 107 Bowen, S.M. ( 5 ) 1 1 5 Boyd, V.L. ( 5 ) 46 Brauer, D.J. ( 1 ) 12, 69, 90, 121; ( 4 ) 43 B r a u n s t e i n , P. (1) 374 B r e c h t , A . ( 7 ) 5 0 , 51 B r e d k h i n a , Z.A. ( 8 ) 132 Brennan, C . A . ( 6 ) 211 B r e s l o w , R . ( 5 ) 23; ( 6 ) 35 1 B r e u e r , E. ( 7 ) 72 B r e v e t , A . ( 6 ) 99 B r i g h t , D.A. ( 1 ) 88 B r i g h t , R . ( 8 ) 1 1 2 , 121 Brimacombe, R. ( 6 ) 292 Brook, C.P. ( 3 ) 1 6 ; ( 9 ) 175 B r o o k s , D.W. ( 7 ) 1 1 9 Broughton, H.B. ( 7 ) 142 B r o v a r e t s , V.S. ( 1 ) 203 Brown, D. ( 5 ) 122 Brown, L. ( 7 ) 38 Brown, N.C. ( 6 ) 6 6 Brown, R.S. ( 6 ) 353 Brown, T. ( 6 ) 375 Broyde, S. ( 6 ) 288 Bruch, R.C. ( 6 ) 6 B r u c h e , L. (8) 10 Bruck, B. ( 9 ) 158 Brune, H . A . ( 1 ) 8 B r u n n e r , H. ( 1 ) 1 7 4 , 1 7 5 ; ( 4 ) 97 B r u n s , A . ( 9 ) 57 B r u z i k , K.S. ( 4 ) 6 6 ; ( 5 ) 10 B r y c e , M.R. ( 1 ) 2 1 3 ; ( 5 ) 3 9 ; ( 9 ) 216 Buck, H.M. ( 2 ) 1 6 ; ( 6 ) 371, 3 7 2 ; ( 9 ) 6 7 , 114 B u d e s i n s k y , M. ( 6 ) 24 Budhram, R.S. ( 7 ) 81 Buhlmeyer, W . ( 1 ) 133 B u r g e r , H. (1) 9 0 B u r k l i n , M. ( 1 ) 1 7 1 Bugerenko, E.F. ( 1 ) 1 4 6 ; ( 9 ) 161 Bukachuk, O.M. (1) 200, 20 1 B u l a r g i n a , T.V. ( 6 ) 232 Bulgakov, R . ( 6 ) 57 B u l g a r e v i c h , S.B. (8) 130; ( 9 ) 232 B u l o t , J.J. ( 5 ) 55 Bulycheva, E.g. (8) 9 1 Buneva, V . N . ( 6 ) 249 Bunton, C.A. ( 5 ) 22 B u r d i c k , G.W. ( 9 ) 235 Burg, A . B . (1) 1 6 5 Burgada, R. ( 2 ) 28-30, 45; (4) 1 5 , 16; (7) 17, 18, 60
Organophosphorus Chemistry
428 Burger, R.M. ( 6 ) 328 Burget, G. (1) 1 8 , 166, 167; ( 8 ) 138; ( 9 ) 160 Burik, A. ( 1 ) 180; ( 4 ) 78; ( 6 ) 26 Burilov, A . R . ( 4 ) 48 Burkey, T.J. ( 9 ) 113, 255 Burklin, M. ( 4 ) 108 Burnaeva, L.A. ( 2 ) 52 Burski, J. ( 2 ) 31 Buryanov, Ya.1. ( 6 ) 317 Bushnell, G.W. ( 1 ) 181 Bushweller, C.H. ( 9 ) 10 Buss, A.D. ( 3 ) 28 Busulini, L. ( 8 ) 171 Butin, B.M. (1) 52 Butler, W. (1) 384 Bychkov, N . N . ( 9 ) 65 Byrd, R . A . ( 4 ) 7 , 93; ( 6 ) 146, 171, 376 Cable, M.B. ( 6 ) 247 Cabral, J. ( 9 ) 89 Cadet, J . ( 6 ) 269 Cai, W. ( 1 ) 229 Cain, T. ( 8 ) 7 ; ( 9 ) 79 Cairns, S.M. ( 2 ) 26; ( 7 ) 22 Callahan, L. ( 6 ) 173 Calvitti, S. ( 7 ) 151 Camerini, E. ( 7 ) 151 Cameron, T.S. ( 8 ) 195 Caminade, A,-M. ( 1 ) 132, 266; ( 4 ) 9 ; ( 8 ) 30 Campana, J.E. ( 9 ) 237 Campbell, J . A . ( 9 ) 167 Camps, F. ( 3 ) 39 Canning, L.F. ( 6 ) 16 Cantor, C.R. ( 6 ) 393 Cantu, Y.L. ( 8 ) 75 Capdevila, J. ( 7 ) 121 Caputo, R . ( 1 ) 87 Cardona, L. ( 7 ) 153 Caretta, A . ( 6 ) 47 Carle, G.F. ( 6 ) 394 Carlquist, M. ( 6 ) 241 Carmichael, D. ( 1 ) 364 Carmichael, I. ( 9 ) 108 Carniato, D. ( 5 ) 93 Carpenter, L.E. ( 2 ) 59 Carr, L . J . ( 8 ) 99 Carrie', R. (1) 106, 107, 379 Carroy, A. ( 1 ) 28 Caruthers, M.H. ( 4 ) 8 3 , 8 4 ; ( 6 ) 123, 150, 166 Casalbore-Miceli, G. ( 8 ) 172 Casser, C. (1) 282, 294, 306, 307; (9) 33 Cassir Chury, M. ( 9 ) 259
Castagnino, E. ( 5 ) 133 Castedo, L. ( 3 ) 40 Caster, K.C. (1) 369 Castera, P. ( 8 ) 88 Castro, M.M. ( 6 ) 147 Cavaggioni, A. ( 6 ) 47 Cech, D. ( 6 ) 317 Cech, T.R. ( 6 ) 342, 343, 345, 346 Cefelin, P. ( 8 ) 157 Cernia, E. (1) 176 Cerrini, S. ( 9 ) 206 Cerveau, G. ( 2 ) 6 , 7 Cesar Castells, R. ( 9 ) 258 Chadha, R . K . ( 9 ) 207 Chae, H . J . ( 8 ) 101 Chakraborty, T.K. ( 7 ) 128 Champion, D.H. ( 1 ) 311 Champion, E. ( 7 ) 115 Chan, G.L. ( 6 ) 262 Chandrasekaran, S. ( 6 ) 383
Chandrasekhar, V. ( 8 ) 90 Chang, C.-W. ( 6 ) 254 Chang, D.-K. ( 6 ) 144 Chang, L.-H., ( 6 ) 324 Charrier, C. ( 1 ) 342, 366; ( 9 ) 73, 74 Chattopadhyaya, J. ( 4 ) 74, 1 5 , 107, 118, 129 Chavez, F. ( 6 ) 212 Chawla, R.R. ( 6 ) 12 Chen, C. ( 6 ) 132 Chen, C.B. ( 6 ) 188 Chen, C.H. ( 1 ) 55; ( 3 ) 9 ; ( 9 ) 156 Chen, H . - J . ( 4 ) 53; ( 9 ) 164 Chen, J.-K. ( 6 ) 275, 276 Chen, P.C.Y. ( 8 ) 7 ; ( 9 ) 79 Cheng, H.-L. ( 6 ) 341 Cheng, M.S. ( 6 ) 76 Cheng, S.-C. ( 6 ) 98, 341 Cherkasov, R . A . ( 2 ) 1 ; ( 5 ) 125, 149, 158 Chermykh, T.E. ( 4 ) 45 Chernega, A . N . (1) 331; ( 4 ) 102; ( 8 ) 24, 54; ( 9 ) 150, 159, 166, 194, 201, 203, 212 Chernov, A.N. ( 1 ) 182, 380; ( 9 ) 90, 174 Chernov, P.P. ( 9 ) 95 Chernykh, T.E. ( 1 ) 184; ( 8 ) 27 Chernyshev, E.A. ( 1 ) 146; ( 9 ) 161 Chernyuk, I . N . ( 1 ) 219 Chiarello, R.H. ( 6 ) 154 Chiche, L. (1) 225, 226
Chichester, S.V. ( 8 ) 65; ( 9 ) 118 Chichkanova, T.V. (1) 191 Chimishkyan, A.L. ( 5 ) 77; ( 8 ) 19 Chinsky, L. ( 6 ) 395 Chivers, T. ( 8 ) 124; ( 9 ) 221 Choder, M. ( 6 ) 392 Choffat, Y. ( 6 ) 308 Chojnowski, J . ( 1 ) 157; ( 3 ) 1 ; ( 4 ) 22 Chong, C. ( 9 ) 46 Chou, T. ( 1 ) 15 Chou, W.-N. ( 8 ) 7; ( 9 ) 79 Choudary, B.M. ( 1 ) 177 Chouinard, P.M. ( 5 ) 8 Choukroun, R. (1) 41 Chovnikova, N . G . ( 1 ) 202 Choy, W. ( 7 ) 80 Christau, H . - J . ( 1 ) 215, 216, 218, 226 Christodoulou, C. ( 6 ) 115 Christol, H. (1) 215, 218, 225 Chu, B. ( 8 ) 142, 143 Chuit, C. ( 2 ) 6 , 7 Chung, Y.S. ( 7 ) 123 Church, J.S. ( 9 ) 227 Churilino, N.V. ( 5 ) 135 Chuvashov, D.D. ( 1 ) 76; ( 9 ) 148 Cicero, S.E. ( 6 ) 387 Ciesiolka, J . ( 6 ) 277 Claesen, C . A . A . ( 4 ) 73; ( 6 ) 32, 107, 125, 160 Clark, J . H . ( 9 ) 123 Clark, J . M . ( 6 ) 264 Clark, T. ( 7 ) 46 Clarke, J. ( 6 ) 224 Claude, C. ( 1 ) 16 Cleary, D.G. ( 7 ) 74 Clegg, W. ( 8 ) 52 Cleland, W.C. ( 5 ) 34, 35 Cleve, C. ( 9 ) 152 Cnossen-Voswijk, C. ( 8 ) 192 Cocito, C. ( 6 ) 390 Coene, M. ( 6 ) 390 Cohen, S. ( 9 ) 197 Coiro, V.M. ( 9 ) 206 Colanduoni, J . A . ( 6 ) 238 Colburn, J.C. (1) 384 Coll, J. ( 3 ) 39 Colleuille, Y. ( 1 ) 114 Collignon, N. ( 5 ) 55, 59; ( 7 ) 75, 97 Collins, M.L. ( 6 ) 204 Colman, R.F. ( 6 ) 227, 228 Comasseto, J . V . ( 9 ) 172 Commenges, G. ( 8 ) 8 9 Cornpagnone, R.S. ( 7 ) 161
429
A uthor Index Condron, L.M. ( 9 ) 21 Conley, M.P. ( 6 ) 257 Connell, C.R. ( 6 ) 299 Connelly, C.J. ( 6 ) 289 Connolly, B.A. ( 6 ) 374; ( 9 ) 51
Constantinides, I. ( 5 ) 124
Contreras, R . H .
( 9 ) 75,
76
Cook, B. ( 5 ) 58 Cook, R.D. ( 5 ) 148; ( 6 )
32; ( 6 ) 7 4 , 76, 272; ( 9 ) 48, 51 Culshaw, D. (7) 124 Cummings, A. ( 6 ) 269 Cummins, J.H. ( 6 ) 20; ( 9 ) 51 Cupps, T.L. (7) 144 Cusack, N.J. ( 6 ) 8 5 , 60 Cypryk, M. ( 1 ) 157 Czech, T.R. ( 6 ) 1 Czerwiuski, E . W . ( 9 ) 170
90; ( 9 ) 247, 279
Cooke, M.P. ( 7 ) 49 Cooney, J.V. ( 7 ) 20 Coons, D.E. ( 4 ) 53; (9) 164
Corbel, B. ( 4 ) 5; ( 5 ) 73 Corbin, J.D. ( 6 ) 55, 56 Cordes, A.W. ( 1 ) 103 Cordiero, M.L. ( 5 ) 110 Corey, E.J. ( 7 ) 28, 116 Corgano, S . ( 5 ) 133 Cornish, C.A. ( 3 ) 29 Corriu, R.J.P. ( 2 ) 5-7 Corset, J . ( 5 ) 118; ( 9 ) 45
Cosstick, R. ( 6 ) 167, 312 Costisella, B. ( 2 ) 37 Cotter, R.J. ( 6 ) 63 Coull, J.M. ( 6 ) 401 Couret, C. (1) 256, 267, 352; ( 9 ) 107, 154 Cowley, A.H. (1) 172, 287, 288, 311, 339, 347, 348, 351, 353-355; ( 4 ) 1, 106, 107, ( 9 ) 190 Cradock, S. ( 9 ) 225 Craig, S.L. (1) 103 Cramm, D.A. ( 2 ) 40; ( 9 ) 252 Crans, D.C. ( 5 ) 9 Crea, R. ( 6 ) 154 Creary, X . ( 5 ) 138; ( 9 ) 1 8 , 277 Cremer, S.E. ( 9 ) 167 Criddle, W.J. ( 1 ) 230, 231; ( 9 ) 260 Cristante, M. ( 1 ) 132; ( 4 ) 9 ; ( 8 ) 30 Cristau, H . J . ( 7 ) 14 Crombie, L. ( 7 ) 135 Cross, R.L. ( 6 ) 234 Crothers, D.M. ( 6 ) 391 Crowther, J.B. ( 6 ) 385 Crumbliss, A.L. ( 1 ) 370 Crysler, C.S. ( 6 ) 82 Cubellis, M.V. ( 6 ) 388 Culcasi, M. ( 1 ) 136, 267; ( 9 ) 107, 110 Cullis, P.M. ( 5 ) 20, 29,
Dabkowski, W. ( 4 ) 64 Daemen, C.J.M. ( 6 ) 3 2 , 160
Dahl, 0. (4: 40, 82 Dahlenburg, L. ( 1 ) 50 Dai, <J. ( 1 ) 229 Daigle, K. ( 6 ) 320 d'Alarcao, M. ( 7 ) 116 Dalbon, P. ( 6 ) 243 Dalley, N.K. ( 6 ) 11 D'Ambrosio, S.M. ( 6 251 Damha, M.J. ( 4 ) 8 7 , 92 : ( 6 ) 122, 164
Dana, V. ( 2 ) 11 Danchenko, E.A. ( 4 ) 1 8 Dang, T.P. ( 1 ) 1 1 3 , 114 Dangyan, Yu.M. ( 5 ) 31 Daniel, H, ( 7 ) 41 Danilova, 0.1. ( 9 ) 229, 230
Daolio, S. (8) 6 1 , 69-73 Daouk, W.A. ( 5 ) 148 Darakis, G. ( 9 ) 264 Darensbourg, D.J. ( 8 ) 33 Dartmann, M . (1) 287, 318; ( 8 ) 22; ( 9 ) 189
Das, M.K. ( 1 ) 9 1 , 92 Datema, R. ( 6 ) 15 Dauter, Z. ( 5 ) 39; ( 9 ) 216
Davidowitz, B. (5) 154; ( 9 ) 186
Davidson, A.H. ( 7 ) 87 Davidson, F. ( 4 ) 94 Davies, D.B. ( 6 ) 369 Davies, G. ( 8 ) 144 Davies, H.M.L. ( 7 ) 112 Davies, R.w. ( 6 ) 344 Davis, J.T. ( 7 ) 80 Davy, H. (5) 139 Dawson, J.M. ( 6 ) 90 Day, H. ( 5 ) 90 Day, R.O. ( 1 ) 303, 304; ( 9 ) 153
DeBoer, J.L. ( 8 ) 192-194 De Bruijn, E.A. ( 9 ) 262 de Clercq, E. ( 6 ) 4 4 , 45 Degener, H.J. ( 1 ) 1 8 5 , 186; ( 5 ) 108
Degl'Innocenti, A. ( 7 ) 58 Dehnicke, K. ( 9 ) 171 DeJaeger, R. ( 8 ) 4 4 , 5 8 , 146
de Jong, S. ( 8 ) 82 Del Buttero, P. ( 7 ) 5 3 , 54
Delius, H. ( 6 ) 224 Dellaria, J.F. ( 7 ) 92 Dellinger, D. ( 4 ) 8 3 Delmas, M. ( 7 ) 25 Delord, T.J. ( 7 ) 70 Delort, A.M. ( 6 ) 140, 141 Dembech, P. ( 7 ) 58 de Murcia, G . ( 6 ) 291 Dencheva, N. ( 3 ) 4 Denney, D.B. (2) 1 9 ; ( 9 ) 6 8 , 69
Denney, D.Z. ( 2 ) 1 9 ; ( 9 ) 6 8 , 69
Dennis, D. ( 6 ) 162 Denny, W.A. ( 6 ) 376; ( 9 ) 72
Deol, S.S. (1) 97 Deome, A.J. ( 8 ) 9 8 de Riese-Meyer, L. ( 1 ) 34 deRuiter, B. ( 8 ) 126 Dervan, P.B. ( 6 ) 331-334 Desai, M.C. ( 7 ) 28 De Sarlo, F. ( 1 ) 379 Deschamps, B. ( 1 ) 292, 362, 368, 374
Deschenaux, R. ( 1 ) 67 Deshong, P. ( 7 ) 141 Dessen, P. ( 6 ) 233 Dettoff, B.S. ( 7 ) 74 Devadoss, E. ( 8 ) 77, 87 De Villiers, L.S. ( 9 ) 272 de Vries, E.G.E. ( 8 ) 8 2 , 83
de Vroorn, E. ( 6 ) 172 Dewan, J.C. ( 6 ) 353 Dharanipragada, R. ( 7 ) 162
Dhathathreyan, K.S. (8) 125, 126
Diallo, 0. (1) 378; ( 4 ) 101
Dianes, R.A. ( 7 ) 128 Dianova, E.N. ( 1 ) 245, 380-382;
( 4 ) 2 ; ( 9 ) 174
Diekmann, S. (6) 391 Diel, P.J. ( 5 ) 95 Diemert, K. ( 1 ) 152 Dilaimi, A.A. ( 7 ) 91 Dillon, K.B. ( 1 ) 187, 239; ( 8 ) 1 6 ; ( 9 ) 5 2 , 56, 105 DiMarco, P. (8) 173 Ding, W . ( 1 ) 229 Dingwall, J.G. ( 5 ) 58 Disdaroglu, M. ( 6 ) 270
Organophosphorus Chemistry
430
Ditrich, K. (7) 90 Di Tullio, D. (7) 114 Dixon, K.R. (1) 181 Diz, A.C. (9) 76 Dizdaroglu, M. (6) 266 Dmitriev, V.I. (9) 131 Dobberstein, B. (6) 177 Dobrova, N.B. (8) 174, 175 Dodd, C. (6) 299 Doel, G.R. (1) 120 Doetsch, P.W. (6) 259, 262 Dogadina, A.V. (5) 48; (9) 228 Doherty, N.M. (1) 122 Doi, T. (6) 210 Dolenko, G.N. (9) 40, 131 Dolgikh, M.A. (8) 160 Dolle, R.E. (3) 38 Dombroski, B.A. (6) 338 Doney, J.J. (1) 55; (3) 9; (9) 156 Doren, D. (7) 145 Dorfman, A.Ya. (1) 77 Dorsey, B.D. (7) 131 Dose, K . (6) 245 Doskeland, S.O. (6) 55, 56 Dostal, K. (8) 149 Douglas, K.T. (6) 278 Dove, M.F.A. (2) 3 Downes, J.M. (1) 17 Drach, B.S. (1) 203 Drahovsky, D. (6) 196 Drake, A.F. (6) 252 Drake, J.E. (9) 207 Draper, D.E. (6) 336 Dreef, C.E. (6) 172 Dresler, S.L. (6) 291 Drew, J. (7) 150 Driler, H. (6) 137 Driska, S.P. (6) 247 Dubendorff, J.W. (4) 83 Dubois, R.A. (1) 118, 119; (8) 159 Dubovik, 1.1. (8) 164, 175 Dubuc, G. (6) 207 DUC, G. (7) 14 Duchamp, D. (6) 173 Duchange, N . (6) 148 Dudchenko, T.N. (2) 50; (8) 28, 29 Duddeck, H. (5) 49; (9) 84 Dudis, D. (7) 70 Dudycz, L.W. (6) 66 Duke, A.E. (6) 14 Dumont, J.E. (6) 52 du Mont, W.-W. (1) 101, 102
Dunach, E. (9) 59 Dunitz, J.D. (3) 16; (9) 175 Dunker, K.-H. (1) 314, 315; (7) 6; (9) 37 Dunn, D.A. (8) 98 Dupont, Y. ( 6 ) 72 du Preez, J.G.H. (3) 46 Durig, J.R. (9) 130, 133, 227 Durmis, J. (9) 86 DUS, D. (5) 98 Dvoinishnikova, T.A. (1) 188; (8) 127-129 Dyatlova, N.M. (5) 96, 97; (9) 248,, 253 Dykema, K.J. (1) 248; (7)
221 Elgamal, M.H.A. (5) 49 Eliseeva, G.D. (9) 278 El-Issa, B.D. (9) 9 El-Khatib, F. (1) 266 El Khoshnieh, Y.O. (2) 28, 29 Elliot, J. (3) 34 El Manouni, D. (2) 30, 45; (4) 15, 16; ( 7 ) 17, 18 Elov, A.A. (6) 158 El-Yazigi, A. (9) 262 Empfield, J.R. (1) 127 Engelhardt, L.M. (1) 39 Engelhardt, M. (5) 126 Engelke, U. (6) 39 Engels, J. (4) 76; (6) 5 Dzhiembaev, B.Zh. (9) 194 157 Eppstein, D.A. (6) 186 Dziegielewski, J . O . (1) 137 Epshtein, L.M. (9) 125 Erastov, O.A. (9) 94 Erhenfeld, G.M. (6) 324 Erickson, T.J. (7) 78 Eadie, J.S. (6) 169 Ericson, A.C. (6) 15 Eads, C.D. (6) 238 Eastman, A. (6) 363 Eriksson, S. (6) 241 Echsler, K.-J. (3) 25 Erkasov, R.Sh. (9) 256 Ermann, P. (7) 101, 104 Eckl, E. (1) 128 Eckstein, F. (6) 50, 54, Ermolaeva, L.V. (9) 17 88, 167, 202, 312, 374; Erneux, C. (6) 52 Ernst, L. (1) 212 (9) 51 Eddy, D.B. (5) 14 Ernst, R.R. (6) 376 Edery, I . ( 6 ) 350 Erzhanov, K.B. (1) 52 Edmonds, M. (4) 84; (6) Escalier, J. (6) 361 166 Escudig, J. (1) 256, 267, Efcavitch, J.W. (6) 153 352; (9) 107, 154 Effenberger, F. ( 4 ) 14; Espenbetov, A.A. (9) 194 Essenfeld, A.P. (7) 80 (5) 56 Efremov, Yu.Ya. (1) 382; Estekhina, M.N. (1) 2 (8) 132 Etemad-Moghadam, G. (1) Egamberdyev, Sh. ( 5 ) 109; 265; (4) 111 (9) 200 Eto, M. (5) 146 Egan, W. (4) 7; (6) 171 Evans, S.A. (1) 95, 96; Egert, E. (5) 100; (8) (2) 20-22 137 Everett, G.W. (6) 84 Ehrenreich, W. (1) 133; Evseev, A.M. (9) 248 Evtyagin, G.A. (9) 233 (9) 187 Ehresmann, B. (6) 305 Ehresmann, C. (6) 305 Ehrlich, K.C. (6) 320 Fackler, J.P. (7) 70 Ehrlich, M. (6) 320 Fahrney, D.E. (6) 42 Eisenbraun, E.J. (7) 81 Falck, J.R. (7) 121, 122 Ejchart, E. (9) 101 Fall, Y. (7) 134 Ejiri, E. (7) 148, 149 Fanni, T. (2) 34 Farag, R.S. (8) 35 Ekanger, R. (6) 55 Ekeland, R. (9) 167 Farnham, W.B. (2) 4 El-Anba, F. (1) 337 Farquhar, D. (6) 17 Elango, V. (7) 141 Faucher, J.P. (8) 88 El-Badawi, M. (5) 74 Fauq, A.H. (7) 129 El-Barbary, A.A. (5) 91, Fawzi, R. (1) 75 Fazakerley, G.V. (6) 377, 141; (9) 188 El-Batouti, M. (1) 220, 382
Author Index F a z i o , S.D. ( 6 ) 387 Feasey, N.D. (1) 120 Fedorov, S.G. ( 8 ) 97 Fedorova, O.S. ( 6 ) 283 Fehlhammer, W.P. ( 1 ) 206; (7) 13 Fenske, D. (1) 260, 261 F e r i n g a , B.L. ( 5 ) 114 Fernandez, I. ( 7 ) 153 F e r r e n t t i , L. ( 6 ) 155 F e r r e r i , C . ( 1 ) 87 Feshchenko, N.G. (1) 243; ( 4 ) 69; ( 9 ) 166 F i e l d , A . K . ( 6 ) 16 F i e l d e r , H.P. ( 9 ) 269 Fincham, J.K. ( 9 ) 218 Finet, J.P. (2) 9 Fi nk, J. (1) 326; ( 9 ) 30 F i n k l e r , S.H. ( 7 ) 89 F i o r e n z a , M. ( 7 ) 58 F i o r i n i , M. (1) 176 F i s c h e r , J. (1) 342, 363, 372; ( 3 ) 7 Fitzsimmons, B . J . ( 7 ) 120 Fl anagan, J.M. ( 6 ) 386 F l e m i n g , H.W. ( 9 ) 141 F l e t c h e r , P. ( 6 ) 71 F l i e s s , A. ( 6 ) 318, 319 F l i t s c h , W . (1) 199; ( 7 ) 35, 45 F loyd, T.R. ( 6 ) 385, 387 Fl uck, E. (1) 68, 211; ( 2 ) 1 8 ; ( 7 ) 15; ( 9 ) 199 Fodor, G. ( 7 ) 162 Fodor, S.P.A. ( 6 ) 396 F o l l i n g , P. ( 1 ) 309 F o e r s t e r , H. ( 9 ) 57 F ontai ne, X.L.R. (1) 116 F o r c e l l e s e , M.L. ( 7 ) 151 Ford, J.R. ( 8 ) 142 F or d, R . R . ( 1 ) 154, 295; ( 8 ) 26 F o r r e s t , . B . J . ( 9 ) 97 For s t ova, J . ( 6 ) 103 FOSS, V.L. ( 1 ) 184; ( 4 ) 45; ( 5 ) 159, 160; (8) 27, 39, 40 Fout s, C.S. ( 6 ) 376 Fox, J . L . (1) 55; ( 3 ) 9 ; ( 9 ) 156 Fox, K . R . ( 6 ) 314 Fraenkel-Conrat, H . ( 6 ) 213 Fr ancke, R. (5) 6 F r a nczek, F.R. ( 5 ) 8 5 Frank, A . ( 6 ) 318 Fr ank, M. ( 6 ) 394 Frank, R. ( 6 ) 177, 303 Franke, E. ( 1 ) 335 Franke, L.A. ( 6 ) 276 F r a n k l i n , W . A . ( 6 ) 259 FrazZo, C.M.F. (1) 189;
43 1 ( 6 ) 35 (7) 9 G a r r e t t , G . ( 5 ) 124 F r e b e l , M. (1) 285, 286 Garrou, P.E. (1) 1 1 8 , F r e e d , J.J. ( 6 ) 12 119; ( 8 ) 159 Freeman, A. ( 9 ) 115 G a s e t , A. ( 7 ) 25 F r e i d z o n , Ya.S. ( 8 ) 169 Gasparro, F.P. ( 6 ) 258 F r e i s t , W. ( 6 ) 65 G a s s n e r , T. (7) 46 French, R . J . ( 9 ) 226 G a u t h i e r , J.Y. ( 7 ) 115 F r e n k e l , K . ( 6 ) 269 G a v a r i n i , H.O. ( 9 ) 7 5 , 76 F r e sc o , J . R . ( 6 ) 258 Gaydoul, K.-R. ( 1 ) 3; ( 3 ) Frey, F.W. ( 1 ) 5 6 , 57 F r e y , M.H. ( 6 ) 376; ( 9 ) 2, 3 Gayen, A . K . ( 7 ) 39 72 Gazizova, L.Kh. ( 9 ) 9 5 F r e y , P.A. ( 5 ) 38; ( 9 ) 50 Gee, Y.G. ( 6 ) 105 Friedman, J . M . ( 5 ) 28 G e f e l , E . I . (9) 82 F r i j n s , J . H . G . ( 3 ) 43 Gehrke, C.W. ( 6 ) 320 F r i t z , G. ( 1 ) 23-26 Gellman, S.H. ( 5 ) 23 F r i t z , H . (9) 81 Gensheimer, H.-P. ( 6 ) 53 F r i t z , H.-J. ( 6 ) 321 F r i t z , H.P. (1) 8 0 ; ( 7 ) 7 G e n tn e r , N.E. ( 6 ) 261 George, R.D. ( 6 ) 11 F r o e h l e r , B.C. ( 4 ) 79; G e r a n t i , L. ( 8 ) 10 ( 6 ) 28 Gereke, R . ( 4 ) 9 8 F r o l o v a , S.B. ( 6 ) 250 Gerhard, J . ( 5 ) 145 Froment, F. ( 5 ) 1 1 8 ; ( 9 ) Germa, H. (1) 247; ( 8 ) 1 45 Germeshausen, J . (1) 1 9 ; Fronczek, F. ( 9 ) 100 ( 6 ) 16; ( 9 ) 32 F r o s t , J.W. ( 5 ) 110 G e r ts y u k , M.N. ( 8 ) 14 F r y , S.E. (1) 241 G e r v a is , D. (1) 41 Fuchs, P.L. (1) 192 F u c i a r e l l i , A . F . ( 6 ) 271 Gettleman, L. ( 8 ) 186 G h a t t a s , A.B.A.G. ( 5 ) 91; F u j i i , M. ( 6 ) 29 ( 9 ) 188 Fujimura, R . K . ( 6 ) 386 Gibbs, D.E. (5) 6 9 , 70 F u j i t a , F. ( 8 ) 184 Gibbs, E.J. ( 6 ) 238 F u j i t a , J . (1) 27 G ie r e n , A. ( 1 ) 186; ( 9 ) F u j i wa r a , M. ( 3 ) 45 187 F u j i wa r a , T. ( 6 ) 25 G ig a n tin o , J.J. (2) 19 Fukui, T. ( 6 ) 235, 236 G i l b e r t , J . C . ( 7 ) 95 Fukuzumi, K . ( 7 ) 130 Gilbert, W. (6) 3 F u l i e r o v a , A . (8) 1 2 G i l e s , J.W. ( 6 ) 150 F u r i n , G.G. ( 2 ) 1 7 ; ( 9 ) Gilheany, D.G. ( 9 ) 173 104, 149 G im a tila k a , A.A.L. ( 7 ) F u r l o n g , J . C . ( 6 ) 306 142 F y t a s , G. ( 8 ) 142 Gimautdinova, 0.1. ( 6 ) 250 Ginsburg, A . ( 6 ) 69 Gaffney, B.L. ( 6 ) 1 2 6 , Giongo, G.M. ( 1 ) 176 135 G ir o , G . ( 8 ) 1 7 2 , 173 G a i t , M . J . ( 6 ) 115 G a i t z s c h , E. ( 1 ) 314, G l a s s , R.S. ( 3 ) 12; (9) 43 315, 317; ( 7 ) 6 ; ( 9 ) Glave, S.A. ( 6 ) 175 37, 165 G a i t z s c h , T. (1) 314, 316 Gleiter, R . ( 9 ) 147 G l e r i a , M. ( 8 ) 6 1 , 69-73, Galat, A. ( 6 ) 380 163, 171, 173 Galazka, G . ( 6 ) 267 G lid e w e ll, C. ( 9 ) 1 1 1 , Galeeva, I . Z . (1) 380; 112 ( 9 ) 174 Gloede, J. (1) 160; ( 2 ) G a l l o , K.A. ( 4 ) 7 , 93; 37; ( 4 ) 55 ( 5 ) 46; ( 6 ) 146, 171 Glowiak, T. ( 9 ) 191 Gao, X. ( 6 ) 126 Gloyna, D. ( 9 ) 143 Ga r b a r i n o , J . E . ( 6 ) 230 Gluber, N.S. ( 9 ) 124 Garbauskas, M.F. (1) 127 Glushakov, S.N. ( 8 ) 177 G a r c i a , B. ( 7 ) 153 Gnewuch, T. ( 6 ) 195 Garegg, P.J. ( 4 ) 7 9 , 8 1 ;
Organophosphoms Chemistry
432 Gnuchev, N.V. ( 6 ) 97 Godovikov, N.N. ( 9 ) 184 Godovikova, T.S. ( 6 ) 249 Goldner, W. ( 1 ) 20 Goghova, M. ( 9 ) 86 Gogte, V.N. ( 9 ) 239 Goh, K.M. ( 9 ) 21 Gol, F. ( 1 ) 69 Goldberg, I . ( 1 ) 169; (5) 89 Goldberg, J . M . ( 6 ) 366 Gol'dfarb, E.I. ( 9 ) 102 Gol'dfarb, E.L. ( 5 ) 158 Gol'din, G.S. ( 8 ) 97 Golina, S . I . ( 8 ) 177 Goljer, I. ( 9 ) 86 Golobish, T.D. ( 1 ) 127 Gololobov, Yu.G. ( 9 ) 203 Gomelya, N.D. ( 9 ) 166 Gonbeau, D. ( 8 ) 6; ( 9 ) 5 , 15 Goodman, D.S. (7) 100 Goody, R.S. ( 6 ) 87 Gordan, M.S. ( 9 ) 6 Gordillo, B. ( 3 ) 41 Gordon, M.S. ( 1 ) 248, 249; ( 7 ) 5 ; ( 9 ) 1 Gorenstein, D.G. ( 2 ) 34; (5) 25 Gorn, V.V. ( 6 ) 151, 156 Gornicki, P. ( 6 ) 273, 274, 277 Gorshunov, I.Yu. ( 4 ) 36 Gottikh, M.B. ( 6 ) 159 Gowda, G. ( 7 ) 150 Gozman, I . P . (9) 102 Grabowski, G. ( 9 ) 126 Grachev, M.A. ( 4 ) 68; ( 6 ) 237 Gradov, V.A. ( 1 ) 141, 142 Graff, M. ( 7 ) 91 Graham, J.B. ( 1 ) 103 Gralla, J . D . ( 6 ) 309 Gramstad, T. ( 3 ) 15 Graves, D.F. ( 8 ) 133 Grebowicz, J. ( 8 ) 162 Green, M . J . ( 7 ) 117 Gregoli, S. ( 6 ) 272 Grekov, L . I . ( 1 ) 76 Grens, E. ( 6 ) 209 Greuer, B. ( 6 ) 292 Grice, P. ( 7 ) 124 Grieco, P.A. ( 7 ) 137 Griffin, J.H. ( 1 ) 30 Griffiths, D.V. ( 4 ) 23, 24; ( 7 ) 19 Griller, D. ( 9 ) 255 Grimley, E. ( 1 ) 4 Grobe, G. ( 9 ) 35 Grobe, J. ( 1 ) 131, 268, 278-280; ( 9 ) 236 Grochowski, E. ( 1 ) 108
Grotzinger, L. ( 1 ) 175 Groginsky, C.M. ( 6 ) 150 Gromov, A.V. (9) 82 Gromova, E.S. ( 6 ) 316, 317 Gronchi, G. ( 1 ) 136, 267; ( 9 ) 107, 110 Groner, P. ( 9 ) 130, 227 Gross, E. ( 1 ) 350 Gross, H. ( 2 ) 37; (5) 84 Gross, M. ( 1 ) 374 Gross, R. ( 9 ) 116 Grosse, F. ( 6 ) 303 Grossmann, G. ( 9 ) 78, 80 Gruner, M. ( 9 ) 78 Gruszeoka, E. ( 9 ) 191 Gruys, K.J. ( 6 ) 86 Gudat, D. ( 1 ) 250, 287, 288; ( 4 ) 103; ( 8 ) 23; ( 9 ) 146 Guengerich, F.P. ( 6 ) 256 Guerch, G. ( 8 ) 6 7 , 88 Guerrier-Takada, C. ( 6 ) 347, 348 Guerro, A. ( 3 ) 39 Guth, W. ( 1 ) 64; ( 4 ) 33 Guga, P. (5) 37; ( 6 ) 51; ( 9 ) 49 Gulbenkian, A.R. ( 7 ) 117 Guldner, K. ( 1 ) 133 Gumport, R . I . ( 6 ) 211 Gunn, B.P. ( 7 ) 119 Gupta, K.C. ( 4 ) 70; ( 6 ) 149; ( 9 ) 226 Gupta, R.K. ( 9 ) 208 Gupta, S.K. ( 7 ) 143 Gurevich, P.A. ( 1 ) 224; ( 4 ) 10, 47 Gurov, M.V. (5) 159, 160; ( 8 ) 39, 40 Guschlbauer, W. ( 6 ) 382 Guseinova, M.M. ( 4 ) 59, 60 Gusev, A . I . ( 1 ) 146; ( 9 ) 161 Gutsche, C.D. ( 9 ) 99 Guy, A. 6 ) 141 Gwara, J (5) 126 Gzewczyk J. ( 5 ) 101 Haake, P ( 9 ) 89 Haas, A. ( 4 ) 28; ( 5 ) 15 Haase. M (1) 158 Habib; M. (lj 48 Hacklin, H. ( 2 ) 41 Hackney, M.L.J. (1) 51; ( 4 ) 46 Hadden, S. ( 6 ) 126 Haddon, R.C. ( 8 ) 62, 65; ( 9 ) 118 Hagele, G. ( 1 ) 156; ( 5 )
126; ( 9 ) 185 Haelters, J.P. ( 4 ) 5 ; ( 5 ) 73 Haeuptle, M.-T. ( 6 ) 177 Hagan, M.P. ( 6 ) 266 Hagerman, P.J. ( 6 ) 391 Hagihara, M. ( 5 ) 50; ( 7 ) 84 Hagnauer, G.L. ( 8 ) 142, 144 Hahn, J. (1) 22, 138; ( 3 ) 10 Hai, T.T. ( 6 ) 62-64 Hajj, A.N. ( 5 ) 148 Hakeem, N.A. ( 6 ) 43 Halasa, A.F. ( 8 ) 150 Halet, J.F. (1) 214; ( 9 ) 168 Haley, B.E. ( 6 ) 71 Hall, C.D. ( 1 ) 99; ( 2 ) 23, 48; ( 4 ) 26 Hall, C.R. ( 5 ) 147 Haltiwanger, R.C. ( 4 ) 41, 53, 58; ( 9 ) 162, 164 Hamblin, M.R. (6) 253 Hamill, R.L. ( 6 ) 11 Hammond, P . J . ( 2 ) 48 Hampton, A. ( 6 ) 1 2 , 62-64 Han, C.-Q. ( 7 ) 114 Han, F.-S. ( 6 ) 173 Hanack, M. ( 7 ) 152 Hanafusa, T. ( 9 ) 46 Hanawalt, E.M. ( 1 ) 228; ( 7 ) 55 Hanaya, T. ( 5 ) 66 Hanecker, E. ( 1 ) 171; ( 4 ) 108 Hanna, A . G . (5) 49; ( 9 ) 84 Hanna, M.M. ( 6 ) 91 Hanna, M.T. ( 1 ) 220, 221 Hansen, D.E. ( 6 ) 79 Hansen, H.F. ( 5 ) 140 Hanski, E. ( 6 ) 6 Harada, F. ( 6 ) 311 Harger, M.J.P. ( 5 ) 155157 Haris, G.S. ( 9 ) 234 Harmon, R.E. ( 7 ) 143 Harnett, S.P. ( 6 ) 77, 78 Harris, D.H. ( 1 ) 387; ( 8 ) 131, 135, 136 Harris, G. ( 6 ) 94 Harris, R.K. ( 9 ) 58 Harris, T.M. ( 6 ) 256 Harris, T.V. ( 1 ) 71 Harrison, A.W. ( 7 ) 155 Harrowfield, J . M . ( 1 ) 39 Harshman, K.D. ( 6 ) 334 Hartley, J . A . ( 6 ) 255 Hartmann, B. (6) 395 Hartmann, G.R. ( 6 ) 237
433
Author Index Hartwick, R . A . ( 6 ) 385, 387
Haseltine, W . A .
( 6 ) 259,
262, 329
Hashimoto, H. ( 7 ) 37 Hashimoto, Y. ( 6 ) 49 Hassall, C.H. ( 5 ) 104 Hassan, F.S.M. ( 1 ) 116 Hassan, M.E. ( 6 ) 19 Hassanein, M. (1) 193, 240
Hasung, 0. ( 9 ) 81 Hata, T. ( 6 ) 29, 95, 1 1113, 128, 165
Hattori, K . ( 6 ) 58 Haubenstock, H. ( 1 ) 88 Haubold, R. ( 1 ) 131 Hausen. H.-D. (1) 68 Hayakawa, Y . ( 4 ) ' 8 5 ; ( 6 ) 108
Hayashi, H. ( 6 ) 397 Hayashi, Y. ( 6 ) 49 Hayatsu, H. ( 6 ) 214, 215, 297
Haydock, K. ( 6 ) 348 Hayes, J . E . ( 1 ) 228; ( 7 ) 55 Hayes, R.C. ( 6 ) 265 Heathcock, C.H. ( 7 ) 158 Heberhold, M. (1) 133 Hecht, S.M. ( 6 ) 323, 324, 335
Hedberg, K. ( 9 ) 226 Hedden, D. ( 1 ) 70 Hegarty, A . F . ,(1) 251255; ( 8 ) 2
Heikkila, J. ( 6 ) 129 Heine, H.W. ( 1 ) 127 Heine, .J. ( 2 ) 41, 42; ( 5 ) 6 Heiner, C.R. ( 6 ) 153, 299 Heinicke, J. (1) 375 He'lzne, C . ( 6 ) 161, 178 Helioui, M. ( 8 ) 146 Helle, M . A . ( 7 ) 82 Helmchen, G. ( 7 ) 145 Hendry, P. ( 5 ) 24 Hennen, W . J . (1) 100; ( 4 ) 29
Henner, W.D. ( 6 ) 329 Henrie, R.N. ( 6 ) 201 Herberhold, M. ( 9 ) 187 Herbst, R. ( 8 ) 137 Herdering, W. ( 4 ) 89; ( 6 ) 37
Hergenrother, W.L. ( 8 ) 150 Herman, T. ( 6 ) 223 Hernandez, P.E. ( 7 ) 123 Herr, R. ( 1 ) 115, 198; ( 9 ) 169
Herr; W. (6) 307
Herring, A.M. ( 1 ) 117 Herrmann, E. ( 4 ) 31; ( 8 ) 149; ( 9 ) 8 0
Herrmann, R. ( 8 ) 20 Herrndorf, M. ( 1 ) 257 Hertzberg, R.P. ( 6 ) 335 Hess, H. ( 9 ) 199 Heubach, G. ( 1 ) 190 Heubel, J . ( 8 ) 44 Hewson, A.T. ( 7 ) 157 Heydt, H. ( 3 ) 24. 26; ( 4 ) 99
Hibbert, R . C . ( 9 ) 77 Hibino, S. ( 5 ) 152 Hietkamp, S. ( 1 ) 1 2 , 6 9 , 121; ( 4 ) 4 3
Higashizaki, S. ( 9 ) 243 Higgins, S.J. ( 1 ) 116,
209
Holt, M.S. (1) 367 Holtzclaw, J . R . ( 9 ) 237 Holwitt, E. ( 6 ) 266 Holy, A . ( 6 ) 23, 24 Holzapfel, W. ( 7 ) 8 9 Honjo, M . ( 6 ) 25 Honnens, J. ( 4 ) 40 Honrath, U. ( 1 ) 153 Hood, L.E. ( 6 ) 299, 300 Hopkins-Davis, T. ( 6 ) 221 Hoppe, I . ( 5 ) 100 Hoppe, J . ( 6 ) 65 Hopton, D. ( 5 ) 112; ( 9 ) 23
Horn, T. ( 6 ) 105, 152 Horner, L. ( 5 ) 145; ( 9 ) 141
117
Horvath, S . J . ( 6 ) 280 Horwitz, S.B. ( 6 ) 328 Higuchi, M. ( 8 ) 165 Hoskins, B.F. ( 9 ) 208 Higuchi, S. ( 6 ) 112 Higuchi, T. (1) 263, 274, Hosoda, A. ( 7 ) 103 275 Hosseini, H.E. (1) 277 Hostomsky, 2. (6) 103 Hill, T.G. ( 4 ) 4 1 , 53; Hotoda, H. ( 6 ) 112 ( 9 ) 164 Hiller, W. (1) 75; ( 9 ) 57 Houkom, E. ( 6 ) 223 Hountondji, C. ( 6 ) 233 Himes, R . H . ( 6 ) 8 4 , 240 Hindman, J . C . ( 7 ) 154 Houriet, R. ( 3 ) 1 7 ; ( 9 ) 246 Hingerty, B.E. ( 6 ) 288 Hinke, A. (1) 264 Hovnanian, N. ( 1 ) 123 Hinke, A.M. ( 1 ) 264 Howard, F.B. ( 6 ) 192 Hirakawa, M. ( 8 ) 184 Howell, J.A.S. ( 1 ) 81 Hiraksuka, 1. ( 5 ) 151 Hoyer, D. (1) 8 4 Hirao, I. ( 1 ) 205; ( 5 ) Hoyer, P.B. ( 6 ) 71 Hsu, A . ( 6 ) 220 130; ( 7 ) 8 8 , 94 Hirao, T. ( 5 ) 50; ( 7 ) 84 Hsu, C.Y.J. (6) 162 Hiremath, S.P. ( 6 ) 61 HSU, S.-H. ( 6 ) 387 Hirooka, S. ( 7 ) 148 Huang, Y . ( 7 ) 27 Hirotsu, K . ( 1 ) 263, 274, Huber, B. ( 1 ) 310, 356 275 Huber, R. ( 5 ) 103; ( 9 ) 9 8 Hitchcock, P.B. ( 1 ) 329, Hubert-Pfalzgraf, L.G. 364
Hixson, S.S. ( 6 ) 275, 276 Hnilica, L.S. ( 6 ) 296 Hobbs, J . B . ( 6 ) 106 Hockensmith, J.W. ( 6 ) 293 Hodge, P. (1) 86 Hodgson, M. (1) 239 Hock, N. ( 1 ) 50 Honle, W. ( 1 ) 25, 264 Hoeve, V . ( 8 ) 125 Hoffmann, R.W. ( 7 ) 90 Hofmann, F. ( 6 ) 53 Hofmockel, U. ( 1 ) 287 Hogan, M.E. ( 6 ) 310 Hogarth, G. ( 1 ) 122 Holloway, S.J. ( 7 ) 135 Holmes, J.M. ( 1 ) 303, 304; ( 9 ) 153 Holmes, R . R . ( 1 ) 303, 304: ( 9 ) 153 Holt,'E..M: ( 5 ) 1 4 ; ( 9 )
( 1 ) 123
Hubner, T. ( 1 ) 186; ( 9 ) 187
Hudson, H.R. ( 4 ) 8 Hughes, L.R. ( 7 ) 87 Hughes, P. ( 6 ) 299 Hullin, R. ( 6 ) 53 Humayun, M.Z. ( 6 ) 257 Hundhammer, B. (1) 244 Hunerbein, J . ( 9 ) 158 Hung, S.C. (1) 1 5 Hunsaker, W.R. (6) 204 Hunt, J.E. (7) 154 Hunting, D.J. ( 6 ) 29 Huque, T. ( 6 ) 6 Hurley, L.H. ( 6 ) 335 Hurst, R.R. ( 9 ) 72 Hursthouse, M.B. ( 8 ) 37 ; ( 9 ) 1 7 9 , 218
Husebye, S. ( 3 ) 1 5 ; 172
9)
434 228 Ionkin, A.S. ( 9 ) 94 I o t o , K. ( 9 ) 3 I s a a c s , N.S. ( 1 ) 222; ( 7 ) 24 I s a e v a , G.M. (1) 52 I s a g u l y a n t s , M.G. ( 6 ) 315 Isenbeg, G. ( 6 ) 239 I s h i d a , M. ( 1 ) 238 I s h i h a r a , T. ( 5 ) 123 I s h i i , K . ( 5 ) 46 Ishmaeva, E.A. (1) 320 Ismaev, I.E. ( 9 ) 8 3 I s s l e i b , K. ( 1 ) 29, 31, Ibrahim, E.H.M. ( 8 ) 35 40, 283; ( 4 ) 13, 1 7 , 34, 42; ( 5 ) 52, 60; ( 9 ) I d e , H. ( 6 ) 263 I g l o i , G.L. ( 6 ) 226 64 I t a i , A. ( 9 ) 183 I g n a t ' e v , N.V. ( 2 ) 17 I t o , T. ( 4 ) 75; ( 6 ) 33, I g n a t ' e v , Yu.A. ( 9 ) 109 I g n a t o v , M.E. ( 8 ) 118; 119 Ivanov, B.E. ( 1 ) 191 ( 9 ) 245 Ivanova, E.M. ( 6 ) 170; I g o l e n , J. ( 6 ) 148, 381 I i o , H. ( 7 ) 36 ( 9 ) 41 Ivanova, N.A. (8) 130; Ikeda, S. ( 6 ) 219 I k e h a r a , M. ( 4 ) 77 ( 9 ) 232 I k e h a r a , M. ( 6 ) 30, 36, Ivanova, N.L. ( 4 ) 68 120, 133, 134, 210 Ivanovskaya, M.G. ( 6 ) 159, 315 Iksanova, S.V. ( 4 ) 109 I v e s , D.H. ( 6 ) 219 I l ' i c h e v , S.A. ( 9 ) 192 I v i n , B.A. (5) 136; ( 9 ) I l ' i n , E.G. ( 8 ) 118; ( 9 ) 245 140 I l ' i n a , M.B. ( 8 ) 174, 175 Iwai, S. ( 6 ) 121 I w a m i , H . ( 6 ) 40 I l ' y a s o v , A.V. ( 1 ) 380; Iwata, T. (1) 238 ( 9 ) 83, 90, 109, 174 I m a i , J. ( 4 ) 91; ( 6 ) 182, I z a n t , J . G . ( 6 ) 179 184 Imai, K. ( 4 ) 75; ( 5 ) 70; Jackson, R.F.W. ( 7 ) 127 ( 6 ) 33 J a c k s t i e s , W. ( 1 ) 72 Imai, S. ( 9 ) 20 Jacob, K. ( 9 ) 261 Imamoto, T . (1) 58, 59; Jacobsen, G.B. ( 1 ) 116, ( 3 ) 18, 19 117 Imbach, J.-L. ( 6 ) 144, Jacobsen, J . S . ( 6 ) 257 145 Jacobson, K.B. ( 6 ) 386 Immenkeppel, M. ( 1 ) 282 Jacobson, M.K. ( 6 ) 100 Imura, A. ( 6 ) 142 J a e g e r , D.A. ( 1 ) 223, I n a g a k i , K. ( 6 ) 365 Inamoto, N. (1) 263, 274, 236, 237; ( 9 ) 251 J a e n i c k e , L. ( 7 ) 146 275, 313; ( 5 ) 76; ( 7 ) Jagendorf, A.T. ( 6 ) 230 71; ( 8 ) 48; ( 9 ) 3 J a i n , V.K. ( 9 ) 208 I n c h , T.D. ( 5 ) 147 Jakubowski, H. ( 6 ) 101 Indzhikyan, M.G. ( 1 ) 82 Jamali, H.A.R. ( 4 ) 23 I n g o l d , K.U. ( 9 ) 113 Jarnil, Z. ( 1 ) 177 Inoguchi, Y. ( 9 ) 183 J a n i c e k , M.F. ( 6 ) 329 Inokawa, S. ( 4 ) 96; (5) J a n o u t , V. ( 8 ) 157 66, 132 J a n s e n , W. ( 5 ) 111 Inoue, H. ( 6 ) 121, 142 Inoue, T. ( 6 ) 188 J a n s s e n , R.A.J. (9) 114 Inoue, Y. ( 7 ) 37 J a n s z , H.S. ( 6 ) 354 Inouye, Y. ( 5 ) 152 J a r o r i , G.K. ( 6 ) 356 Inskeep, P.B. ( 6 ) 256 J a r r e l l , K.A. ( 6 ) 341 J a s i n s k i , J. (5) 14; ( 9 ) I o n i n , B . I . ( 1 ) 151; ( 2 ) 209 46; ( 5 ) 2 , 48, 75; ( 9 )
Hussong, R . ( 3 ) 24; ( 4 ) 99 Hutchins, R.O. ( 3 ) 12; ( 9 ) 43 Hutchinson, D.W. ( 5 ) 119, 121; ( 9 ) 238; ( 6 ) 102 H u t t n e r , G. ( 1 ) 262, 269, 270, 345, 346 Hutton, A.T. ( 5 ) 45 Huynh-Dinh, T. ( 6 ) 148, 381 Hyver, K . J . ( 6 ) 6 3
Organophosphorus Chemistry J a s t o r f f , B. ( 6 ) 52, 53, 56, 57, 400 Jaw, J.Y. ( 7 ) 49 J e a n n i n , Y . ( 1 ) 16; ( 9 ) 73 Jemmis, E.D. ( 9 ) 11 J e n c k , J. ( 1 ) 112-114 J e n k i n s , B.G. ( 6 ) 377 J e n k i n s , I . D . ( 1 ) 109; ( 2 ) 36 J e r n s t e d t , K.K. (5) 11 J i b r i l , I. ( 1 ) 345 J i n g , X. ( 9 ) 119 J i n g l i n , Z. ( 1 ) 383 Jb'rg, K . ( 1 ) 310, 349, 350 Joergensen, P. ( 5 ) 142 John, A. ( 9 ) 80 Johns, R.B. ( 5 ) 12 Johnson, D.L. ( 6 ) 286 Johnson, K.A. ( 6 ) 201 Johnson, L.D. ( 6 ) 261 Johnson, N.P. ( 6 ) 361 Johnson, P.D. ( 7 ) 155; ( 9 ) 130 J o n e s , P.G. ( 8 ) 51 J o n e s , R.A. ( 1 ) 259; ( 6 ) 126, 135, 162, 383 J o n e s , T.R. ( 7 ) 115 J o v i n , T.M. ( 6 ) 196 J u a r i s t i , E. ( 3 ) 1 2 , 13, 41; ( 9 ) 43, 176 Judek, M. ( 6 ) 274 Juneau, M.K. ( 8 ) 153 Juodka, B.A. ( 6 ) 41 J u s t , G. ( 5 ) 117 Kabachnik, M . I . ( 5 ) 8 4 , 135; (9) 184, 250 Kabachnik, M.M. (1) 1 3 , 1 4 , 179; ( 2 ) 49; ( 4 ) 1 9 , 51, 52; ( 5 ) 107 Kabbani, A. ( 5 ) 148 Kachkovskaya, L.S. ( 1 ) 297; ( 9 ) 31 Kada, R. ( 8 ) 12 Kadyrov, R.A. ( 9 ) 135, 136 K a f a r s k i , P. ( 5 ) 98; ( 9 ) 267 Kaga, K. (1) 238 Kagan, H.B. ( 1 ) 110; ( 9 ) 59 Kagawa, Y. ( 6 ) 245 Kaim, W. ( 9 ) 116 Kaiser, K. ( 6 ) 138 Kaiser, M. ( 5 ) 49 Kaiser, N.F. ( 6 ) 153 Kaiser, R . J . ( 6 ) 299 Kajiwara, M. ( 8 ) 102, 182 Kakadii, L . I . ( 5 ) 116
435
Author Index Kakiuchi , H . ( 1 ) 194 Kakuchi, J . ( 6 ) 311 Kalasinsky, V.F. ( 1 ) 330 Kalbitzer, H . R . ( 6 ) 373 Kal'chenko, V.I. ( 2 ) 61, 62; ( 9 ) 53, 54, 6 6 , 71 Kalinichenko, E.N. (6) 185 Kalisch, B.W. ( 6 ) 196 Kallmerten, J . ( 3 ) 33 Kalman, A . ( 6 ) 44 Kamber, M . ( 5 ) 117 Kamimura, ' 7 . ( 6 ) 95 Kamishiro, J . ( 6 ) 40 Kanemasa, S. ( 7 ) 93 Kanjolia, R.K. ( 1 ) 208 Kant, M. ( 2 ) 60 Kao, S.-C. ( 6 ) 194 Kapetanovic, E. ( 6 ) 228 Kaplan, B.E. ( 6 ) 150 Kappler, F. ( 6 ) 12, 62-64 Kapur, O.P. ( 9 ) 265 Karaghiosoff, K. ( 1 ) 358, 377; ( 4 ) 104; ( 9 ) 152, 182 Karas, M. ( 9 ) 86 Kardinov, N . A . ( 9 ) 184 Karelov, A . A . ( 4 ) 71 Kargin, Yu.M. ( 9 ) 109, 233 Karkas, J.D. (6) 16 Karnik, S.S. ( 6 ) 155 Karpova, G . G . ( 6 ) 250 Karpova, R . D . ( 1 ) 143 Karsch, H.H. ( 1 ) 43-45, 305, 310; ( 7 ) 11 Karthikeyan, S. ( 8 ) 90 Karuppiah, N . ( 6 ) 48 Kashemirov, B.A. ( 5 ) 77, 116; ( 8 ) 19 Kashiwabara, K. (1) 27 Kashman, Y. (1) 169; (5) 89 Kaslina, N . A . ( 5 ) 96, 9 7 , 135; ( 9 ) 253 Kasukhin, L.F. ( 8 ) 9 Katahira, M. (6) 397 Katerinopoulos, H. ( 7 ) 118 Kato, H . ( 4 ) 8 5 ; (6) 108 Kato, M. (1) 168; ( 3 ) 8 Kato, S. ( 1 ) 238 Kato, T. ( 7 ) 148 Katti, K.V. ( 8 ) 103, 116, 137 Katz, J . J . ( 7 ) 154 Kaub, J . (1) 335 Kauffmann, T. ( 1 ) 3 ; ( 3 ) 2 , 3 , 25 Kawakami, N . ( 6 ) 40 Kawamoto, H . ( 5 ) 66 Kawanobe, W . ( 4 ) 67
Kawashima, T. (5) 76; ( 7 ) 71 Kay, P.B. ( 2 ) 14; ( 5 ) 20; ( 9 ) 4 7 , 4 8 , 55 Kazankova, M . A . ( 1 ) 148, 149 Kazimierzcuk, 2. ( 6 ) 46 Kean, J.M. ( 6 ) 336 Keana, J.F.W. ( 5 ) 1 1 Keat, R . ( 8 ) 66 Keglevich, G. ( 1 ) 173 Kehne, A . ( 4 ) 8 9 ; ( 6 ) 38, 136 Keitel, 1. (5) 84 Kelbanskii, E.O. ( 1 ) 331 Keller, H. ( 1 ) 319; ( 3 ) 21 Keller, K. ( 7 ) 8 Kellogg, R . M . ( 1 ) 3 0 ; ( 5 ) 114 Kelly, J.W. (1) 9 5 , 9 6 ; ( 2 ) 20-22; ( 6 ) 366 Kelly, T..J. ( 6 ) 222 Kemp, R . A . ( 1 ) 353, 354; ( 4 ) 1 , 106; ( 9 ) 190 Kennedy, D . A . ( 9 ) 173 Kent, D.E. ( 5 ) 80 Kent, J . R . (6) 343 Kent, S.B.H. ( 6 ) 299 Kerby, M.C. (1) 155 Kern, C.W. ( 3 ) 17; ( 9 ) 246 Kernan, P . A . (6) 11 Kesbeke, E. (6) 57 Kessenikh, A.V. ( 5 ) 9 6 , 9 7 , 135; ( 9 ) 253 Kezdy, F . J . ( 6 ) 173 Khafizova, G.S. ( 2 ) 52 Khailova, N . A . ( 1 ) 182 Khairullin, V.K. ( 1 ) 182 Khalil, F.Y. ( 1 ) 220, 221 Khammatova, Z.M. ( 9 ) 8 3 Khan, N.N. ( 6 ) 66 Khardin, A.P. ( 1 ) 76 Kharitonov, V.G. (1) 204 Kharitonov, Yu.Yu. ( 9 ) 122 Khbeis, S.G. ( 9 ) 196 Khokhlov, P.S. ( 1 ) 144; ( 5 ) 1 3 , 77, 116; (8) 19 Khorana, H.G. (6) 155 Khropov, Yu.V. (6: 232 Khusainova, N . G . ( 5 ) 125; ( 8 ) 132 Khusnutdinova, E.K. ( 2 ) 52 Kibardina, L.K. ( 4 ) 56 Kibrik, G.E. ( 9 ) 7r3 Kidani, Y . ( 6 ) 365 Kiefer, G.E. ( 7 ) 8 5 Kiekel. C. (. 8,) 168 Kierzek, R. ( 4 ) 8 3 . 8 4 ;
( 6 ) 123, 124, 130, 166 Kilkurkie, R.E. ( 6 ) 323, 324 Kim, C.H. ( 8 ) 113 Kim, D.Y. (5) 61 Kim, T.V. ( 9 ) 203, 212 Kim, U.Y. ( 8 ) 113 King, C. 5 ) 85; ( 9 ) 100 King, C.M ( 6 ) 286 King, R . B (1) 6 3 ; ( 4 ) 32 Kingston, E.E. (6) 43 Kini, G.D (1) 100; ( 4 ) 29 Kinochita M. ( 5 ) 105 Kirby, A . . ( 5 ) 31 Kireyev, V.V. ( 9 ) 219 Kirfel, A . ( 8 ) 49; ( 9 ) 180 Kirilov, M. (7) 76, 77 Kirzow, K.H. ( 1 ) 303 Kischkel, H . (1) 159; ( 2 ) 27 Kise, H. ( 7 ) 6 3 Kiseleva, E.I. ( 9 ) 203, 212 Kishi, Y. (7) 73 Kisilenko, A . A . ( 4 ) 69 Kitane, S. (5) 42 Kiuchel, P.W. ( 6 ) 384 Kjaer, A . ( 7 ) 159 Kjaer, D. ( 7 ) 159 Klaebe, A. ( 5 ) 21 Klebanskii, E.O. ( 4 ) 1 0 2 , 109, 110; ( 8 ) 24 Klehr, H. ( 1 ) 377; ( 4 ) 104 Kleiner, H . J . ( 1 ) 145 Klirnentova, G.Yu. ( 1 ) 224; ( 4 ) 1 0 , 47 Klingebiel, U. ( 1 ) 158 Klochkov, V.V. ( 9 ) 9 2 , 136 Klose, G. (9) 9 6 Kaosin'ski, P. ( 4 ) 1 1 2 Klug, A . ( 6 ) 353 Kluger, R . ( 2 ) 3 2 , 3 3 ; ( 5 ) 26, 27 Klysik, J. (6) 267 Knachel, H. ( 7 ) 70 Kneip, H.-G. ( 1 ) 199; ( 7 ) 35 Knierzinger, A. (5) 103; ( 9 ) 98 Knight, W.B. ( 5 ) 3 4 , 35 Knoch, F. (1) 271, 273, 299, 306-309, 312, 315317; ( 7 ) 6 ; ( 9 ) 6 2 , 151, 1 5 8 , 165 Knorre, D.G. ( 6 ) 114, 131, 249, 282, 283 Knouzi. N. ( 1 ) 106 Knowles, J . R . ( 5 ) 28; ( 6 ) 1
,
Organophosphorus Chemistry
436 79 Knox, S.A.R. ( 1 ) 120, 122 Kobayashi, H. ( 1 ) 168; (3) 8; ( 6 ) 109 Kobayashi, M. ( 4 ) 96 Kobayashi, T. ( 1 ) 385; ( 4 ) 21 Kobayashi, Y. ( 6 ) 134; ( 7 ) 103 Kobayshi, K. ( 7 ) 52 Kober, R. ( 5 ) 102 Kobori, J . A . ( 6 ) 300 Koch, E.M. ( 6 ) 313 Kochergina, L.A. ( 5 ) 135; ( 9 ) 253 K ochervi nski i , V.V. (8) 169 Kockkanyan, R.O. ( 9 ) 91 Kodama, M. ( 7 ) 130 Koenig, M. ( 1 ) 265, 266; ( 4 ) 111 K oes sel , H. ( 6 ) 226 Kotz, J . ( 4 ) 13; ( 5 ) 52 Koga, N. ( 6 ) 256 Kogan, V.A. (8) 130; ( 9 ) 232 Kogoh, K. ( 9 ) 271 Koh, J.J. (1) 42 Kohn, K.W. ( 6 ) 255 Koidan, G.N. ( 1 ) 209, 232; ( 8 ) 31, 32, 46 Kojima, M. ( 8 ) 166, 167 Koketsu, J. ( 1 ) 126 K o l a t a , G.B. ( 6 ) 4 K o l l e r , B. ( 6 ) 224 Kolodyazhnyi, 0.1. ( 1 ) 281; ( 9 ) 29, 159 K o l o t i l o , N . V . ( 1 ) 301; (8) 130; ( 9 ) 27, 232 Komarov, E.V. ( 5 ) 2 Komarov, V.Ya. ( 9 ) 228 Komarova, N . I . ( 6 ) 250 Komina, T.V. ( 1 ) 224; ( 4 ) 10, 47 Konareva, I.E. ( 9 ) 65 Konarska, M.M. ( 6 ) 340 Kondo, M. ( 9 ) 60 Kondo, S. ( 4 ) 75; ( 6 ) 33 Kondo, Y. ( 9 ) 257 Konovalova, I . V . ( 2 ) 52 KOO, H.-S. ( 6 ) 391 Koole, L.H. ( 2 ) 16; ( 6 ) 371, 372; ( 9 ) 67 Kopola, N. ( 5 ) 40 Kopp, D.W. ( 4 ) 84; ( 6 ) 166 Kopylov, V.M. (8) 160; ( 9 ) 219 Koreeda, M. ( 7 ) 38 Korkin, A.A. (9) 8 Kormachev, V.V. ( 1 ) 141143
Kornilov, M.U. (9) 5 3 Kornuta, P.P. (8) 130; ( 9 ) 232 Ko r o b e i n i c h e r a , I . K . ( 9 ) 41 Koroleva, T . I . ( 9 ) 6 5 Korsakov, M.V. ( 5 ) 136; ( 9 ) 140 Korshak, V.V. (8) 9 1 , 9 4 , 1 7 4 , 175 Korshin, E.E. ( 4 ) 6 1 , 62; (5) 88 Korshunov, R.L. ( 1 ) 382; (8) 132 Kos, A . J . ( 7 ) 1; ( 9 ) 1 6 Kosacheva, E.M. ( 1 ) 191 Koshdel, E. ( 1 ) 8 6 Koslov, I . A . ( 6 ) 244 Ko st e r , H. ( 4 ) 9 0 K o s t i n , V.P. ( 4 ) 71, 72 Kosykh, V.G. ( 6 ) 317 Kottmann, H. ( 4 ) 1 4 ; ( 5 ) 56 Ko t t wi t z , B. ( 1 ) 152 Kovacs, J. ( 1 ) 104; (8) 1 1 , 12 Kovenya, V.A. ( 8 ) 36 Kovyazin, V.A. (8) 160; ( 9 ) 219 Kow, Y.K. ( 6 ) 263 Kowalski, J. ( 3 ) 1; ( 4 ) 22; ( 9 ) 191 Koyano, K . ( 1 ) 54 Kozarich, J . W . ( 6 ) 325, 326 Ko z i a r a , A . ( 5 ) 41 Kozlov, E.S. ( 8 ) 190 Kozlowski, S.A. ( 6 ) 135 Kraemer, R. ( 1 ) 341; ( 3 ) 22; ( 5 ) 92; ( 9 ) 8 6 K r a f f t , G.A. (1) 234; ( 4 ) 27 Krannich, L.K. ( 1 ) 208 K r a s i l ' n i k o v a , E.A. (5) 53 Krasnova, T.L. ( 1 ) 146; ( 9 ) 161 Kraszewski, A . ( 6 ) 140 K r a t z e r , R.H. ( 1 ) 387; (8) 1 3 1 , 135, 136 Kraus, M.A. (8) 181, 185 Krause, D. ( 6 ) 184 Krauss, G. ( 6 ) 303 Krauss, J . H . ( 6 ) 275 Krawczyk, E. ( 2 ) 31 Krebs, B. ( 1 ) 287, 318; ( 8 ) 22; ( 9 ) 189 Krech, F. (1) 31 K r e i d e r , D.G. ( 9 ) 39 K r e i s z , S. ( 7 ) 50 Kren, R.M. ( 1 ) 8 9 Kr e u t n e r , W. ( 7 ) 117
K r is c h , H.M. ( 6 ) 178 Krishnamurthy, M.N. ( 9 ) 265 Krishnamurthy, S.S. (8) 7 0 , 80, 9 0 , 9 2 , 9 3 , 103, 116, 117 Krishnan, V. ( 9 ) 106 K r i z , M. ( 8 ) 12 Krokhina, S.S. ( 1 ) 191 Kroto, H.W. (1) 277 Krueger, W.E. ( 9 ) 193 Kruger, C. ( 1 ) 1 2 ; ( 4 ) 4 3 Krugh, T.R. ( 6 ) 285 Krupnov, V.K. ( 2 ) 47 Krupoder, S.A. ( 9 ) 40 K r u tik o v , V . I . ( 9 ) 254, 275 Krynetskaya, N.F. ( 6 ) 158 Krzyzosiak, W . J . ( 6 ) 274 Ku, L . ( 6 ) 105 Kubareva, E.A. ( 6 ) 316 Kubasek, W.L. ( 6 ) 293 Kubiniok, S. ( 1 ) 102 K u b li, E. ( 6 ) 308 Kuchen, W. (1) 152, 264 Kudelska, W. ( 5 ) 36 Kudryavtsev, A.A. ( 5 ) 1 7 ; ( 8 ) 43 Kiickelhaus, W. (1) 156; ( 9 ) 185 Kuehne, U. ( 1 ) 31 Kuendgen, U. ( 9 ) 151 Kuge, 0. ( 6 ) 297 Kuhn, N. ( 1 ) 207; ( 3 ) 2 7 , 44 Kuhn, W. ( 2 ) 42; ( 6 ) 373 Kukhar, V.P. (1) 281; (8) 9 ; ( 9 ) 2 9 , 128, 159 Kukhareva, T.S. (1) 147; ( 5 ) 82 Kulak, T.I. ( 6 ) 185 K u lie v , A.A. ( 4 ) 5 6 , 5 7 , 59, 60 K u lie v , A . K . ( 1 ) 161, 162 K u lk a r n i, P.S. ( 9 ) 239 Kumar, C.V. ( 6 ) 366 Kumar, K.R. ( 1 ) 177 Kumar, V.T.R. ( 7 ) 83 Kume, A. ( 6 ) 29 Kumobayashi, H. (1) 54 Kunz, E. (7). 145 Kunz, H. ( 1 ) 235 Kunze, U. ( 9 ) 57 Kupprat, G. (1) 3 5 , 36 Kurchenko, L.P. (8) 100, 114 Kurku, A . ( 5 ) 148 Kurochkin, V.V. ( 4 ) 5 4 Kuroda, S. ( 7 ) 148, 149 Kusabayashi, S. ( 9 ) 257 Kusmierek, J.I. ( 6 ) 213 Kusumoto, T. (1) 58, 5 9 ;
A ut hor Index (3) 1 8 , 19 K u t i a v i n , I . V . ( 6 ) 284 K u t u e v , A . A . (1) 77 K u t y r e v , G.A. ( 5 ) 1 4 9 K u t z k e , U. ( 6 ) 50 K u y l - Y e h e s k i e l y , E. ( 4 ) 80; ( 6 ) 2 7 , 4 1 Kuzmenko, 1.1. ( 8 ) 56 K u z n e t s o v , A . V . ( 6 ) 231 Kvasyuk, E . I . ( 6 ) 185 Kwiatkowski, M. ( 6 ) 118 Kwon, S . ( 8 ) 1 5 8 Kyba, E.P. (1) 1 5 5 K y l e r , K.S. ( 7 ) 116 Kyogoku, Y. ( 6 ) 1 3 4 K y u n t s e l , I . A . ( 9 ) 70 L a a k s o n e n , M. ( 6 ) 290 Laane, J. ( 9 ) 121 L a b a r r e , J.-F. ( 8 ) 6 0 , 6 7 , 88, 8 9 , 195 L a b a u d i n i e r e , L. ( 7 ) 60 L a b e l l e , M. ( 6 ) 351 L a c o s t e , A.-Marie ( 5 ) 93 L a F a i l l e , L. ( 8 ) 89 L a f e r , E.M. ( 6 ) 220 L a h a n a , R . (8) 6 7 , 88 L a i , K . (5) 2 5 L a i , R . ( 7 ) 65 L a i g l e , A. ( 6 ) 395 L a i n g , E.M. ( 6 ) 18 L a j o i e , G. ( 5 ) 1 4 3 Lamba, D. ( 9 ) 206 L a m b e r t , P.H. (1) 1 0 7 L a m b e r t , R.W. ( 5 ) 1 0 4 L a m b e r t s , H.B. ( 8 ) 81 L a n c e t , D. ( 6 ) 6 L a n d g r a f , W. ( 6 ) 53 L a n e , D . J . ( 6 ) 301 Lang, H. ( 1 ) 3 4 5 , 346 L a n g e r , W. ( 7 ) 4 5 L a n g e r b e i n s , K. (1) 33 L a n g l o i s , Y. ( 7 ) 1 3 4 L a n g r i c k , C.R. ( 1 ) 10, 2 8 Lanoux, S . ( 8 ) 115 t a p i e n i s , G. ( 4 ) 112 L a p p e r t , M.F. ( 1 ) 39 L a r i n , Z. ( 6 ) 322 L a r s e n , C. ( 5 ) 69 L a r s e n , R. ( 9 ) 1 6 7 L a r s s o n , A . ( 6 ) 15 L a s c h , J.G. (1) 3 5 4 ; ( 4 ) 1 0 6 ; ( 9 ) 190 L a s k o r i n , B.I. ( 9 ) 245 L a s s o t a , P. ( 6 ) 4 6 L a t s c h a , H.P. (1) 1 7 0 ; (2) 8 L a t y p o v a , V.Z. ( 9 ) 2 3 3 L a u , P.T. ( 1 ) 9 Laude, B. ( 5 ) 42 L a u r e n c e , C. ( 9 ) 1 2 6
437 L a v i n , K.D. (1) 118; ( 8 ) 109, 159 L a v r e n t ' e v , A . N . ( 9 ) 254 , 275 Lawessf.n, S.-0. ( 5 ) 91, 140-142, 1 4 4 ; ( 9 ) 188 L a z i u s , A . G . ( 6 ) 339 Lebedev, A . V . ( 6 ) 1 5 1 , 283 Lebedev, N . N . (5) 3 ; ( 9 ) 276 Le B i g o t , Y . (7) 2 5 L e b l a n c , Y. ( 7 ) 1 2 0 L e b l e u , B. ( 6 ) 1 8 7 L e C l e r c , .J.E. ( 6 ) 265 L e c l e r c q , P.A. ( 9 ) 262 Le C o r r e , M. ( 7 ) 4 1 L e d e r e r , F. ( 6 ) 2 3 3 L e e , B.L. ( 6 ) 1 3 4 L e e , C.S. ( 6 ) 83 L e e , D.-C. ( 8 ) 1 4 2 , 1 4 3 L e e , J.Y. ( 1 ) 5 3 , 5 6 , 57 L e e , M.H. ( 6 ) 8 7 L e e , M.-S. ( 6 ) 286 L e e , M.Y.W.T. ( 6 ) 6 7 L e e , Y.M. ( 6 ) 242 L e f e u v r e , M. ( 7 ) 4 7 Le F l o c ' h , Y . ( 7 ) 47 L e g e r , S. ( 7 ) 1 1 5 l e G o f f i c , F. (5) 93 Lehmann, H.A. ( 1 ) 2 3 3 ; ( 8 ) 149 ( 1 ) '28 Lehn, J.-M. L e i b f r i t z , D. ( 6 ) 400 L e i c h t l i n g , B.H. ( 6 ) 4 2 L e i s s r i n g , E . (9) 6 4 L e j c z a k , B. ( 5 ) 9 8 ; ( 9 ) 267 L e k s u n k i n , V . A . ( 5 ) 159, 1 6 0 ; ( 8 ) 39, 4 0 L e l i e v e l d , P. ( 8 ) 81 Lemarchand, A . ( 6 ) 1 4 8 Lemoine, P. ( 1 ) 3 7 4 L e m p e r e u r , L. ( 6 ) 305 Leng, M. ( 6 ) 3 7 8 , 395 l e N o b l e , W . ( 5 ) 30 L e n z , G. ( 1 ) 316 L e o n a r d , N . J . ( 6 ) 61 Leonov, A.A. ( 9 ) 2 2 8 Lequan, M. ( 1 ) 2 1 4 ; (9) 168 Lequan, R.M. ( 1 ) 2 1 4 ; ( 9 ) 168 L e r c h , C. (8) 5 L e r n e r , L. ( 6 ) 3 7 0 L e r o u x , Y. ( 2 ) 28-30, 4 5 ; ( 4 ) 15, 16; 7) 1 7 , 18 Leserman, L.D. ( 6 ) 1 8 7 L e s i a k , K. ( 4 ) 9 1 ; ( 6 ) 182-184 L e t s i n g e r , R.L ( 6 ) 1 6 9 Leupin, W. (6) 376; ( 9 )
72 L e u t l o f f , R. ( 4 ) 1 3 ; (5) 52 Le Van, D. (1) 2 6 8 , 2782 8 0 ; ( 9 ) 35, 2 3 6 L e v i n , B.V. ( 8 ) 118 L e v i n , D. (3) 30 L e v i n , M.L. (8) 7 4 ; ( 9 ) 218 L e v i n , Ya.A. ( 9 ) 95, 102 L e v i n a , A.S. ( 6 ) 1 7 0 Lewin, R . ( 6 ) 3 4 0 L e w i s , E.S. ( 9 ) 249 Lewy, M . ( 5 ) 4 4 ; ( 9 ) 210 Ley, S.V. ( 7 ) 3 4 , 1 2 4 Leykam, J . F . ( 9 ) 2 6 8 L i , B.-L. ( 1 ) 295, 296 L i , H.M. ( 8 ) 78, 145, 147, 148 L i , L.B. ( 8 ) 2 5 L i , W. ( 4 ) 9 7 L i , Y.S. ( 9 ) 227 L i , Z. ( 5 ) 5 4 , 86 L i c a n d r o , E. ( 7 ) 53, 5 4 L i e t j e , S . ( 5 ) 59; ( 7 ) 7 5 L i l l e y , D . M . J . ( 6 ) 306,
39 1 Limn, W. ( 6 ) 1 9 2 L i n , R.-J. ( 6 ) 341 L i n , Y . ( 7 ) 61 L i n b e r g , L.F. ( 8 ) 8 4 L i n c o l n , J. ( 9 ) 105 L i n d h a r d t , P. ( 5 ) 1 4 2 L i n d n e r , E. ( 1 ) 6 2 , 73-75 L i n e s , C.T. ( 5 ) 3 9 ; ( 9 ) 216 L i o r b e r , B.G. ( 9 ) 83 L i o u , R . (6) 16 Lipman, R. ( 6 ) 330 Lippard, S.J. (6) 362 L i s t v a n , V . N . ( 1 ) 196, 197 L i t i n a s , K.E. ( 7 ) 4 4 L i t t l e , T.S. ( 9 ) 133 L i t v i n e n k o , L.M. ( 8 ) 100, 114 L i t v i n o v , I . A . (1) 380; ( 9 ) 150, 1 7 4 , 2 1 5 , 224 L i t v i n o v , V.M. ( 8 ) 1 6 1 , 164 L i u , S. ( 1 ) 153 L i u , X. ( 6 ) 1 3 2 L i u , Z. ( 3 ) 2 3 L i v a n t s o v , M.V. ( 4 ) 11, 35; ( 5 ) 6 2 Liverton, N.J. (7) 126 L l o y d , J . R . (1) 9 9 ; ( 2 ) 4 8 ; ( 4 ) 2 6 ; ( 5 ) 113 Lobana, T.S. (1) 9 7 Lobanov, O.P. (1) 2 0 3 L o c h s c h m i d t , S. ( 1 ) 2 1 0 , 356-359; (9) 1 5 5 , 1 8 2
Organophosphorus Chemistry
438 Logan, N. ( 9 ) 77 Logunov, A.P. ( 9 ) 178 Loomis, R.E. ( 6 ) 191 Lopez, F. ( 1 ) 386; ( 3 ) 42; ( 8 ) 45
Lopez, L. ( 1 ) 378; ( 4 ) 101
Lbpez-NGzez, N.A.
( 3 ) 12;
( 9 ) $3
Lopusinski, A. ( 4 ) 28; ( 5 ) 15
Lora, S. ( 8 ) 171-173 Loreau, N . ( 6 ) 178 Losilkina, V . I . (1) 2 Lough, J. ( 6 ) 223 Lowe, G. ( 5 ) 33; ( 6 ) 7578, 80; ( 9 ) 51
Lown, J.W. ( 6 ) 144 Lowther, N. ( 1 ) 99; ( 2 ) 23; ( 4 ) 26
Lu, S.-B. ( 7 ) 32 Ludeman, S.M. ( 5 ) 46 Luders, H. ( 7 ) 138 Ludwig, E.G. ( 1 ) 135 Lugtenburg, J. ( 7 ) 102 Lukanov, L.K. ( 5 ) 18 Lukanyuk, S.S. ( 9 ) 91 Lum, G.S. ( 8 ) 147, 148 Luss, H.R. ( 1 ) 55; ( 3 ) 9 ; ( 9 ) 156
Lusztyk, J. ( 9 ) 113 Lutke, H. ( 7 ) 57 Lutsenko, A . I . ( 2 ) 49 Lutsenko, I.F. (1) 1 3 , 148, 149, 179, 184; ( 2 ) 49; ( 4 ) 11, 19, 25, 35, 45; ( 5 ) 62, 107; ( 8 ) 27 Lygin, A.V. ( 5 ) 149 Lygo, B. ( 7 ) 34 Lyu, H.S. ( 8 ) 101
Maartmann-Moe, K. ( 3 ) 15; ( 7 ) 10
Maas, G. (1) 319; ( 3 ) 21; ( 7 ) 8 ; ( 9 ) 196 McBride, L.J. ( 6 ) 123 McCabe, D.J. ( 5 ) 115 Maccioni, A.M. ( 8 ) 69 McClelland, R.A. ( 2 ) 3840; ( 9 ) 252 McConnell, D.J. ( 6 ) 366 McCourt, D.W. ( 9 ) 268 McDowell, R.S. ( 2 ) 12; ( 9 ) 19 McElroy, A.B. ( 3 ) 31 McEwan, W.E. ( 2 ) 26; ( 7 ) 20-22 McGall, G.H. ( 2 ) 38-40; ( 9 ) 252 McGarvey, G.J. ( 7 ) 108 McGee, D.P.C. (6) 1 4
McGinn, M.A. ( 1 ) 251, 253, 254; ( 8 ) 2 Maciej, T.W. (5) 120; ( 7 ) 98 McIntosh, L.P. ( 6 ) 196 Mack, H. ( 7 ) 152 McKechnie, J.S. ( 9 ) 234 Mackenzie, P.B. ( 1 ) 17 MacKinnon, I . A . (1) 39 McLaughlin, L.W. ( 6 ) 127, 387 Macomber, R.S. ( 5 ) 124 McPherson, D.T. ( 7 ) 157 Macpherson, K . A . ( 1 ) 122 Macquet, J.P. ( 6 ) 361 Maeda, T. ( 7 ) 131 Markl, G. (1) 128, 323325; ( 9 ) 157 Maerkl, R. (1) 272 Magdeeva, R.K. ( 5 ) 64, 65; ( 9 ) 195 Magdesieva, N.N. (1) 202 Magill, J.H. ( 8 ) 166-168 Magnusson, E. ( 9 ) 63, 242 Mahh, M.J. (1) 329 Mahoun, A. ( 8 ) 67, 88 Mahran, M.R. ( 2 ) 35 Maier, L. (5) 95 Maigrot, N. ( 1 ) 16; ( 9 ) 74 Maiorana, S. ( 7 ) 54 Majewski, M. ( 9 ) 255 Majewski, P. ( 3 ) 11 Majoral, J.-P. (1) 132, 337; ( 4 ) 9 ; ( 8 ) 1 6 , 30; ( 9 ) 52, 217 Makaranets, B.I. ( 9 ) 192 Makhmudov, M.K. ( 5 ) 109; ( 9 ) 200 Maki, R.G. ( 7 ) 92 Makovetskii, Yu.P. ( 1 ) 243 Makowka, B. (1) 32, 33 Malakhova, I.G. ( 1 ) 14 Malamas, M.S. ( 7 ) 131 Malarova, M.A. ( 9 ) 215 Malavaud, C. ( 1 ) 378; ( 4 ) 110 Malecha, M. ( 6 ) 154 Malenko, D.M. ( 4 ) 63; ( 5 ) 71, 87 Malik, L. ( 9 ) 86 Malisch, W. ( 1 ) 172, 287, 310, 349, 350 Malkovskaya, T.H. ( 9 ) 253 Malone, J.F. ( 9 ) 173 Malovik, V.V. (1) 142 Mal'tseva, T.V. ( 9 ) 41 Mamzurin, B.V. ( 5 ) 3; ( 9 ) 276 Manaev, S.V. ( 6 ) 284 Manami, H. ( 7 ) 130
Mangiaracina, P. ( 7 ) 117 Maniatis, T. ( 6 ) 322 Manna, S. ( 7 ) 122 Manninen, P.A. ( 9 ) 241 Manohar, H. ( 8 ) 80 Manolson, M.F. ( 6 ) 248 Manuel, G. ( 1 ) 337 Marchenko, A.P. (1) 209, 232; ( 5 ) 17; ( 8 ) 31, 32, 34, 36, 43, 46 Marecek, J.F. ( 5 ) 30; ( 9 ) 210 Marinetti, A. ( 1 ) 342, 344, 361, 363; ( 3 ) 6 , 7; ( 9 ) 34 Marino, G. ( 6 ) 388 Markiewicz, W.T. ( 6 ) 124 Markova, L. ( 9 ) 87 Markovskaya, T.A. ( 5 ) 9 6 , 97 Markovskii, L.N. (1) 297, 298, 300-302, 331, 334; ( 2 ) 61, 62; ( 4 ) 18, 38, 102, 109, 110; ( 8 ) 24, 47, 54; ( 9 ) 27, 28, 31, 53, 54, 6 6 , 71, 201 Marler, D.O. ( 7 ) 70 Marlier, J.F. ( 6 ) 201 Marmetova, G.R. ( 9 ) 263 Marques, E.C. (1) 49 Marre-Mazieres, M.R. ( 8 ) 6 , 1 7 , 18, 21; ( 9 ) 15 Marsh, T.L. ( 6 ) 349 Marsh, Y.V. ( 6 ) 186 Marshall, J.H. ( 7 ) 74; ( 8 ) 65; ( 9 ) 118 Martin, C.R. ( 9 ) 262 Martin, D.R. ( 1 ) 94 Martin, F.H. ( 6 ) 147 Martin, J.C. ( 2 ) 4 ; ( 6 ) 14 Martin, M.R. ( 9 ) 181 Martin, R. (5) 7 8 Martin, R.P. (1) 93 Martin, S.J. ( 5 ) 122 Martinez, F. (8) 76 Martucci, I. ( 7 ) 151 Marugg, J.E. (1) 180; ( 4 ) 40, 65, 78, 80, 82; ( 6 ) 26, 27, 172 Maruthamuthu, P. ( 9 ) 117 Maruyama, T. ( 6 ) 25 Marx, J.L. ( 6 ) 379 Maryanoff, B.E. ( 2 ) 24, 25; ( 7 ) 23 Marynick, D.S. ( 8 ) 7 ; (9) 79 Marzilli, L.G. ( 6 ) 360, 376 Mas, R.H. ( 8 ) 115 Masafumi, Y. ( 6 ) 245 Masamune, S. ( 7 ) 80, 109
439
Author Index MascareEas, J.L. ( 3 ) 40 Mashchenko, N . V . ( 1 ) 1 3 ; ( 4 ) 19; ( 5 ) 107 Mashima, K. ( 1 ) 54
Maslennikova, V.I. ( 5 ) 64, 65; ( 9 ) 195
Masojidkova, M. ( 6 ) 24 Masse, G. (5) 68 Massoud, S . S . ( 6 ) 359 Mastalerz, P. ( 5 ) 94, 9 8 ; ( 9 ) 267
Mastryukova, T.A. ( 9 ) 250 Masuda, N . ( 6 ) 128 Masui, M. ( 1 ) 124 Masuko, T. ( 8 ) 141 Mateev, I . S . ( 9 ) 25 Mathey, F. ( 1 ) 16, 292, 342-344, 359-364, 366, 368, 372, 374; ( 3 ) 6 , 7 ; ( 9 ) 34, 73, 74 Mathieu, S . ( 1 ) 341; ( 3 ) 22 Mathis, F. ( 5 ) 129; ( 8 ) 67 Mathis, R. ( 5 ) 129; ( 8 ) 67 Matkovskaya, T.A. ( 9 ) 248 Matsuda, H. ( 1 ) 125; ( 3 ) 45 Matsugi, J. ( 6 ) 120, 210 Matsumura, N . ( 7 ) 85 Matsuura, T. ( 6 ) 294 Matsuzaki, J.-i. ( 6 ) 111, 112 Matsuzawa, S. ( 8 ) 165 Mattes, W.3. ( 6 ) 255 Matteucci, M.D. ( 4 ) 79 ; ( 6 ) 2 8 , 281 Matthes, K.E. (1) 28 Matthews, T.R. ( 6 ) 14 Matus, B. ( 6 ) 48 Matveeva, E.V. (1) 76 Matveicheva, G.P. ( 1 ) 146; ( 9 ) 161 Mauer, K.H. ( 6 ) 400 Maurizi, M.R. ( 6 ) 69 Mavarez, E.O. ( 9 ) 217 Maximova, T.G. ( 6 ) 237 Mayer, H.A. (1) 74 Mayer, R . ( 6 ) 163 Mayers, A.I. ( 1 ) 84 Mayo, S.L. ( 8 ) 65; ( 9 ) 118 Mayol, L. ( 6 ) 388 Mazalov, L.N. ( 9 ) 149 Mazany, A.M. ( 7 ) 70 Mazard, A.M. ( 6 ) 361 Mazhar, M. ( 2 ) 5 Mazieres, M.R. (1) 332, 333 Meares; C.F. ( 6 ) 327 Mecklenburg, K.L. ( 6 ) 341
Medina, R. ( 8 ) 119 Medinger, L . ( 4 ) 5; ( 5 ) 73
Medved, T.Ya. (5) 84 Meek, D.W. ( 1 ) 4 Meek, J.L. ( 9 ) 270 Meetsma, A . ( 8 ) 192-194 Mehrotra, R.C. ( 9 ) 208 Mehrsheikh-Mohammadi, M.E. ( 5 ) 138; ( 9 ) 18 Mei, G. ( 9 ) 99 Meidine, M.F. ( 1 ) 313, 327
Meier, I.K. ( 7 ) 64 Meille, S.V. ( 8 ) 163 Meine, G. ( 1 ) 291 Meinwald, J. ( 3 ) 39 Meir, C . J . (1) 327 Meister, J.J. ( 8 ) 170 Mejillano, M.R. ( 6 ) 8 4 Melchior, F. ( 1 ) 122 Mel'nichuk, E.A. ( 4 ) 69 Mel'nikov, B.V. ( 9 ) 233 Mendz, G.L. ( 6 ) 384 Menzel, J. ( 1 ) 273, 299; ( 9 ) 151
Mercier, F. (1) 360, 372 Merecek, J.F. (5) 44 Merkel, C.M. (1) 9 3 , 94 Merkle, R.D. ( 1 ) '73-75 Merrick, W.C. ( 6 ) 229 Mertes, K.B. ( 6 ) 59 Mertes, M.P. ( 6 ) 59 Merzweiler, K . ( 1 ) 260 Meshcheryakov, N.M. ( 9 ) 245
Messmer, A . ( 1 ) 104; ( 8 ) 11
Metelev, V.G. ( 6 ) 317 Metni, M. ( 9 ) 247 Metzgar, J. ( 7 ) 65 Metzner, P. ( 5 ) 139 Meuwly, R. ( 4 ) 12; ( 9 ) 205
Meyer, A. ( 1 ) 349, 350 Meyers, E.A. ( 9 ) 172 Meyers, R.E. ( 8 ) 8 5 , 8 6 Meznik, L. ( 1 ) 233; (8) 149
Michaeli, D. ( 6 ) 163 Michalska, M. ( 5 ) 36 Michalski, J . ( 1 ) 157; ( 4 ) 64
Michalski, T.J. ( 7 ) 154 Michejda, C . J . ( 1 ) 108 Michels, M. (1) 22, 138;
Mikailov, V.V. ( 9 ) 240, 263
Mikhailopulo, I .A . ( 6 ) 185
Mikhailov, G.Yu. (1) 148, 149
Mikhailov, Yu.B. ( 1 ) 163, 164; ( 4 ) 56
Mikityuk, A.D. ( 5 ) 77; ( 8 ) 19
Milavetz, B. ( 6 ) 221 Milburn, R.M. ( 6 ) 359 Miles, H.T. ( 6 ) 192 Milgrom, Ya.M. ( 6 ) 244 Miller, E .J . ( 9 ) 193 Miller, J.P. ( 6 ) 5 5 , 56 Miller, P.P.J. ( 7 ) 102 Miller, P.S. ( 6 ) 174-176, 180
Milliaresi, E.E. ( 9 ) 125 Milne, C . R . C . ( 1 ) 17 Mimasu, R. ( 7 ) 94 Minami, T . ( 1 ) 205; ( 5 ) 130; ( 7 ) 8 8 , 94 Minasu, R. (5) 130 Minasyan, G.G. (1) 8 2 Mincione, E. ( 7 ) 151 Minore, J . ( 5 ) 30 Minter, S.J. ( 6 ) 344 Minto, F. ( 8 ) 171 Mirilov, M. ( 5 ) 153 Miroschichenko, V.V. ( 8 ) 34, 4 3 ; ( 5 ) 17
Misiura, K . ( 9 ) 214 Misumi, S. ( 9 ) 46 Mitomo, S. ( 7 ) 6 3 Mitrolol'skaya, G.I. (8) 9 4 , 160, 177 Mitrosov, Yu.N. ( 5 ) 47 Mitsunobu, 0. ( 6 ) 40 Miura, K . ( 6 ) 311 Miwa, T. ( 1 ) 168; ( 3 ) 8 Miyama, Y. ( 8 ) 41 Miyamoto, Y. ( 7 ) 130 Miyashiro. H . ( 6 ) 133 Mizrahi, V . ( 6 ) 201 Mizuki, Y. (1) 124 Mizusawa, S. ( 6 ) 302 Mochida, K . ( 9 ) 183 Mochizuki, A . ( 5 ) 151 Modak, A.S. ( 9 ) 239 Modro, T.A. ( 5 ) 45, 154; ( 9 ) 186, 202, 211
Magelin, W. ( 4 ) 1 7 , 3 4 ; ( 5 ) 60
Moeps, A . ( 9 ) 96 Mohammad, A.T. ( 1 ) 217 ( 3 ) 10 Michniewicz, J.J. (6) 207 Mokeeva, V.A. ( 9 ) 70 Miftakov, M.S. ( 7 ) 113 Molineux, I.J. ( 6 ) 335 Miguel Nardillo, A . ( 9 ) Molko, D. ( 6 ) 141 258 Mollow. N.M. ( 5 ) 1 8 Mihart, C. ( 8 ) 64 Momchilova, S.' ( 7 ) 7 6 , 77
Organophosphorus Chemistry
440 Mondal, J.U. (1) 94 Mondeshka, D.M. (9) 87 Monin, E.A. (1) 179; (2) 49; (4) 51, 52 Monius, T. (7) 56, 57 Monkiewicz, J. (7) 26 Montgomery, C.D. (1) 38 Moore, J.M. (6) 355 Moore, M.F. (6) 34 Moors, R. (4) 105 Mootz, D. (9) 185 Moran, T.F. (9) 235 Morand, P. (1) 215, 216, 218; (7) 150 Morel, D. (1) 112-114 Morioka, H. (6) 120, 210 Mormachov, V.V. (5) 47 Morr, M. (6) 57 Morris, P.G. (6) 102 Morschheuser, 0.S. (2) 8 Morton, D.W. (1) 79; (4) 20; ( 8 ) 38 Morton, S. (1) 327 Morvan, F. (6) 144 Moskva, V.V. (1) 161, 162, 188; (4) 56, 57, 59, 60; (8) 129; (9) 134 Moskvin, A.V. (5) 136; (9) 140 Motherwell, W.B. (2) 9 Motoki, S. (1) 376; (5) 150; (7) 52 Mouriiio, A. (3) 40 Moustakis, C.A. (7) 121 Movshovish, D.Ya. (8) 130; (9) 232 Mowbray, J. (6) 102 Moyse, C.D. (6) 43 Miiller, G. (1) 12, 43, 45, 80, 115, 183, 189, 198, 305, 310, 356; (9) 177 Miiller, U. (1) 217 Mueller, W. (6) 388, 389 Mueller, W.B. (8) 179, 180 Muenstedt, R. (8) 55 Mujasaka, T. (5) 152 Mukaiyama, T. (6) 49 Mukhacheva, O.A. (9) 129 Mukhametov, F.S. (4) 61, 62; (5) 88 Mukherjee, S. (6) 242 Mukhtarov, R.L. (9) 120 Mukmenev, E.T. (9) 215 Mukroyannidis, J.A. (3) 20
Mulder, N.H. (8) 81-83 Mullenbach, G.T. (6) 206 Muller, A.J. (4) 30 Muller, E.P. (9) 223
Muller, G . (4) 43; (7) 7, 9, 11; (9) 169 Murakami, A. (6) 174-176 Murakami, K. (8) 140 Murataliev, M.B. (6) 244 Murphy, M.K. (8) 181, 183, 185 Murray, H.H. (7) 70 Murugesan, N. (6) 324 Musin, R.Z. (1) 382 Mustaev, A.A. (6) 237 Myasnikova, L.G.(5) 2 Myers, R.M. (6) 322 Mynott, R. (1) 111 Nader, F.W. (7) 50, 51 Naesman, J.H. (5) 40 Nafikova, A.A. (9) 90 Nagai, N. (1) 124 Nagaoka, H. (7) 73 Nagarajan, K . (9) 81 Nagase, S. (1) 275; (8) 48; (9) 3 Nagase, T. (5) 76; (7) 71 Nair, C.P.R. (8) 87 Nakahama, S. (4) 67 Nakahara, J.H. (1) 387; (8) 131, 135, 136 Nakamura, S. (5) 152 Nakamura, T. (7) 84 Nakane, M. (7) 52 Nakanishi, K. ( 6 ) 330 Nakano, K. (6) 236 Nakashima, T.T. (5) 66 Nakazawa, M. (9) 20 Narain, R.P. (1) 150 Narang, S.A. (6) 207 Narmetova, G.R. (9) 240 Nassal, M. (6) 155 Nassimbeni, L.R. (9) 202, 211 Nath, J.P. (6) 240 Natiello, M.A. (9) 75, 76 Naumov, V.A. (9) 224 Navech, H. (9) 86 Navech, J. (1) 247, 338, 341; (2) 53; (3) 22; (5) 92; (8) 1 Nazarova, G.V. (I) 76 Kedecheva, G . (3) 4 Neenan, T.X. (8) 110, 111, 155 Negareche, M. (9) 115 Negishi. K . (6) 214, 215, 297 Negrebetskii, V.V. (2) 61, 62; (9) 53, 54, 65, 66, 71 Neidlein, R. (1) 185, 186; ( 5 ) 108 Neilson. R.H. (1) 79.
154, 295, 296; (4) 20; (8) 25, 26, 38, 170 Nelson, G.E. (1) 60, 61 Nelson, J.H. (1) 367, 372, 374 Nerstad, G.O. (9) 222 Nesmeyanov, N.A. (1) 204 Nesterov, L.V. (4) 37 Nesterova, L.I. (2) 51; (5) 106; ( 8 ) 134 Neubert, W.J. (6) 313 Neuffer, J. (1) 66; (4) 44 Neumann, J.-M. (6) 381 Neuzil, E. (5) 93 Nevskii, N.N. (1) 7; (4) 39; (5) 65; (9) 163, 195, 213 Nevstad, G.O. (7) 10; (8) 191 Nevzorova, O.L. (5) 53 Newkome, G.R. (7) 85 Newman, A.J. (6) 341 Newman, R.H. (9) 21 Newton, B.H. (1) 39 Newton, R.P. (6) 43 Nguyen, M.T. (1) 251-255; (8) 2 Nichols, G.M. (8) 99 Nicolaides, D.N. (7) 44 Nicolaou, K.C. (3) 38; (7) 118, 123, 128 Nicoletti, F, (9) 270 Nicoloso, M. (6) 305 Niecke, E. (1) 64, 250, 287, 288, 318; (4) 33, 103; (8) 22, 23; (9) 189 Nieger, M. (5) 100 Nieke, E. (9) 146 Nielsen, J. (4) 40, 82 Nielson, P. (9) 138, 139 Niemann, J. (7) 4; (9) 38 Nientiedt, J. (1) 280 Niewiarowski, W. (6) 21, 22 Nifant'ev, E.E. (1) 7, 147; (4) 39, 54, 68; (5) 64, 65, 81 Nifant'ev, E.E. (9) 125, 163, 195 Nikitin, E.V. (9) 109 Nikitina, G.S. (8) 97 Nikitina, T.T. (6) 209 Nikloaeva, L.S. (9) 248 Nikonov, G.N. (9) 94 Nin, 2. (9) 7 Nishimura, S. (6) 302 Nishimura, Y. (6) 112, 397 Nishitani, Y. (7) 109 Nishivama. S. (6) 95
Author Index Ogreid, D. ( 6 ) 5 5 , 56 Ogura, Y. ( 9 ) 60 Oh, D . Y . ( 5 ) 61 Ohashi, M. ( 8 ) 9 5 , 96 Ohashi, 0. ( 1 ) 277 Ohler, E. ( 5 ) 74; ( 7 ) 42 Ohmori, H . ( 1 ) 124 Ohtsuka, E. ( 6 ) 36, 120, 121, 142, 210 Ohuigin, C. ( 6 ) 366 Oikawa, H . ( 5 ) 151 Oishi, H . ( 6 ) 25 Ojima, J. ( 7 ) 148, 149 Okamoto, Y. ( 5 ) 4 Okazaki, H . ( 9 ) 210 Okotrub, A.V. ( 9 ) 149 Okruszek, A . ( 5 ) '37; ( 6 ) 51, 312 Okui, S. ( 9 ) 183 Oleski, P. ( 9 ) 101 Olivares, R.C. ( 8 ) 75 Oliveros, L. (3) 14; ( 9 ) 142 Olsen, C.J. ( 6 ) 301 Olsen, R . K . ( 1 ) 100; ( 4 ) 29 Olson, M . V . ( 6 ) 394 Olthof-Hazekamp, R . (8) 25, 51, 52; ( 5 ) Nowak, M. ( 7 ) 79 194 O'Neill, R.E. ( 6 ) 229 Nowak, S. ( 5 ) 84 Oprian, D.D. ( 6 ) 155 Nowak, T. ( 6 ) 87 Orahovats, A.S. ( 5 ) 128 Noyori, R . ( 1 ) 54 ( 4 85; ( 6 ) 108 Orama, 0. ( I ) 270, 346 Nunomoto, M. ( 7 ) Organ, H.M. ( 7 ) 34 256 Orgel, L.E. ( 6 ) 188, 189 Nurakhmetov, N.N. 37 Orleva, T.D. ( 5 ) 135; ( 9 ) Nuretdinov, I . A . 253 Nuretdinova, O.W. 229, 230 Orpen, A . G . ( 1 ) 122, 348 Osaki, Y. ( 6 ) 95 Oshikawa, T. ( 4 ) 96; ( 5 ) 132 Oakley, R.T. (1) 103; 107, 123; ( 9 ) 220 Osipov, O.A. ( 8 ) 130; ( 9 ) 232 Obendorf, D. (1) 178 Oberster, A . E . ( 8 ) 187 Osipova, T . I . ( 6 ) 96 Obrecht, J.P. ( 5 ) 103; Osman, F.H. ( 2 ) 56 Osowska-Paciewicka, K . ( 9 ) 98 Ocando, E. (1) 132; ( 4 ) ( 5 ) 43 Osswald, M. ( 6 ) 292 9 ; ( 8 ) 30 Ostroukhova, O . K . ( 9 ) 266 O'Connor, D. ( 6 ) 287 O'Sullivan, W.J. ( 6 ) 83 Odinets, I . L . ( 4 ) 25 Odoriso, P.A. ( 5 ) 8 3 Ott, J. ( 6 ) 202, 374; ( 9 ) 51 Oeberg, B. ( 6 ) 15 Oefner, C. (6) 352 Ouahab, L. (1) 214; ( 9 ) Oertel, U. (1) 244 168 Otvos, L. ( 6 ) 45, 200 Ouyang, T. ( 9 ) 119 Ovakimyan, M.Zh. ( 1 ) 82 Ofengand, J. ( 6 ) 277 Offermann, W. ( 2 ) 41, 42 Ovchinnikov, Yu.E. ( 9 ) 219 Ogawa, K . ( 6 ) 25 Ovodova, O.V. ( 9 ) 229, Ogawa, Y. ( 7 ) 139 230 Ogden, R.C. ( 6 ) 280 Ogilvie, K . K . ( 4 ) 8 6 , 8 7 , Ozakaki, H. ( 5 ) 44 92; ( 6 ) 31, 122, 164 Ozaki, K . ( 6 ) 29
Nishizawa, M. ( 6 ) 214 Nitta, M. ( 1 ) 385; ( 4 ) 21; ( 6 ) 297 Niven, M.L. ( 5 ) 45, 154; ( 9 ) 186 Nixon, J.F. (1) 277, 313, 327-329, 364 Noda, I . ( 8 ) 120 Nijtfi,H. ( I ) 72, 171; ( 4 ) 108 Noltemeyer, M. ( 8 ) 51, 52 Nomura, S. ( 1 ) 168; ( 3 ) 8 Noorda, S. ( 5 ) 134; ( 9 ) 144 Nordheim, A . ( 6 ) 306, 378 Norman, A.D. (1) 51; ( 4 ) 41, 46, 53 58; ( 9 ) 164 Norman, N.C. (1) 172, 348, 354; 4 ) 106; ( 9 ) 190 Normanly, J . ( 6 ) 280 Norman, A . D ( 9 ) 162 Nortay, S.O. ( 5 ) 51 Noviello, S. ( 1 ) 87 Novikova, S.P. (8) 174 Novikova, Z.S. ( 1 ) 1 3 ,
441 Pace, B. ( 6 ) 301 Pace, N.R. ( 6 ) 42, 301, 349 Pace, U. ( 6 ) 6 Paciorek, K.J.L. (1) 387; ( 8 ) 131, 135, 136 Packer, K . J . ( 9 ) 58 Paddock, N.L. ( 8 ) 5 9 , 107; ( 9 ) 220 Padgett, R . A . ( 6 ) 340 Padiou, J. (1) 214; ( 9 ) 168 Paillous, N. ( 1 ) 266 Paine, R.T. ( 5 ) 115 Pakulski, M. (1) 339, 347, 348; ( 2 ) 31 Pala, M. ( 8 ) 33 Palacios, F. (1) 386; ( 3 ) 42; ( 8 ) 45 Palaniswamy, V . A . ( 7 ) 8 1 Palecek, E. ( 6 ) 267 Paleologue, A. ( 6 ) 293 Palumbo, G . ( 1 ) 87 Panczek, S. ( 4 ) 112 Paneth, P. ( 5 ) 3 8 ; (9) 50 Pankov, V.I. ( 1 ) 76 Panosyan, G . A . ( 5 ) 131 Panov, A.M. ( 9 ) 131, 148 Papagni, A . ( 7 ) 53, 54 Papkov, V.S. ( 8 ) 161, 164 Paquette, L . A . ( 7 ) 147 Parakin, O.V. (9) 109 Paramonov, V . I . (1) 142 Paranawithana, S.R. ( 6 ) 368 Pardoen, T.A. ( 7 ) 102 Pariza, R . J . ( 1 ) 192 Parkanyi, L. ( 6 ) 44 Parker, D. ( 1 ) 1 0 , 28, 239 Parkes, H.G. ( 8 ) 6 6 ; ( 9 ) 218 Parrott, M.J. (5) 112 Parvez, M. ( 8 ) 109 Pastor, S.D. ( 5 ) 8 3 ; ( 9 ) 6 8 , 69 Pastushenko, E.V. ( 2 ) 4 3 Patel, D . J . ( 6 ) 135 Patel, G. ( 2 ) 39 Patel, P. ( 7 ) 38, 106, 107 Paterson, M.C. ( 6 ) 252, 26 1 Patoprsty, V. ( 9 ) 8 6 Patsanovskii, 1.1. ( 1 ) 320 Pattenden, G. ( 7 ) 106, 107 Paulen, W. ( 1 ) 271; ( 9 ) 62 Pavlov, V.A. ( 9 ) 8 3 Pawelke, G. ( 1 ) 9 0
Organophosphorus Chemistry
442 Payard, M. (1) 265; ( 4 ) 111 Payne, C. ( 6 ) 221 Payne, N.C. ( 1 ) 38 Pearson, J . D . ( 6 ) 8 5 P e c h s i r i , S. ( 1 ) 330 Pedersen, U. ( 5 ) 140, 144 Pedro, J . R . ( 7 ) 153 P e e b l e s , C.L. ( 6 ) 341 Peh, M.-L.N. ( 7 ) 65 P e i s a c h , J . ( 6 ) 328 P e l k a , H. ( 6 ) 279 P e l t i g r e w , F.A. ( 8 ) 147, 148, 151 P e n s a r , G. ( 5 ) 40 Penton, H.R. ( 8 ) 139, 151, 154 Penz, G. ( 5 ) 79 P e r e z , F. ( 7 ) 120 P e r e z , J.J. ( 7 ) 141 P e r i c h , J . W . ( 5 ) 12 P e r i e , J.J. ( 5 ) 21 P e r i n g e r , P. ( 9 ) 223 Perlman, P.S. ( 6 ) 341 P e r r e t , D. ( 3 ) 1 7 ; ( 9 ) 246 P e r r o t t , M . J . ( 9 ) 23 P e r u z z i n i , M. ( 1 ) 365 P e t e r s , G.H. ( 9 ) 133 P e t e r s , H. ( 1 ) 69 P e t e r s , K . ( 1 ) 257 P e t e r s , T . J . ( 6 ) 90 P e t e s , W. (5) 126 P e t r a g i n i , N. ( 9 ) 172 P e t r e d i s , G. ( 6 ) 57 P e t r i e , C.R. ( 6 ) 11 P e t r i l l o , M.L. ( 6 ) 341 P e t r o s y a n , E.R. ( 9 ) 120 P e t r o v , A . A . ( 5 ) 48; ( 9 ) 228 P e t r o v a , I. ( 5 ) 153 P e t r o v a , J. ( 7 ) 76, 77 P e t r o v a , T.M. ( 9 ) 266 P e t r o v s k i i , P.V. ( 1 ) 204 P e t s o n , A. ( 3 ) 1 2 ; ( 9 ) 43 P e t t e r , R. ( 5 ) 23 P e t t e r , W. ( 9 ) 223 P f e i f e r , G.P. ( 6 ) 196 P f e u t z n e r , E. ( 9 ) 80 P f i s t e r - G u i l l o n z o , G. ( 8 ) 6 ; ( 9 ) 5 , 15 P f l e i d e r e r , W. ( 6 ) 13 P h i l l i o n , D.P. ( 5 ) 137 P h i l l i p s , L.R. ( 4 ) 7; ( 6 ) 171 P i a n c a t e l l i , G. ( 5 ) 133 P i c c i a l l i , G. ( 6 ) 388 Pichko, N.P. ( 6 ) 283 Pidcock, A. ( 1 ) 364 Pidwer, M . J . ( 5 ) 99 P i e n t a , N.J. (1) 241 P i e r o t h , M. ( 1 ) 22, 138;
( 3 ) 1 0 ; ( 7 ) 65 P i e t r u s i e w i c z , K.M. ( 7 ) 26 Pinchuk, A.M. ( 1 ) 85, 209, 232; ( 5 ) 17; ( 8 ) 31, 32, 34, 36, 43, 46 Pingoud, A. ( 6 ) 318, 319 P i n k e r t , W. ( 8 ) 52 Pinnavaia, T.J. ( 6 ) 358 P i n t e r , I. (1) 104; ( 8 ) 11 P i n t o , A.L. ( 6 ) 362 P i s t o r i u s , A.M.A. ( 6 ) 125 Pitchumani, K . ( 1 ) 9 8 P l a g a , A. ( 9 ) 269 P l a t e a u , P. ( 6 ) 99 PlGnat, F. ( 1 ) 225, 226; ( 7 ) 14 P l e s s , R.C. ( 6 ) 298 Plyamovatyi, A.Kh. ( 9 ) 137 Pochet, S. ( 6 ) 381 Pochlauer, P. (9) 223 Podkopaeva, T.L. ( 6 ) 185 Podyminogin, M.A. ( 6 ) 284 Poetzsch, M. ( 8 ) 94 P o i r i e r , M. ( 2 ) 5 Polenov, E.A. ( 5 ) 116 Poleshchuk, O.Kh. ( 9 ) 104 P o l e t a e v , A . I . ( 6 ) 97 Polezhaeva, M.A. ( 2 ) 1 Polk, M. ( 1 ) 284, 285, 290 P o l l o k , T. ( 1 ) 37, 198; ( 3 ) 5 ; ( 9 ) 169 Polyachenko, L.K. ( 1 ) 298 Polyak, M.S. ( 5 ) 2 Polyakov, A.Yu. ( 9 ) 70 Polyakova, I . A . ( 5 ) 9 6 , 9 7 , 135; ( 9 ) 253 Polyanchuk, G.V. ( 9 ) 198 Polynova, T.N. ( 9 ) 192 Pomberio, A.J.L. ( 8 ) 20 Pomerantz, M. ( 8 ) 7; ( 9 ) 79 Pompliano, D.L. ( 5 ) 110 Pon, R.T. ( 4 ) 8 6 , 8 7 , 92; ( 6 ) 31, 122, 164 Ponomarchuk, M.P. ( 8 ) 9 P o n s i n e t , G. ( 7 ) 48 Poojany, M.D. ( 8 ) 80 Poole, R . J . ( 6 ) 248 Popoff, S. (6) 364 Popov, B.N. ( 1 ) 76 Popov, I . L . ( 6 ) 185 Popova, I . A . ( 9 ) 122 Porai-Koshits, M.A. (9) 192 P o r z e l , A. ( 9 ) 22 P o r z i o , W. ( 8 ) 163 Posner, G.H. ( 7 ) 32, 33 Poss, M.A. ( 7 ) 125
Potapov, V.K. ( 6 ) 315, 316 P o t t a g e , C. ( 5 ) 147 P o t t e r , B.V.L. ( 6 ) 20, 253; ( 9 ) 51 Pouet, M.-J. ( 5 ) 118; ( 7 ) 72; ( 9 ) 42, 45 Pougeois, R. ( 6 ) 72 Povolotskii, M . I . (1) 297, 300, 302; ( 9 ) 28, 31, 54 Power, J . M . ( 1 ) 339 Powroznyk, L. ( 4 ) 8 P r e i s s , J. ( 6 ) 242 P r e n g l , C. (1) 50 P r e t z e r , W.R. ( 1 ) 71 Prezhdo, V.V. ( 9 ) 231 Prigozhina, M.P. ( 8 ) 91 P r i s b e , E.J. ( 6 ) 14 P r i s b y l l a , M.P. ( 7 ) 140 Prishchenko, A.A. ( 4 ) 11, 35; ( 5 ) 62; ( 9 ) 82 P r i v e t t , J.A.J. ( 1 ) 103 P r o c t o r , G. ( 7 ) 87 Prokof'ev, M.A. ( 6 ) 158 Proskurnina, M.V. ( 2 ) 43; ( 5 ) 62 P r o s s e r , K. ( 4 ) 83 Prouex, P. ( 7 ) 150 Provotorova, N . I . ( 8 ) 175 Pu, J. ( 1 ) 229 P u c k e t t , W.E. . ( 7 ) 85 Pudovik, A.N. ( 1 ) 163, 164, 182; ( 2 ) 52; ( 4 ) 36, 48-50, 56, 71, 72; ( 5 ) 125, 149, 158; ( 8 ) 132; ( 9 ) 90, 109, 233 Pudovik, M.A. ( 1 ) 161164; ( 4 ) 48-50, 5 6 , 57; ( 9 ) 90 P u j o l , L. (1) 267; ( 9 ) 107 Pushkareva, G. ( 9 ) 124 P u s k a r i c , E. ( 8 ) 146 Pyo, H.S. ( 8 ) 101 Quan, C. ( 5 ) 22 Quashie, S. ( 1 ) 287, 288 Q u a s s i n i , A. ( 8 ) 4 4 , 58 Quin, L.D. ( 1 ) 173, 340, 366, 369, 370; ( 4 ) 100; ( 5 ) 113; ( 9 ) 33, 36 Quinn, A.M. ( 7 ) 110 Q u r e s h i , A.R. ( 4 ) 8 Rabinowitz, J.C. ( 6 ) 84 Radeglin, R. (9) 78 Rademacher, P. ( 1 ) 250; ( 4 ) 103; ( 8 ) 23 Raduly, S. ( 8 ) 64
Author Index 117 R a d z i k o w s k i , C. ( 5 ) 98 Reeve, R . N . ( 9 ) 56 R a e v s k i i , O.A. ( 9 ) 132 R e f o l o , L.M. ( 6 ) 257 R a g l i o n e , T.V. ( 6 ) 387 Regan, J . B . ( 5 ) 4 6 R a h a r i n i r i n a , A . ( 1 ) 352 R a h h a l - A r a b i , L. ( 9 ) 279 Regberg, T. ( 4 ) 7 9 , 8 1 ; R a i , A . K . ( 9 ) 208 ( 6 ) 35 R e g i t z , M . ( 1 ) 293, 3 1 9 , R a j a g o p a l a n , K . ( 7 ) 83 3 2 1 , 3 2 2 , 326; ( 3 ) 2 1 , R a j a l a k s h m i , S. ( 9 ) 265 2 4 , 26; ( 4 ) 9 9 ; ( 5 ) 7 8 ; Rajeshwar, K. ( 8 ) 7 ; ( 9 ) ( 7 ) 8 ; ( 9 ) 2 4 , 196 79 Rakhmankulov, D.L. (2) 4 3 R e i c h , W. (1) 349 R e i d , D.G. ( 6 ) 375 Rakov, R . D . ( 6 ) 234 R e i d , T.M. ( 6 ) 286 R a l e i g h , J.A. ( 6 ) 271 R e i l y , M.D. ( 6 ) 360 Ramabrahmam, P. ( 8 ) 117 R e i m s c h u s s e l , W. ( 5 ) 38; Ramachandran, K . (8) 1 2 1 Ramage, R . ( 5 ) 112; ( 9 ) (9) 50 R e i s a c h e r , H.-U. ( 1 ) 3 0 5 , 23 310; ( 7 ) 11 Ramaiah, M. (1) 83 Ramakrishna, J . ( 9 ) 106 R e i s c h e r , R.J. ( 6 ) 1 4 3 Rambaud, M. ( 7 ) 9 1 R e i t z , A . B . (2) 2 4 , 2 5 ; (5) 51; ( 7 ) 23 Ramesh, S. ( 7 ) 1 4 1 R e i z i g , K . ( 1 ) 2 5 8 , 284Ramirez, F. ( 5 ) 3 0 , 4 4 ; 286, 290, 291 ( 9 ) 210 Remizov, A.B. ( 9 ) 134 R a n a i v o n j a t o v o , H . (1) 256; ( 9 ) 154 Remizova, A . A . ( 9 ) 219 Rankin, D.W.H. ( 9 ) 225 Renhof, R . ( 6 ) 209 Ransom, S.C. ( 6 ) 238 R e p i n a , L.A. ( 4 ) 6 3 ; ( 5 ) Rao, A . V . R . ( 7 ) 1 3 3 71, 87 Rao, B.D.N. ( 6 ) 356 R e t t i g , S.J. ( 8 ) 1 0 7 ; ( 9 ) Rao, C . V . N . ( 5 ) 1 4 ; ( 9 ) 220 R e t u e n t , J. ( 8 ) 76 209 R e t u e r t , P . J . ( 9 ) 199 Rao, M.N.S. ( 8 ) 124; ( 9 ) 3 3 , 221 Reuther, W. (1) 195 Rao, V.S. ( 5 ) 1 4 3 Reutov, O.A. (1) 204 R a p h a e l , A.L. ( 6 ) 367 Revankar, G . R . ( 6 ) 11 R a p o p o r t , H. ( 7 ) 1 6 1 R e v e l , M. (1) 338, 3 4 1 ; Rasmussen, P.B. ( 5 ) 1 4 2 , ( 2 ) 53; ( 3 ) 2 2 ; ( 5 ) 92 144 Reye, C. ( 2 ) 6 , 7 R a s t o n , C.L. ( 1 ) 39 Reynolds, C.D. ( 5 ) 39; R a t h g e b e r , G. ( 6 ) 245 ( 9 ) 216 R a t h k e , M . W . ( 7 ) 79 R e y n o l d s , V.L. ( 6 ) 335 Ratovskii, G.V. ( 9 ) 131, Rezumov, A . I . ( 9 ) 134 148 Rezvukhin, A . I . ( 9 ) 40 Ray, B.D. ( 6 ) 356 Rheingold, A . L . ( 8 ) 33; R a y f o r d , R . ( 6 ) 229 (9) 193 R a y n e r , B. ( 6 ) 1 4 4 , 145 R i c c i , A. ( 7 ) 5 8 Razhabov, A . ( 8 ) 13 Ricci, J.S. ( 5 ) 44; ( 9 ) Razumov, A . I . ( 4 ) 4 7 ; ( 9 ) 210 129 R i c h , A. ( 6 ) 220, 378 Rea, P.A. (6) 248 R i c h a r d s o n , J . F . (8) 1 2 4 ; R e b e r , G. (1) 80; ( 7 ) 7 ( 9 ) 221 ( 6 ) 293 Reboud, A.-M. R i c h a r d s o n , S. ( 7 ) 125 Reboud, J . - P . ( 6 ) 293 R i c h t e r , S. ( 4 ) 13; ( 5 ) R e b r o v a , O.A. (1) 204 52 Reckmann, B. ( 6 ) 303 R i c h t e r , W.J. (1) 6 6 , Reddy, C.D. ( 5 ) 1 4 ; ( 9 ) 111, 1 2 9 , 371; ( 4 ) 4 4 ; 209 ( 9 ) 81 Reddy, D.B. ( 9 ) 209 R i c k a r d , C.E.F. ( 1 ) 289 Reddy, E.R. ( 7 ) 133 R i c k e n b e r g , H.V. ( 6 ) 42 Reddy, M.P. ( 6 ) 1 7 5 , 180 R i d e r , P. ( 6 ) 110 Reed, G.H. ( 6 ) 355 R i d i n g , G.H. ( 8 ) 109 R e e s e , C.B. ( 6 ) 1 1 4 , 1 1 6 , R i e d e , J. ( 1 ) 1 1 5 , 1 9 8 ;
443 ( 9 ) 169 R i e d e l , R . (1) 6 8 R i e d e r e r , M. (8) 57 R i e g e r , P.H. ( 1 ) 42 R i e h l , N. ( 6 ) 305 Riemer, M . ( 9 ) 6 4 R i e s e l , L. ( 2 ) 6 0 R i e s n e r , D. ( 6 ) 321 R i e s s , J.G. ( 2 ) 5 8 ; ( 4 ) 3; ( 9 ) 244 R i f f e l , H. ( 1 ) 1 3 0 ; ( 9 ) 199 R i l e y , R.W., ( 8 ) 152 R i n e s , S.P. ( 1 ) 155 R i s e n , W.M. ( 1 ) 42 R i s s a l u , Kh.1. ( 2 ) 46 R i t h n e r , C.D. ( 9 ) 10 R o b e r t , F. (1) 1 6 ; ( 9 ) 7 3 R o b e r t s , A.B. ( 7 ) 100 R o b e r t s , D.M. ( 6 ) 154 R o b e r t s , R.M.G. (1) 3 7 3 R o b e r t s , T.G. ( 3 ) 3 5 R o b i n s , R . K . ( 6 ) 11 R o b i n s o n , G. (6) 384 R o b i n s o n , P.L. ( 1 ) 9 6 ; ( 2 ) 20-22 R o d r i g u e z , L.O. ( 6 ) 324 Roemming, C. ( 9 ) 1 8 8 , 222 Roesch, L. ( 2 ) 44 Rosch, W. (1) 2 9 3 , 3 2 1 , 3 2 6 ; ( 9 ) 2 4 , 30 R o s c h e n t h a l e r , G.-V. (1) 134, 159; ( 2 ) 10, 27, 41, 42; (5) 6 Roesky, H.W. (8) 5 1 , 5 2 , 137 R o g o z i n a , I . N . ( 9 ) 275 Rokach, J. ( 7 ) 120 R o l ' n i k , L.Z. ( 2 ) 4 3 Romakhin, A.S. ( 9 ) 109 Romanenko, V.D. (1) 2 9 7 , 298, 300-302, 3 3 1 , 334; ( 4 ) 38, 1 0 2 , 109, 1 1 0 ; ( 8 ) 24, 47, 54; ( 9 ) 27, 2 8 , 3 1 , 201 Romano, L . J . ( 6 ) 286 Romanov, G . V . ( 9 ) 1 0 9 , 224 Romao, M.J. (1) 1 2 ; ( 4 ) 43 R@mming, C. ( 7 ) 10; (8) 191 R o n j a t , M. ( 6 ) 72 Roobeek, C.F. (3) 4 3 R o p e r , W.R. (1) 289 Rose, H. ( 8 ) 6 6 Roseman, B. ( 6 ) 223 Rosen, B. ( 6 ) 220 Rosen, T. ( 7 ) 1 5 8 R o s e n b e r g , I . ( 6 ) 2 3 , 24 R o s e n d a h l , M. ( 4 ) 83 R o s e n f e l d , P . J . ( 6 ) 222
Organophosphorus Chemistry
444
Rosenthal, A. (6) 103, 317, 318 Ross, C. (9) 97 Ross, L.M. (8) 186 Ross, P. (6) 163 Roundhill, D.M. (1) 70; (5) 85; (9) 100 ROUS, A . J . (5) 29, 32; (6) 74; (9) 51 Roush, W.P. (7) 80 Roy, S. (1) 91, 92 Royo, G. (2) 5 Ruban, A.V. (1) 298; (8) 54 Rudemacher, P. (9) 146 Rudi, A. (1) 169; (5) 89 Rudley, K . (9) 61 Rudolf, H. (9) 177 Rudomino, M.V. (5) 135; (9) 253 Rudyi, R.B. ( 2 ) 61, 62; (9) 54, 66, 71 Riiger, R. (1) 64; (4) 33 Ruelle, P. (1) 254 Ruiz, J.P. (I) 93, 94 Ruland, A. (1) 195 Rumyantseva, Z.G. (8) 118 Rupp, W.D. (6) 364 Ruppel, H. (7) 104 Rusakov, V.A. (8) 97 Rushkina, N.G. (9) 125 Russkamp, P. ( 7 ) 45 Rycroft, D.S. (8) 66 Rycyna, R.e. (6) 260 Ryder, J . M . (9) 273 Sachse, B. (1) 190 Sadanani, N.D. (1) 63; (4) 32 Safonova, T.S. (8) 84 SGgi, J. (6) 200 Sahasrabudhe, S.D. (9) 239 Saindrenan, P. (9) 264 Saito, I. (6) 294 Saito, T. (1) 376; (5) 150; (7) 52 Sakai, K. (1) 124 Sakai, T. (7) 80 Sakhnovskaya, E.B. (1) 161, 162; (4) 57, 59, 60 Saks, V.A. (6) 231 Saksena, A . K . (7) 117 Sakurai, T. (7) 52 Salamanczyk, G. (4) 66; (5) 10 Salbeck, G. (5) 7 2 Salih, S.G. (6) 43 Salisbury, S.A. (6) 375 Salomon, Y. (6) 6
Samaha, M. (5) 148 Samakaev, R.Kh. (9) 248 Samarai, L . I . (8) 14 Sambamurti, K . (6) 257 Samitov, Yu.Yu. (9) 92, 93, 229, 230 Samples, M.S. (9) 39 Samson, C . J . (4) 93; (6) 146 Sancar, A. (6) 364 Sanchez, M. (1) 332, 333; (8) 6, 17, 18, 21; (9) 15 Sanders, J.Z. (6) 299 Sandhu, S.S. (1) 97 Sandstroem, A. (6) 118 Sanford, D.G. (6) 285 Sannia, G. (6) 388 Sargeson, A.M. (5) 24 Sarina, T.V. (9) 27, 28 Sarina-Pidvarko, T.V. (1) 300-302 Sarjudeen, N . (1) 328 Sarkar, A.B. (9) 207 Sarkar, N . (6) 225 Sarukhanov, M.A. (9) 122 Satg;, J. (1) 256, 352; (9) 154 Sato, K . (1) 59; ( 3 ) 19 Sato, R. (7) 59; (8) 41, 42 Sato, Y. ( 6 ) 25 Saundes, J . K . ( 6 ) 252 Sauve, G. ( 5 ) 143 Savel'yanov, V.P. (5) 3; (9) 276 Savenkov, N.F. (1) 144; ( 5 ) 13 Savignac, P. (1) 367; (5) 16, 55, 59; (7) 75, 97 Sawada, M. (9) 46 Sawai, H. (6) 182, 184 Sawaki, H . (4) 91 Sawka-Dobrowolska, W. (9) 191 Sazonova, G . V . (9) 184 Scaillet, S. (5) 45 Schade, G. (7) 56, 57 Schadour, H. (1) 233 Schadow, H. (8) 149 Schafer, A. (1) 257 Schafer, H. (1) 261 Schaefer, H . - J . (6) 245 Schaefer, W. (9) 147 Schaeffer, C.D. (9) 39 Schaeffner, A.R. (6) 237 Schaumloffel, G. (1) 235 Schellenberg, K.A. (6) 268 Scheller, K.H. (6) 357 Schenck, T.G. (1) 1 7 Scherer, O . J . (1) 246,
335, 336 Scherfise, K.D. (9) 171 Scheytt, C. (1) 62 Schiebel, H.M. (6) 399, 400 Schier, A. (1) 189, 198; (7) 9; (9) 169 Schiffer, H. (8) 3; (9) 13
Schipperus, 0. (6) 181 Schleich, T. (6) 193 Schleicher, M. (6) 239 Schlessinger, R.H. (7) 125 Schleyer, P.von R. (7) 1; (9) 11, 16 Schmeusser, M. (1) 350 Schmid, G. (7) 56 Schmidbauer, H. (1) 37, 115, 183, 189, 198; (3) 5; (7) 9; (9) 169, 177 Schmidpeter, A. (1) 18, 166, 167, 210, 303, 304, 356-359, 377; (4) 104; (5) 39; (8) 138; ( 9 ) 26, 152, 153, 155, 160, 182, 216 Schmidt, B.F. (6) 193 Schmidt, H. (1) 40, 283; (4) 42; (7) 132, 136 Schmidt, M.C. (6) 91 Schmidt, M.W. (1) 249 Schmidt, R.R. (7) 160 Schmidt, W. (6) 312 Schmidt, W.M. (9) 1 Schmidt, W.N. (6) 296 Schmiemenz, G.P. (9) 138, 139 Schmoburg, D. (1) 212 Schmutzler, R. (1) 105, 212; (2) 44, 54, 55; (4) 98; (5) 6; (8) 15 Schnabl, G. (9) 261 Schnockel, H. (4) 98 Schobert, R. (7) 29, 30 Schoeller, W.W. (1) 250; (4) 103; (7) 4; (8) 5 , 23; (9) 2, 12, 38, 146 Schoellkopf, U. (5) 100 Schoffstall, A.M. (6) 18 Scholten, P.M. (6) 306 Schomburg, D. (1) 105; (2) 10, 54, 55; (8) 15; (9) 152 Schott, H. (6) 385 Schotten, T. (7) 146 Schouten, J.P. (6) 293, 295 Schow, S.R. (3) 36 Schrader, R. (5) 102 Schram, K.H. (6) 398 Schreiber, G. (6) 313
445
Author Index S c h r y v e r , B.B. (6) 1 8 6 S c h u b e r t , U. ( 1 ) 349 Schuhn, W . ( 1 ) 309 Schulman, L.H. ( 6 ) 279 S c h u l t e n , H.R. ( 6 ) 399 S c h u l t z e , P. ( 6 ) 400 S c h u l z , B.S. ( 6 ) 13 S c h u l z , H. ( 3 ) 2 5 Schumann, H . ( 1 ) 2 0 7 ; (3) 2 7 , 44 Schupp, W. ( 8 ) 4 9 ; ( 9 ) 180 S c h u s t e r , R . ( 9 ) 269 S c h u s t e r , S.M. ( 6 ) 8 6 , 8 9 S c h w a r t z , B.D. ( 9 ) 268 S c h w a r t z , J. ( 7 ) 6 4 S c h w e i z e r , E.E. ( 1 ) 228; ( 7 ) 55 S c h w e i z e r , W.B. ( 3 ) 1 6 ; ( 9 ) 175 S c h w e l l n u s , K . ( 6 ) 318 S c k o l ' n i k o v a , L.M. ( 9 ) 198 S c o t t , T.L. ( 6 ) 73 S e c o n i , G . ( 7 ) 58 S e e b a c h , D. ( 7 ) 127 S e e b e r g e r , M.H. ( 1 ) 259 S e e g a , J. ( 1 ) 156 S e e l a , F. ( 4 ) 8 9 ; ( 6 ) 373 9 , 5 7 , 136-138, 302 S e e l y , F.L. ( 7 ) 8 2 S e e l y , R.J. ( 6 ) 42 S e g e r s , R.P.A.M. ( 4 ) 7 3 ; ( 6 ) 107 S e g u i n e a u , P. ( 7 ) 9 1 S e j p k a , H. (1) 272, 323325
( 9 ) 188 S h a b a r o v a , Z.A. ( 6 ) 1 5 8 , 1 5 9 , 315-317 S h a e f f e r , J. ( 6 ) 268 Shagidullin, R.A. (1) 182; ( 9 ) 135-137 S h a g v a l e e v , F.Sh. ( 4 ) 6 0 S h a i d u l i n , S.A. ( 9 ) 224 Shaikhutdinova, I.T. (1) 77 S h a k i r o v , T.Kh. ( 9 ) 137 Shakya, R.P. (1) 11 Shalamov, E.A. ( 9 ) 178 Shao, K.-L. ( 4 ) 9 3 ; ( 6 ) 146 Shao Yong Wu ( 5 ) 146 S h a p i r o , L. ( 6 ) 1 3 5 S h a p i r o , R . ( 6 ) 288 Sharapov, V . A . ( 1 ) 146; ( 9 ) 161 S h a r i k o v , I.Kh. ( 9 ) 1 3 5 , 136 Sharrna, A . S . ( 7 ) 3 9 S h a r p , P . A . ( 6 ) 340 Shaw, B.L. (1) 1 1 6 , 117 Shaw, J . C . ( 8 ) 121 Shaw, L.S. ( 9 ) 218 Shaw, R.A. ( 8 ) 6 6 ; ( 9 ) 218 Shayban, F. 5 ) 146 Shchelkunova M.A. 9) 129 S h c h u k i n a , L I . ( 2 ) 47 Shebana, R . 5 ) 9 1 Shechenko, I v. ( 9 ) 159 S h e l d r i c k , G M. ( 8 ) 51 , 137
S h e l d r i c k , W s. ( 1 ) 1 8 , S e k i , H. ( 6 ) 40 6 9 , 1 6 6 , 3 3 6 , 358; ( 8 ) S e k i n e , M. ( 6 ) 2 9 , 9 5 , 52, 53; ( 9 ) 155, 160, 111-113, 1 2 8 , 1 6 5 S e l i g e r , H. ( 4 ) 7 0 ; ( 6 ) 182 S h e l n e s s , G.S. ( 6 ) 304 149 S h e n , W. ( 1 ) 229 S e m e n i i , V.Ya. ( 2 ) 1 7 Shen, Y. ( 7 ) 61 Semple, G. ( 5 ) 1 1 9 , 1 2 1 ; Shenoy, S. ( 6 ) 3 2 0 ; ( 9 ) ( 9 ) 238 81 S e n d y u r e v , M.V. ( 1 ) 151 Sherer, O.J. (8) 53 S e n n e t t , M.S. ( 8 ) 144 S h e r m o l o v i c h , Yu.G. ( 4 ) Seno, M. ( 7 ) 6 3 18 Senocq, F. (1) 4 1 Shevchenko, I . V . ( 1 ) 281; Sentemov, V . V . ( 5 ) 5 3 S e r a f i n o w s k a , H.T. ( 6 ) ( 9 ) 29 Shevchuk, M . I . ( 1 ) 200, 117 S e r f o n t e i n , W.J. ( 9 ) 272 201, 219 S h e v e s , M. ( 7 ) 105 S e r i n a , L. ( 6 ) 209 S h i , L. ( 7 ) 27 S e s e k e , U. ( 8 ) 5 1 , 5 2 , S h i b a e v , V.P. (8) 1 6 9 137 S h i b a s a k i , M. ( 7 ) 1 3 9 S e t k i n a , V.N. ( 1 ) 2 S h i b a t a , I . ( 1 ) 125; ( 3 ) S e v e r e n g i z , T. ( 1 ) 102 45 S e v e r i n , E.s. ( 6 ) 232 Seyden-Penne, J. ( 5 ) 118; Shibayarna, K . ( 8 ) 48; ( 9 ) 4 (7) 72; ( 9 ) 42, 45, 8 5 S h a b a n a , R. ( 5 ) 9 1 , 1 4 1 ; S h i b u t a n i , M. ( 7 ) 1 4 8 ,
149 S h i i k i , S. ( 1 ) 194 S h i l o v , S.A. ( 1 ) 1 5 1 Shim, I . W . (1) 42 S h i m i z u , M. ( 5 ) 11 S h i o b a r a , Y. ( 7 ) 130 S h i r a i s h i , M. ( 6 ) 36 S h k l o v e r , V.E. (9) 219 S h o m s h t e i n , Z.A. ( 6 ) 209 S h o r t l e , D. ( 6 ) 203 S h r e e v e , J . M . ( 9 ) 226 S h r i v e r , D.F. ( 8 ) 1 5 5 , 156 S h u g a r , D. ( 6 ) 4 6 S h u l ' g i n , V.F. (1) 3 3 4 ; ( 4 ) 38; ( 8 ) 47, 54; ( 9 ) 201 Shum, F.Y. ( 6 ) 271 Shumeiko, A.E. ( 8 ) 100, 114 Shumyantseva, V . V . ( 6 ) 97 Shvedova, Yu.1. ( 5 ) 48 S i a e o k i , Z. ( 9 ) 191 S i c a r d , G. ( 1 ) 5; ( 4 ) 9 5 ; (7) 16 S i d d a l l , T.L. (1) 234; ( 4 ) 27 S i d d i q u i , M.Z. ( 1 ) 150 S i d k y , M.M. ( 5 ) 7 S i d o r e n k o , E.S. ( 8 ) 174 S i e b e r , H . ( 6 ) 237 S i g e l , H. ( 6 ) 357 Sigman, D.S. ( 6 ) 337 S i h , C.-J. ( 7 ) 114 S i l v e r m a n , R . H . ( 6 ) 184 S i l v e r t o n , J.V. ( 9 ) 214 Simon, Z. ( 8 ) 6 4 Simonnin, M.-P. ( 5 ) 118; ( 7 ) 72; (9) 42, 45, 8 5 Sirnpkins, N.S. ( 7 ) 1 2 8 S i n g e r , B. ( 6 ) 212, 213 S i n g l e r , R.E. ( 8 ) 9 8 , 144 S i n i t s a , A . D . ( 2 ) 50, 5 1 ; ( 4 ) 63; (5) 71, 87, 106; ( 8 ) 28, 29, 134; ( 9 ) 212 S i n i t s y n a , N . I . ( 1 ) 188; (8) 1 2 9 S i n o u , D. ( 1 ) 114 S i n y a s h i n , O.G. ( 4 ) 3 6 , 7 1 , 72 S i p p e l ' , I.Ya. ( 5 ) 1 2 5 S i r o t k i n , K . ( 6 ) 205 S i s k o , J.T. (8) 155 S i s l e r , H. (1) 89 S i u , G. ( 6 ) 300 S j o b e r g , B.-M. ( 6 ) 241 S k a l s k i , B. (6) 380 S k e l t o n , B.W. (1) 3 9 Skone, P.A. ( 6 ) 116 Skopenko, V . V . ( 1 ) 3 3 4 ; ( 4 ) 38; (8) 47; ( 9 ) 201
446 Skowronska, A. (2) 31; ( 5 ) 126 Skrydstrup, T. (7) 159 Skrzypczynski, 2. (4) 64 Skurat, A.V. (6) 232 Sladky, F. (1) 178 Slinimskii, G.L. (8) 164,
Organophosphorus Chemistry Spassky, A. (6) 337 Spassov, S.L. (9) 87 Spears, L.G. (9) 249 Spector, T. (6) 93 Spek, A.L. (8) 192-194 Spengler, S.J. (6) 212,
213
Sperling, W. (7) io4 Slowikowski, D.L. (6) 398 Spiro, T . G . (6) 396 Smaardijk, A.A. (5) 114, Spitz, F.R. (9) 89 Spitz, S . A . (6) 175 134; (9) 144 Smale, T.C. (7) 110, 111 Spitznagel, G.W. (9) 11 Spitzner, D. (7) 43 Smee, D.F. (6) 14 Spivach, J . D . (5) 83 Smegal, J . A . (7) 64 Sporn, M.B. (7) 100 Smerat, G. (7) 89 Sprivzl, M. (6) 196 Smirnova, E . I . (4) 54 Sproat, B.S. (6) 110 Smith, A. (5) 155-157 Sridharan, K.R. (9) 106 Smith, A.B. (3) 36, 37; Srinivasin. C. (1) 98 (7) 126, 131 Srivastava, R.C. (1) 1 Smith, C.C. (6) 180 Srivastava, S. (5) 30; Smith, C . L . (6) 393 Smith, L.M. (6) 299 (6) 247 Stahl, D.A. (6) 301 Smith, R. (6) 17 Stanley, G.C. (1) 49 Smith, S.J. (6) 70 Starke, U. (2) 44 Smorygo, N.A. (5) 136; Starr, P.A. (6) 396 (9) 140 Starzewski, K.A.O. (7) 66 Smrt, J. (6) 103 Stasyuk, A.P. (1) 196, Smurova, E.V. (8) 175 Smythe, M.E. (1) 387; (8) 197 Stawirkki, J. (4) 79, 81; 131, 135, 136 So, K . K . (1) 139, 140 (6) 35 Sobolev, V.G. (5) 75 Stec, W . J . (4) 7, 66; (5) Soderlund, H. (6) 290 10, 19, 37; (6) 22, 51, Sogin, M.L. (6) 301 57, 168, 171; (9) 49, 214 Soifer, G.B. (9) 70 Steger, G. (6) 321 Sokol, O.G. (5) 116 Steglich, W. (5) 102 Sokolov, M.P. (9) 83 Sokol'skaya, I . B . (8) 169 Steiger, T. (9) 78 Solaiman, D. (6) 68 Steinberg, J.J. (6) 269 Solnick, D. (6) 340 Steiner, K . S . (6) 206 Stelten, J. (2) 42 Sologub, L . S . (8) 9 Stelzer, 0. (1) 12, 69, Solomon, J. (6) 269 121; (4) 43 Solov'ev, A.V. (4) 18 Sommer, H. (1) 12, 69, Stepanov, B . I . (9) 65 Stepanov, V.A. (2) 17 121; (4) 43 Stepanova, T.Ya. (9) 224 Sonenberg, N. (6) 350 Songstad, J. (7) 10; (8) Stephen, S . J . (9) 123 Stepowska, H. (1) 108 21, 191; (9) 222 Sonnemans, M.H.W. (9) 114 Stercho, J . P . (3) 12; (9) 43 Sontheimer, G.M. (6) 373 Stevenson, W.H. (2) 4 Sorbi, R.T. (6) 47 Stewart, C.A. (1) 354; Sorenson, O.W. (6) 376;
175
(9) 72
(4) 94, 106; (9) 190
Sorokina, S.F. (1) 7; (4) Stiege, W. (6) 292 Stille, J.K. (1) 67 39; (9) 163 Stoehrer, G. (6) 287 Sosnovsky, D. (6) 195 Sournies, F. (8) 67, 88, Stohrer, W.D. (6) 400 Stollberg, D. (1) 160; 195 Sousa, R. (6) 220 (4) 55 Southgate, R. (7) 110, Stoppioni, P. (1) 365 111 Storch, W. (1) 72, 171; (4) 108 Sowerby, D.B. (2) 3
Storhoff, B.N. (1) 48 Strange, G.A. (7) 124 Strauss, E.C. (6) 300 Streitweiser, A. (2) 12;
(9) 19 Strepikheev, Yu.A. (5)
77; (8) 19 Strijtveen, B. (5) 114 Stritt, H.P. (1) 170 Stromberg, R. (4) 79,
81; (6) 35 Struchkov, Yu.T. (1) 331,
380; (4) 102; (8) 24, 54, 190; (9) 150, 159, 166, 174, 178, 194, 201, 203, 212, 215 Stryer, L. (6) 54, 88 Stubbe, J. (6) 92-94, 325, 326 Sturm, P. (6) 55 Sturtz, G. (4) 5 (5) 68, 73 Stuv;, L. (6) 193 Styruchkov, Yu.T. (9) 219 Subotkowski, W. (5) 94 Subramanian, R. (6) 327 Suck, D. (6) 352 Suda, M. (7) 96 Suga, H. (7) 93 Suggs, J.W. (6) 197, 198 Sugiura, M. (4) 96; (5) 132 Sugiyama, H. (6) 323, 324 Sullivan, J.M. (8) 119 Sulzer, G.M. (8) 152 Sumitomo, H. (7) 130 Summers, M.F. ( 4 ) 93; (6) 146, 376 Suter, B. (6) 308 Sutoh, K. (6) 246 Sutter, M.A. (7) 127 Suva, R.H. (6) 55, 56 Suzuki, H. (5) 57; (7) 99 Suzuki, N. (1) 59; (3) 19 Svara, J. (1) 211, 343, 344; (2) 18; (7) 15 Swaminathan, S. (7) 83 Swamy, K.C.K. (8) 80,92, 93, 117 Swiedan, N . I . (9) 9 Swoboda, H. (7) 43 Symons, M.C.R. (6) 272 Syrneva, L.P. (9) 134 Syvunen, A.-C. (6) 290 Szabo, A.G. (7) 150 Szabolcs, A. (6) 200 Szemzo, A. (6) 200 Szewczyk, J. (1) 340; (4) 100; (5) 113; (9) 33 Taagaard, M. (4) 40, 82
447
Author Index Tabata, S. 5 ) 105 Taber, A.M. ( 1 ) 151 Tabor, J.H. ( 6 ) 341 Taboury, J. ( 6 ) 381 Tabrizi, A . ( 6 ) 206 Tafesse, F. ( 6 ) 359 Taffer, I.M. ( 7 ) 123 Tagaya, M . ( 6 ) 235, 236 Taguchi, T. ( 7 ) 103 Taillandier, E. ( 6 ) 381 Taira, K . ( 2 ) 34; ( 5 ) 25 Takabe, K . ( 7 ) 140 Takacs, J.M. ( 7 ) 82 Takahashi. K. ( 6 ) 58 Takahashi, M. ( 6 ) 40, 214, 215 Takai, Y. ( 9 ) 46 Takaku, H. ( 4 ) 75; ( 5 ) 70; ( 6 ) 33, 109, 119 Takaya, H. ( 1 ) 54 Takemasa, T. ( 7 ) 109 Taketomi, T. (1) 54 Takeyama, T. ( 1 ) 58; ( 3 ) 18 Takigawa, T. ( 7 ) 137 Tamano, M. ( 1 ) 126 Tamas, J . ( 6 ) 402 Tamatsukuri, S. ( 4 ) 77; ( 6 ) 30 Tamm, C. (6) 139 Tamer, T. ( 1 ) 190 Tamura, J.K. ( 6 ) 234 Tanaka, H . ( 1 ) 376; ( 5 ) 150 Tanaka, T. ( 4 ) 77; ( 6 ) 30 Tancheva, Ch. ( 5 ) 127; ( 9 ) 87 Tanielian, O.V. ( 5 ) 148 Tanigami, T. (8) 165 Tanimura, H. ( 6 ) 113 Tanner, N.K. ( 6 ) 342 Tansley, G. ( 6 ) 77, 78 Tarasevich, A.S. ( 9 ) 44 Tarasova, R . I . ( 1 ) 188; (8) 127-129, 134 Tarusova, N.B. ( 6 ) 96 Tashenov, A. ( 9 ) 256 Tashkhodzhaev, B. ( 5 ) 109; ( 9 ) 200 Tashma, 2 . ( 9 ) 197 Tatsuoka, T. ( 3 ) 39 Tautchenko, I. ( 2 ) 57 Taylor, A.J. ( 6 ) 143 Taylor, D.A. ( 6 ) 197, 198 Taylor, E.C. ( 7 ) 112 Taylor, J.W. ( 6 ) 202, 312 Tebby, J . C . ( 4 ) 23, 24; ( 7 ) 19 Teebor, G.W. ( 6 ) 269 ten Hoeve, W. ( 5 ) 5; ( 9 ) 204
Teoule, R . ( 6 ) 140, 141
Terent'eva, S.A. ( 9 ) 90 Tesser, G.I. ( 4 ) 73; ( 6 ) 32, 107, 125, 160 Teulade, M.-P. ( 5 ) 16; ( 7 ) 75, 97 Thatcher, G.R.J. ( 2 ) 32, 33; ( 5 ) 26, 27 Thayer, A.M. ( 9 ) 58 Thiem, J. (7) 138 Thoma, R.J. ( 1 ) 295 Thomas, B. ( 1 ) 233; (8) 149; ( 9 ) 22, 80 Thomas, D.H. ( 8 ) 152 Thomas, M.J. (1) 81 Thompson, A.S. ( 3 ) 36 37 Thompson, M.D. ( 5 ) 14 ( 9 ) 209 Thompson, M.L. ( 4 ) 53 ( 9 ) 164 Thomsen, I. (5) 142, 44 Thornton-Pett, M. ( 1 ) 116 Thorson, M. ( 5 ) 140 Throckmorton, L. (8) 7 ; ( 9 ) 79 Thuong, N.T. ( 6 ) 161, 178, 395 Thyagarajan, G. ( 1 ) 177 Tiekink, E.R.T. ( 9 ) 208 Tikhonova, E.G. ( 8 ) 84 Tilak, B.D. ( 9 ) 239 Tilhard, H.-J. ( 3 ) 25 Tirnmer-Bosscher, H. ( 8 ) 83
Tirnokhin, B.V. ( 2 ) 2 Timpe, H.-J. ( 1 ) 244 Tinoco, I . ( 6 ) 147 Tirakyan, M.R. (5) 131 Titskii, C.D. ( 8 ) 100, 114 Tius, M.A. ( 7 ) 129 Tjaden, U.R. ( 9 ) 262 Tkachev, V . V . ( 9 ) 184 Tocher, J. ( 7 ) 70 Topelmann, W. ( 1 ) 233 Togo, H. (1) 227 Tokoroyamo, T. ( 7 ) 36 Tokumasu, S. (5) 130; ( 7 ) 88, 94 Tollefson, N.M. ( 8 ) 8 Tolman, R.L. ( 6 ) 16 Tolstikov, A.G. ( 7 ) 113 Tolstikov, G.A. ( 7 ) 113 Tomasz, J . ( 6 ) 402 Tomasz, M. (6) 330 Tomaszek, T.A. ( 6 ) 89 Tomita, K. ( 6 ) 25, 133 Tomoi, M. (1) 194 Toomey, N.L. ( 6 ) 67 Topelmann, W. ( 8 ) 149 Topping, R . J . ( 1 ) 370 Tordo. P. ( 1 ) 136, 267: ( 9 ) ' 1 0 7 , -110, 115
Toren, P.C. (6) 401 Torgomyan, A.M. (1) 82 Tornvall, H. ( 6 ) 241 Torreilles, E. ( 1 ) 215, 216, 218 Torrence, P.F. ( 4 ) 9 1 ; ( 6 ) 182-184 Tosing, G. ( 1 ) 156; ( 9 ) 185 Tossi, A . B . ( 6 ) 366 Toth, G . ( 1 ) 104; ( 8 ) 11 Toulade, M.P. (5) 59 Toulmg, J.J. ( 6 ) 178 Toupet, L. ( 1 ) 379 Towner, P. (6) 344 Townsend, L.B. ( 7 ) 144 Toyofuku, M. ( 7 ) 37 Toyota, K . ( 1 ) 274, 275, 313; ( 8 ) 48; ( 9 ) 4 Trahms, L. ( 9 ) 96 Traldi, P. ( 8 ) 61, 69-73 Tran-Dinh, S. ( 6 ) 381 Trifonov, E.N. ( 6 ) 392 Trifonov, L.S. ( 5 ) 128 Trinquier, G . ( 8 ) 4 , 6 3 Trippett, S. ( 2 ) 13-15; ( 5 ) 20; ( 7 ) 8 6 ; ( 9 ) 47, 48, 55 Tromp, M. ( 1 ) 180; ( 4 ) 78, 80; ( 6 ) 26, 27, 172, 181 Trostyanskaya, I.G. ( 1 ) 148, 149 Trotta, F. ( 1 ) 242 Trotter, J . ( 8 ) 107; ( 9 ) 220 Trsic, M. (8) 1 2 2 True, 0. ( 8 ) 122 Trujillo, H. ( 1 ) 48 Truong, T.N. ( 1 ) 248; ( 7 ) 5
Trzcinska-Bancroft,B. ( 7 ) 70 Tsai, E.W. ( 8 ) 7; ( 9 ) 79 Tsao, C.-H., ( 1 ) 1 5 Ts'o, P.O.P. (6) 175, 180 Tsuboi, A . ( 9 ) 243 Tsuboi, M. ( 6 ) 112, 397 Tsuchiya, H. ( 5 ) 70; ( 6 ) . 109 Tsuchiya, S. ( 7 ) 6 3 Tsuda, S. ( 6 ) 311 Tsuge, 0. ( 7 ) 9 3 Tsukamoto, M. ( 7 ) 36 Tsunekawa, K. ( 4 ) 96; ( 5 ) 132 Tsvetkov, E.N. ( 1 ) 1 4 ; (9) 8 Tuck, S.P. ( 5 ) 33; ( 6 ) 75; ( 9 ) 51 Tufano. M.D. ( 7 ) 40 Tullius, T.D. ' ( 6 ) 338
OrganophosphorusChemistry
448 Tundo, P. (1) 242 Tupchienko, S.K. (2) 50; (8) 28, 29
Tur, D.R. (8) 157, 161, 164,. 174, 175 Turpin, P.Y. (6) 395 Turro, N.J. (6) 366 Turski, K. (5) 41 Tuzhikov, 0.1. (1) 76 Tyka, R. (5) 94 Tzschach, A. (1) 375
Ubbink, J.B. (9) 272 Uchiyama, M. (4) 85; (6) 108
Van den Berg, E.M.M. (7) 102
van der Hofstad, W.J.M. (2) 16; (9) 67
van der Huizen, A.A. (8) 81
van der Klein, P.A.M. (6) 41
van der Marel, G.A.. (1) 180; (4) 65, 78, 80; (6) 26, 27, 41, 172, 323
van der Meer-Kalverkamp, A. (8) 81 Van der Veken, B.J. (9) 133
van de Sande, J.H. (6) Ueda, M. (5) 151 Ueda, S. (6) 109; (6) 119 196 van Genderen, M.H.P. (6) Ueda, T. (6) 311 372 Uesugi, S. (6) 133, 134 van Haastert, P.J.M. (6) Uhl, W. (1) 130 57 Uhlmann, E. (4) 76; (6) van Heerikhuizen, H. (6) 157 224 Ulanovsky, L. (6) 392 van Kooyk, R.J.L. (6) Ulses, R. (5) 111 371, 372 Underiner, T.L. (9) 277 Van Leeuwen, P.W.N.M. (3) Underwood, G.R. (6) 288 43 Une, F. (5) 105 van Mansfeld, A.D.M. (6) Urbanke, C. (6) 303 354 Urbauer, J.L. (6) 86 Urdea, M . S . (6) 105, 152 Van Sande, J. (6) 52 Usman, N. (4) 86; (6) 31 van Teeffelen, H.A.A.M. Usmanova, L.N. (4) 48 (6) 354 van Westrenen, J. (6) 181 Uznanski, B. (6) 21, 22, Vapirov, V.V. (8) 100, 168 114
Vakulenko, O.V. (2) 47 Valeeva, T.G. (9) 102 Valentin, A. (2) 11 Valentin, L.H. (2) 11 Valentine, D. (1) 65 Valentini, C. (1) 176 Valenzuela, B.A. (3) 13; (9) 176
Valerio, R.M. (5) 12 Valetdinov, R.K. (1) 76, 77
Valle, L. (3) 13, 41; (9) 176
van Bolhuis, F. (5) 134; (8) 125, 126; (9) 144
van Boom, J.H. (1) 180; (4) 40, 65, 78, 80, 82; (6) 26, 27, 41, 172, 181, 323 van Brunt, J. (6) 150 van de Grampel, J.C. (8) 81-83, 108, 125, 126, 192-195 van de Huizen, A.A. (8) 195
Varbanov, S. (3) 4 Vasella, A. (4) 12; (5) 103; ( 9 ) 98, 205
Vasil'ev, V.P. (2) 46; (5) 135; (9) 253
Vasil'eva, T.V (1) 141143
Vasseur , J.-J. (6) 145 Vasyakina, L.A (1) 188; 29 Vaultier, M. (1) 106, 107 Vdovenko, S.I. ( 9 ) 128 Veale, C.A. ( 7 ) 118 Vebrel, J. (5) 42 Vecchi, E. (8) 61, 69-73 Vecerkova, H. (6) 103 Vedananda, T.R. (7) 137 Veeneman, G.H. (4) 65 Vegh, D. (8) 12 Veiko, V.P. (6) 317 Veits, Yu.A. (1) 184; (4) 45; (5) 159, 160; (8) 27, 39, 40 Venkov, A.P. (5) 18 Venturello, P . (1) 242 Ven'yaminova, A.G. (6) (4) 68; (8)
114
Verdine, G.L. (6) 330 Verheyden, J.P.H. (6) 14 Verjovsky-Almeida, S. (6) 72
Verkade, J.G. (2) 59 Verrier, M. (1) 266 Viala, J. ( 7 ) 121, 122 Vicic, J.C. (8) 187 Victorianio, L. (1) 78 Viersen, F.J. (8) 126 Vignais, P.V. (6) 243 Villafranca, J.J. (6) 81, 82, 238; (9) 51
Villieras, J. ( 7 ) 91 Vinogradov, S.V. (8) 164 Vinogradova, M.N. (6) 317 Vinogradova, S.V. (8) 91, 157, 174, 175
Viscidi, R.P. (6) 289 Visnick, M. (7) 131 Visser, G.M. (6) 41, 181 Vizel', A.O. (2) 47 Vlasov, V.V. (6) 282, 284 Vogel, S. (6) 65 Vogelbacher, U. (9) 24 Vogelbacher, V.-J. (1) 321, 326
Vogt, W. (9) 261 Volkov, V.N. (9) 240 Volter, A. (4) 90 Volz, P. (1) 273 von Allwoerden, U. (1) 134
von der Saal, W. (6) 81, 82; (9) 51
von Hippel, P.H. (6) 293 von Itzstein, M. (1) 109; (2) 36
von Schnering, H.G. (1) 25, 257
Vo-Quang, L. ( 5 ) 93 Vorachek, W.R. (6) 293 Vorob'eva, L.A. (1) 7; (4) 39; (9) 163
Voronkov, M.G. (9) 278 Voropai, L.M. (9) 125 Vougloukas, A.E. (1) 11 Vulfson, E.N. (6) 244 Wada, M. (9) 243 Wakabayashi, T. (6) 246 Walker, B.J. (7) 2, 31, 156; (9) 173
Walker, N.P. (8) 37; (9) 179
Wallace, P. (3) 32 Wallace, S.S. (6) 263 Walter, R. (1) 336; (8) 53
Wamhoff, H. (8) 49; ( 9 )
Author Index 180
Wan, J.K.S. ( 9 ) 113 Wang, A . H . ( 6 ) 378 Wang, Q. ( 6 ) 132 Wang, Y. ( 6 ) 132 Wang, Y.-F. ( 7 ) 114 Wang, Z. ( 9 ) 88 Wani, A.A. ( 6 ) 251 Wannagat, U. ( 8 ) 55 Waring, R.B. ( 6 ) 344 Warner, B.D. ( 6 ) 105 Warren, S. ( 3 ) 28-32, 34 Warrens, C.P. ( 8 ) 37; ( 9 ) 179 Wartell, R.M. ( 6 ) 377 Wassow, H.G. ( 9 ) 185 Watanabe, K . ( 5 ) 57; ( 7 ) 99 Watanabe, T. ( 7 ) 52 Watkins, C.L. ( 1 ) 208 Watt, W. ( 6 ) 173 Watterson, D.M. ( 6 ) 154 Wawer, A. ( 9 ) 274 Wawer, I. ( 9 ) 274 Waykole, L. ( 7 ) 147 Webb, G.A. ( 9 ) 85 Webb, T.R. ( 6 ) 281 Webber, S.E. ( 7 ) 118 Weber, G. (1) 186 Weber, H. (3) 174, 175; ( 4 ) 97 Weber, J . ( 3 ) 17; ( 9 ) 246 Weber, K.L. ( 8 ) 52 Weber, L. (1) 258, 284286, 290, 291; ( 7 ) 6 8 , 69 Weber, W. ( 9 ) 157 Webster, J . (1) 120 Wechter, W.J. ( 6 ) 143 Wedrychowski, A. ( 6 ) 296 Wegener, W. ( 9 ) 143 Weidenbruch, M. (1) 257 Weinberger-Ohana, P. ( 6 ) 163 Weinfeld, M. ( 6 ) 252, 261 Weinhouse, H. ( 6 ) 163 Weintraub, H . ( 6 ) 179 Weis, M. (1) 80; ( 7 ) 7 Weiss, E. (1) 183 Weiss, P.M. ( 5 ) 34, 35 Weiss, W. ( 9 ) 157 Weissman, S.A. ( 1 ) 355; ( 4 ) 107 Weith, H.L. ( 6 ) 401 Welch, C . J . (6) 15, 129 Weller, F. ( 9 ) 171 Wellman, G. ( 7 ) 143 Wells, A.S. (1) 373 Wells, G . J . ( 7 ) 147 Wells, R.D. ( 6 ) 267 Werner, D.E. ( 6 ) 208 Wendisch, D. ( 5 ) 126
449 Wendland, M.F. ( 6 ) 84 Wermuth, U. (1) 105; ( 2 ) 54, 55; ( 8 ) 15 Werntges, H. ( 6 ) 321 Wesseley, H.-J. (1) 130 Westerduin, P. ( 4 ) 65 Westheimer, F.H. ( 6 ) 2 Wewers, D. ( 7 ) 68, 69 Whelan, J. (1) 17 White, A . H . (1) 39 White, H.D. ( 6 ) 70 White, J. ( 7 ) 6 6 , 140 White, S.A. ( 6 ) 336 Whitesides, G.M. ( 5 ) 9 ; ( 6 ) 190 Whitham, G. ( 3 ) 35 Whittle, P . J . ( 2 ) 15 Whittle, R . R . ( 8 ) 8 , 74 Whittlesey, B.R. (1) 259, 354; ( 4 ) 106; ( 9 ) 190 Wickham, G . ( 7 ) 147 Wiechman, B.E. ( 7 ) 95 Wieczorkowski, J . ( 9 ) 211 Wife, R.L. ( 3 ) 43 Wilk, A. ( 9 ) 49 Wilke, G. (1) 111 Will, G. ( 8 ) 49; ( 9 ) 180 Willhalm, A. ( 1 ) 303, 304; ( 9 ) 153 Williams, D.G. ( 6 ) 375 Williams, D.L. ( 6 ) 304 Williams, E.A. (1) 127 Williams, J.M. ( 7 ) 108 Williams, N.E. ( 5 ) 147 Williams, N . R . ( 5 ) 1 Williamson, D. ( 7 ) 150 Willis, C . J . ( 1 ) 38 Willson, M. ( 8 ) 6 7 , 8 9 Wilson, J . R . H . ( 4 ) 6 ; ( 5 ) 63 Wilson, S. (2) 4 Wilson, W.D. ( 6 ) 383 Wilt, J.W. ( 7 ) 40 Wilting, T. ( 8 ) 81 Winkle, S.A. ( 6 ) 387 Winter, H. ( 8 ) 108, 192194 Winzenberg, K . N . ( 3 ) 36 Wirkner, Ch. (1) 40; ( 4 ) 42 Wise, D.S. ( 7 ) 144 Wisian-Neilson, P. ( 8 ) 170 Witke, W. ( 6 ) 239 Witt, M. ( 8 ) 137 Wittman, M.D. ( 3 ) 33 Witzgal, K . ( 7 ) 1, 58 Woerz, H.-J. (1) 170 Woisard, A . ( 6 ) 377, 382 Wolanski, A. ( 6 ) 274 Wolf, R. (1) 332, 333; (8) 17, 18
Wolfenden, R. ( 6 ) 98 Wolfes, H. ( 6 ) 318, 319 Wolfsberger, W. ( 1 ) 47; ( 8 ) 50 Wolmershauser, G. ( 3 ) 44 Wong, C.-H. ( 6 ) 190 Wong, J . K . ( 7 ) 117 Wonnacott, A. ( 7 ) 34 Woods, M. ( 8 ) 90, 103 Woollins, J . D . ( 8 ) 37; ( 9 ) 179 Wozniak, L. ( 3 ) 1; ( 4 ) 22 Wren, B.W. ( 6 ) 272 Wright, G.E. ( 6 ) 6 6 , 67 Wright, T.C. (1) 354; ( 4 ) 106; ( 9 ) 190 Wroblewski, K. ( 9 ) 101 WU, F.Y.-H. ( 6 ) 68 WU, H.-M. ( 6 ) 391 WU, H.-y. ( 6 ) 199 Wu, J . C . ( 6 ) 325, 326 Wuethrich, K . ( 6 ) 376; ( 9 ) 72 Wunderlich, B. (8) 162 Wyatt, J . R . ( 9 ) 237 Wynberg, H. ( 5 ) 5 , 114, 134; ( 9 ) 144, 204 Xin, Y. ( 7 ) 61 Xu, C. ( 6 ) 324 XU, J.-F. ( 6 ) 132 Xu, Y . ( 5 ) 8 6 ; ( 6 ) 132 Yabushita, S. ( 9 ) 6 Yadagiri, P. ( 7 ) 122 Yafina, A . A . ( 9 ) 109 Yagi, M. (1) 54 Yagodin, V.G. ( 9 ) 245 Yagodinets, P . I . (1) 219 Yagupol'skii, L.M. ( 2 ) 17 Yakobi, L.V. ( 6 ) 159 Yakobson, G.G. ( 9 ) 104 Yakout, E.M. ( 5 ) 7 Yakovleva, E.P. ( 5 ) 2 Yakovleva, O.G. ( 9 ) 233 Yakovson, G.G. ( 9 ) 149 Yamaguchi, K . ( 4 ) 67 Yamamoto, H. ( 4 ) 96; (5) 66 Yamamoto, K . (6) 246; ( 7 ) 149 Yamamoto, N. (8) 102 Yamanaka, G. ( 6 ) 54, 88 Yamane, A. (6) 120 Yamasaki, Y. ( 5 ) 123 Yamashita, M. ( 4 ) 96; ( 5 ) 66, 132 Yamashita, Y. ( 6 ) 214 Yamauchi, K . ( 5 ) 105 Yamaura, K. (8) 165
OrganophosphorusChemistry
450 Yamazaki, N. (4) 67 Yang, J. (7) 27 Yang, N.C. (6) 254 Yang, S. (9) 88 Yang, Y. (9) 88 Yang, Y.Y. (8) 123 Yang, Z. (6) 132 Yanovskii, A . I . (9) 178 Yao, F.L. (6) 207 Yaouane, J.J. (5) 68 Yarkov, A . v . (9) 132 Yaroshenko, G.F. (5) 96, 97; (9) 253
Yashina, N.S. (9) 82 Yashkin, V.V. (9) 245 Yasumoto, F. (6) 40 Yatsimirskii, K . B . (9) 14 Yde, B. (5) 140, 144 Yen Vo-Quang (5) 93 Yeung Lam KO, Y.Y.C. (1) 379
Yi, Q. (5) 57; (7) 99 Yoder, C.H. (9) 39 Yohannes, P.G. (6) 59 Yokoi, M. (1) 238 Yolken, R.H. (6) 289 Yolov, A.A. (6) 316, 317 Yoshifuji, M. (1) 263, 274, 275, 313; (8) 48; ( 9 ) 3, 4 Young, R.N. (7) 115 Youngquist, R.S. (6) 332 Yousif, N . M . (5) 141 Yuanyao Xu (5) 54 Yudelevich, V . I . (5) 2 Yui, S. (6) 297 Yurchenko, V.G. (1) 85 Yurkova, M . S . (6) 232 Yusman, T.A. (8) 130; (9) 232
(8) 13; (5) 109; (9) 200 Yvernault, G. (9) 127 Yvernault, T. (3) 17; (9) 127, 246
Yusopov, M.M.
Zabirov, N.G. (5) 158 Zabotina, E.Ya. (1) 381, 382
Zahn, T. (7) 67 Zajicek, J. (6) 24 Zakim, M.M. (6) 148 Zal'tsman, I.S. (1) 209; (8) 32
Zamaletdinova, G.U. (9) 233
Zamboni, R. (7) 115 Zanka, A. (9) 257 Zan-Kowalczewska, M. (6) 46
Zappia, G. (6) 117 Zard, S.Z. (1) 227 Zarytova, V.F. (6) 131, 156, 249, 284 (6) 1, 343, 346 Zavalishina, A . I . (4) 54 Zavgorodnii, C.G. (6) 96 Zawadzka, H. (6) 288 Zayakina, G.V. (6) 158 Zaychikov, E . f . (6) 237 Zbiral, E. (5) 74, 79; (7) 42 Zdravkova, Z. (5) 153 Zecchi, G. (8) 10 Zeelie, B. (3) 46 Zeiger, H.E. (1) 88 Zemlyyanoi, V.N. (9) 128 Zhadanov, B.V. (5) 96,
Zaug, A . J .
97, 135; (9) 253
Zhang, M. (9) 119 Zhdankovich, E.L. (9) 278 Zhenodarova, S.M. (6) 114 Zhisong, C . (1) 383 Zhmurova, I . N . (1) 85 Zhuzhi, Z. ( 9 ) 103 Zibuck, R. ( 7 ) 126 Ziegler, M . L . (7) 67 Zielinski, W.S. (6) 196 Zijlstra, J . G . (8) 82 Zimmerman, A.L. (6) 54 Zimmermann, P. ( 7 ) 160 Zimmermann, R.A. (6) 275, 276
Zinchenko, A . I . (6) 185 Zingaro, R.A. (9) 172 Zink, J.I. (8) 123 Zinner, G. (1) 206; (7) 13
Zinzyuk, T.A. (1) 200 Zipkin, R.E. (7) 123 Zlot'skii, S.S. (2) 43 Zobowa, M. (6) 292 Zon, G. (4) 7, 93; (5) 46; (6) 146, 168, 171, 376 Zsabo, G. (1) 99; (4) 26 Zschunke, A. (9) 64 Zsohai, L. (1) 262, 269 Zuev, M.B. (9) 93 Zurmuhlen, F. (1) 293 Zwaschka, F. (1) 166 Zwierzak, A. (5) 41, 43 Zyablikova, T . A . (2) 47; (9) 83, 93 Zyk, N.V. (5) 65; (9) 195 Zykova, T.V. (4) 47, 60 Zyryanova, L . I . (2) 47