PYROLYSIS-GC/MS DATA BOOK OF SYNTHETIC POLYMERS
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PYROLYSIS-GC/MS DATA BOOK OF SYNTHETIC POLYMERS Pyrograms, Thermograms and MS of Pyrolyzates
TSUGE Shin, OHTANI Hajime, WATANABE Chuichi
Amsterdam • Boston • Heidelberg • London • New York • Oxford Paris • San Diego • San Francisco • Singapore • Sydney • Tokyo
Elsevier The Boulevard, Langford Lane, Kidlington, Oxford OX5 1GB, UK Radarweg 29, PO Box 211, 1000 AE Amsterdam, The Netherlands First edition 2011 Copyright Ó 2011 Elsevier B.V. All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means electronic, mechanical, photocopying, recording or otherwise without the prior written permission of the publisher Permissions may be sought directly from Elsevier’s Science & Technology Rights Department in Oxford, UK: phone (+44) (0) 1865 843830; fax (+44) (0) 1865 853333; email: permissions@ elsevier.com. Alternatively you can submit your request online by visiting the Elsevier web site at http://elsevier.com/locate/permissions, and selecting Obtaining permission to use Elsevier material Notice No responsibility is assumed by the publisher for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions or ideas contained in the material herein British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library Library of Congress Cataloging-in-Publication Data A catalog record for this book is available from the Library of Congress ISBN: 978-0-444-53892-5 For information on all Elsevier publications visit our web site at elsevierdirect.com
Printed and bound in Great Britain 11 12 13 10 9 8 7 6 5 4 3 2 1
CONTENTS
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Preface
Part 1 Introduction 1.1 History and scope of analytical pyrolysis 1.2 Expanded applicability of GC/MS by combining with pyrolysis 1.3 Py-GC/MS measuring process for polymer characterization
Part 2 Pyrograms and thermograms of 163 high polymers, and MS data of the major pyrolyzates 2.1 Experimental conditions for measuring pyrograms and thermograms of high polymers, and MS data for the major pyrolyzates by means of pyrolysis-GC/MS and evolved gas analysis (EGA)-MS techniques 2.1.1 Polymer samples 2.1.2 Measuring conditions for the pyrograms of the polymers and the MS data of the major peaks on each pyrogram, and the thermograms of the polymers 2.1.3 Data descriptions for the pyrograms and the MS data of the major peaks on the pyrograms, and the thermograms for 163 polymer samples 2.2 Data compilation of pyrograms, thermograms and MS data of major pyrolyzates for 163 typical polymer samples 2.2.1 Polyolefins (homopolymers) 001 Polyethylene (high density); PE(HDPE) 002 Polypropylene (isotactic); iso-PP 003 Polypropylene (atactic); at-PP 004 Polypropylene (syndiotactic); syn-PP 005 Polybutene-1 (isotactic) 006 Poly(4-methyl-1-pentene); PMP 007 Isobutylene-isoprene rubber; IIR 2.2.2 Vinyl polymers with ethylene units (copolymers) 008 Ethylene-propylene copolymer; P(E-P) 009 Ethylene-propylene-diene rubber; EPDM 010 Ethylene-methyl methacrylate copolymer; P(E-MMA) 011 Ethylene-acrylic acid copolymer; P(E-AA)
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012 Ethylene-vinyl acetate copolymer; EVA 013 Ethylene-ethyl acrylate copolymer; P(E-EA) 014 Ethylene-vinyl alcohol copolymer; P(E-VA) 015 Polyethylene ionomer; IO 2.2.3 Vinyl polymers with styrene units 016 Polystyrene; PS 017 Styrene-methyl acrylate copolymer; P(S-MA) 018 Styrene-methyl acrylate alternating copolymer 019 Styrene-methyl methacrylate copolymer; P(S-MMA) 020 Styrene-methyl methacrylate alternating copolymer 021 Methyl methacrylate-butadiene-styrene copolymer; MBS 022 Acrylonitrile-styrene copolymer; AS 023 Acrylonitrile-styrene alternating copolymer 024 Acrylonitrile-butadiene-styrene copolymer; ABS 025 Acrylonitrile-acrylate-styrene copolymer; AAS 026 Acrylonitrile-EPDM-styrene copolymer; AES 027 Styrene-maleic anhydride copolymer; P(S-Mah) 028 Styrene-divinylbenzene copolymer; P(S-DVB) 2.2.4 Vinyl polymers with styrene units’ derivatives 029 Poly(a-methylstyrene); P-a-MS 030 Polydivinylbenzene; PDVB 031 Poly(p-chlorostyrene) 032 Poly(p-methylstyrene); PMS 033 Poly(2-vinylpyridine) 034 Acrylonitrile-p-chlorostyrene copolymer 035 Chloromethylated styrene-divinylbenzene copolymer 2.2.5 Acrylate-type polymers 036 Poly(methyl methacrylate); PMMA 037 Poly(n-butyl methacrylate); PBMA 038 Poly(2-hydroxyethyl methacrylate); PHEMA 039 Poly(methyl acrylate); PMA 040 Poly(ethyl acrylate); PEA 041 Poly(butyl acrylate); PBA 042 Poly(acrylic acid; isotactic); PAA 043 Methyl methacrylate-methyl acrylate copolymer; P(MMA-MA) 044 Higher methacrylate copolymer 045 Acrylic rubber; ACM 046 Polyacrylonitrile; PAN
34 36 38 40 42 42 44 46 48 50 52 54 56 58 60 62 64 66 68 68 70 72 74 76 78 80 82 82 84 86 88 90 92 94 96 98 100 102
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047 Acrylonitrile-methyl acrylate copolymer 048 Polyacrylamide; PAAm 049 Poly(maleic anhydride); PMAH 2.2.6 Chlorine-containing vinyl polymers 050 Poly(vinyl chloride); PVC 051 Vinyl chloride-vinylidene chloride copolymer; P(VC-VdC) 052 Chlorinated poly(vinyl chloride); CPVC 053 Chlorinated polyethylene; CM 054 Vinyl chloride-vinyl acetate copolymer; P(VC-VAc) 055 Chlorosulfonated polyethylene; CSM 056 Acrylonitrile-vinyl chloride copolymer; P(AN-VC) 057 Acrylonitrile-vinyl chloride alternating copolymer 058 Methyl acrylate-vinyl chloride copolymer; P(MA-VC) 059 Methyl acrylate-vinyl chloride alternating copolymer 2.2.7 Fluorine-containing vinyl polymers 060 Polytetrafluoroethylene; PTFE 061 Tetrafluoroethylene-hexafluoropropylene copolymer; FEP 062 Polychlorotrifluoroethylene; PCTFE 063 Poly(vinyl fluoride); PVF 064 Poly(vinylidene fluoride); PVDF 065 Vinylidene fluoride-hexafluoropropylene rubber 066 Propylene-tetrafluoroethylene rubber 2.2.8 The other vinyl polymers 067 Poly(vinyl alcohol); PVA 068 Poly(vinyl butyral); PVB 069 Poly(vinyl acetate); PVAc 070 Poly(vinyl pyrrolidone); PVP 2.2.9 Diene-type elastomers 071 High cis-butadiene rubber; BR 072 Poly(1,2-butadiene) 073 Natural rubber; NR 074 Chloroprene rubber; CR 075 Hydrogenated natural rubber 076 Acrylonitrile-butadiene rubber; NBR 077 Hydrogenated acrylonitrile-butadiene rubber 078 Polynorbornene 079 Styrene-butadiene rubber; SBR 080 Styrene-butadiene-styrene block copolymer; SBS(TPS)
104 106 108 110 110 112 114 116 118 120 122 124 126 128 130 130 131 132 134 136 138 140 142 142 144 146 148 150 150 152 154 156 158 160 162 164 166 168
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081 Styrene-ethylene-butadiene-styrene block copolymer; hydrogenated SBS (SEBS) 2.2.10 Polyamides 082 Polycaproamide; Nylon-6 083 Polyundecanoamide; Nylon-11 084 Polylauroamide; Nylon-12 085 Poly(tetramethylene adipamide); Nylon-4,6 086 Poly(hexamethylene adipamide); Nylon-6,6 087 Poly(hexamethylene sebacamide); Nylon-6,10 088 Poly(dodecamethylene adipamide); Nylon-12,6 089 Caproamide-hexamethylene adipamide copolymer; Nylon-6/66 090 Poly(m-xylene adipamide); Nylon-MXD6 2.2.11 Polyacetals and polyethers 091 Polyoxymethylene; POM 092 Polyoxymethylene(copolymer) 093 Poly(ethylene oxide) 094 Epichlorohydrin rubber; CHR 095 Epichlorohydrin-ethylene oxide rubber; CHC 2.2.12 Thermosetting polymers 096 Phenol formaldehyde resin (novolak); PF 097 Phenol formaldehyde resin (resol); PF 098 Cresol formaldehyde resin (novolak) 099 Diallyl phthalate resin; DAP 100 Poly(ethylene glycol bisallyl carbonate); CR-39 101 Urea formaldehyde resin; UF 102 Melamine formaldehyde resin; MF 103 Xylene resin 104 Unsaturated polyester; UP 105 Epoxy resin; EP 106 Brominated epoxy resin 2.2.13 Polyimide and polyamide-type engineering plastics 107 Bismaleimide triazine resin; BT resin 108 Polyetherimide; PEI 109 Polypyromellitimide; PI 110 Polyaminobismaleimide; PABM 111 Polyamideimide; PAI 112 Poly(p-phenylene terephthalamide); Kevlar 113 Poly(m-phenylene isophthalamide); Nomex
170 172 172 174 176 178 180 182 184 186 188 190 190 192 194 196 198 200 200 202 204 206 208 210 212 214 216 218 220 222 222 224 226 228 230 232 234
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114 Poly(p-phenylene/3,4-diphenylene ether terephthalamide) 2.2.14 Polyesters 115 Poly(ethylene terephthalate); PET 116 Poly(butylene terephthalate); PBT 117 Poly(ethylene naphthalate); PEN 118 Poly(p-hydroxybenzoic acid); type A 119 Poly(p-hydroxybenzoic acid); type B 120 Polyarylate; PAR 121 Poly(1,4-cyclohexanedimethylene terephthalate) 122 Poly(lactic acid); PLA 123 Poly(3-caprolactone); PCL 124 Poly(butylene succinate / adipate); PBSA 125 Poly(3-hydroxybutylic acid); PHB 126 Poly(butylene succinate / carbonate); PEC 2.2.15 The other engineering plastics with phenylene skeletons 127 Polycarbonate(melt method); MM-PC 128 Polycarbonate(solvent method); SM-PC 129 Bisphenol Z polycarbonate 130 Polycarbonate (thermally stabilized) 131 Brominated polycarbonate; Br-PC 132 Polysulfone; PSF 133 Poly(phenylene oxide); PPO 134 Modified poly(phenylene oxide); Modified PPO 135 Polyethersulfone; PESF 136 Poly(ether ether ketone); PEEK 137 Poly(phenylene sulfide); PPS 138 Poly(arylether nitrile); PEN 2.2.16 Silicone polymers 139 Polydimethylsiloxane; PDMS 140 Polymethylphenylsiloxane; PMPS 141 Dimethylsiloxane-methylphenylsiloxane copolymer 142 Polymethylsilsesquioxane; PMSQ 143 Poly(methyl-phenyl) silsesquioxane; PMPSQ 2.2.17 Polyurethanes 144 TDI-polyester polyurethane; PU 145 TDI-polyether polyurethane; PU 146 MDI-polylactone polyurethane; PU 147 Urethane rubber; U 2.2.18 Cellulose-type polymers
236 238 238 240 242 244 246 248 250 252 254 256 258 260 262 262 264 266 268 270 272 274 276 278 280 282 284 286 286 288 290 292 294 296 296 298 300 302 304
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148 Cellulose 149 Methylcellulose; MC 150 Ethylcellulose 151 Cellulose acetate; CA 152 Cellulose acetate-propionate; CAP 153 Cellulose acetate-butyrate; CAB 154 Hydroxyethylcellulose; HEC 155 Carboxymethyl cellulose; CMC 2.2.19 The other natural polymers, etc 156 Glue 157 Shellac 158 Chitin 159 Chitosan 160 Ivory 161 Synthetic lignin; DHP 162 Wood powder 163 Gluten
Part 3 Pyrograms for 33 condensation polymers and MS data of the major pyrolyzates obtained in the presence of organic alkaline 3.1 Experimental conditions for measuring pyrograms and MS data of the major pyrolyzates for the condensation polymers by means of reactive pyrolysis-GC/MS in the presence of organic alkaline 3.1.1 Polymer samples 3.1.2 Measuring conditions for the pyrograms of the polymers and the MS data of the major peaks on each pyrogram by use of reactive pyrolysis in the presence of organic alkaline 3.1.3 Data descriptions for the reaction pyrograms and the MS data of the major peaks on the pyrograms for 33 condensation polymer samples 3.2 Data compilation of pyrograms of 33 condensation polymers through reactive pyrolysis
304 306 308 310 312 314 316 318 320 320 322 324 326 328 330 332 334
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337 337
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[ The number in [xyz] corresponds to that in the Chapter 2.2. ] R01 [042] Poly(acrylic acid; isotactic); PAA R02 [099] Diallyl phthalate resin; DAP R03 [100] Poly(ethylene glycol bisallyl carbonate); CR-39 R04 [104] Unsaturated polyester; UP R05 [105] Epoxy resin; EP R06 [107] Bismaleimide triazine resin; BT resin
340 342 343 344 346 348
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R07 [108] Polyetherimide; PEI R08 [109] Polypyromellitimide; PI R09 [110] Polyaminobismaleimide; PABM R10 [115] Poly(ethylene terephthalate); PET R11 [116] Poly(butylene terephthalate); PBT R12 [117] Poly(ethylene naphthalate); PEN R13 [118] Poly(p-hydroxybenzoic acid); type A R14 [119] Poly(p-hydroxybenzoic acid); type B R15 [120] Polyarylate; PAR R16 [121] Poly(1,4-cyclohexane dimethylene terephthalate) R17 [122] Poly(lactic acid); PLA R18 [123] Poly(3-caprolactone); PCL R19 [124] Poly(butylene succinate / adipate); PBSA R20 [125] Poly(3-hydroxybutylic acid); PHB R21 [126] Poly(butylene succinate / carbonate); PEC R22 [127] Polycarbonate (melt method); MM-PC R23 [128] Polycarbonate (solvent method); SM-PC R24 [129] Bisphenol Z polycarbonate R25 [130] Polycarbonate (thermally stabilized) R26 [132] Polysulfone; PSF R27 [135] Polyethersulfone; PESF R28 [136] Poly(ether ether ketone); PEEK R29 [151] Cellulose acetate; CA R30 [152] Cellulose acetate-propionate; CAP R31 [153] Cellulose acetate-butyrate; CAB R32 [157] Shellac R33 [161] Synthetic lignin; DHP APPENDIX Monographs and reviews for pyrolysis-GC of polymers Index
350 352 354 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 378 380 382
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PREFACE
Pyrolysis-gas chromatography/mass spectrometry (Py-GC/MS) as evidenced by ever increasing numbers of publications in various fields is a rapidly growing scientific area. Especially, in the field of polymer characterization, it is now widely recognized as one of the most promising and practical techniques. Among important factors enabling the rapid advancement of the modern analytical pyrolysis technique are the developments of: a) Various specific pyrolyzers such as the resistively heated self-sensing Pt filaments, the Curie point devices and the functional micro-furnace ones, b) Highly efficient and specific capillary columns such as fused-silica and deactivated stainless steel capillary ones enabling separation of up to fairly polar compounds with higher boiling points to yield high-resolution pyrolysis-gas chromatogram (pyrogram) characteristic of the sample, c) Specific on-line identification techniques for separated components on the pyrograms by means of GC/MS, GC/AED (atomic emission detector), GC/IR (infrared spectrometer), etc. among which GC/MS has played the most important role, d) On-line chemolysis combined with thermal decomposition of condensation polymers in the pyrolysis chamber, typically in the presence of an organic alkaline such as tetramethylammonium hydroxide (TMAH), and e) Sophisticated data searching and handling systems aided by modern computer with abundant memory capacity and processing speed. However, not a few scientists have been skeptical to some extent against the reported data of modern analytical pyrolysis, especially concerning to interlaboratory specificity and reproducibility of the resulting data. Therefore, the standardization of the analytical conditions by use of well characterized samples, and the publication of well qualified data compilation for a series of standard samples have been eagerly requested for a long time. In the end of the 1980’s, the authors published a trial standard database for the pyrograms of 135 typical synthetic polymer samples taken under the same conditions for Py-GC with flame ionization detector (FID) (Tsuge S, Ohtani H. “Pyrolysis-gas chromatography of polymers - fundamentals and data compilations”. Techno System Co., Tokyo, 1989). Recently, we launched a revised database for the pyrograms of 165 typical standard polymers by use of Py-GC/MS together with those for 33 condensation polymers taken by reactive pyrolysis (RP) in the presence of TMAH, where all pyrograms were monitored by total ion current of MS rather than by FID (Tsuge S, Ohtani H, Watanabe C. “Pyrolysis-GC/MS of high polymers - fundamentals and pyrogram compilations”. Techno System Co., Tokyo, 2006). Both of the above mentioned data books, however, were written in Japanese. xiii
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Therefore, the authors have been frequently requested to publish their English editions. In this new data book, the authors compiled the comprehensive pyrolysis data for representative synthetic polymers along with some natural polymers, not only pyrograms taken by conventional Py-GC/MS and RP, but also thermograms and mass spectra taken by evolved gas analysis (EGA) under programmed degradation temperatures. Furthermore, the mass spectra of the up to top 10 major pyrolyzates observed on each pyrogram, and the retention index data for each peak on a given pyrogram were also compiled, for the sake of users’ convenience and promotion of interlaboratory reproducibility and reliability. The authors would be in supreme bliss if this data book could contribute to move up the status of Py-GC/MS in the field of polymer characterization through overcoming its potential skepticism.
ACKNOWLEDGMENTS The authors wish to acknowledge with thanks so many suppliers of the standard polymer samples used for the data measurements of this compilation. We wish to extend our sincere gratitude to Frontier Laboratories Ltd (FLL) and Nagoya Institute of Technology (NIT) for their instrumental and scientific contribution, especially to Ms. MATSUI Kazuko, Mr. HOSAKA Akihiko and Ms. KUNII Sayuri (FLL), and Ms. AOI Hiromi and Ms. KATO Shino (NIT), for collecting, interpreting and compiling huge pyrolysis data properly with patience. TSUGE Shin Nagoya University
OHTANI Hajime Nagoya Institute of Technology
WATANABE Chuichi Frontier Laboratories Ltd
October 1, 2010
PART 1
Introduction In this data book, both conventional Py-GC/MS where thermal energy alone is used to cause fragmentation of given polymeric materials, and reactive Py-GC/MS in the presence of organic alkaline for condensation polymers are compiled. Before going into detailed presentation of the data, however, acquiring a firm grip on the proper understanding about the situation of Py-GC/MS would promote better utilization of the following pyrolysis data for various polymer samples.
1.1 HISTORY AND SCOPE OF ANALYTICAL PYROLYSIS Figure 1.1 shows a brief chronological diagram of modern analytical pyrolysis after the advent of organic MS with an electron impact (EI) ion source followed by the appearance of GC, together with various developments in related techniques and the associated international conferences.1–3 In 1948, the first reports on the off-line pyrolysis-MS (Py-MS) of polymers were published by Madorsky and Straus, and Wall. In 1953, Bradt et al. described on-line Py-MS for which pyrolysis of polymer samples was affected within the instrument in vacuo. Thus valuable structural information about the samples became obtainable. Two years after the introduction of GC by James and Martin in 1952, Davison et al. reported the first work on off-line Py-GC of polymers. These workers demonstrated that Py-GC was quite effective for the characterization of polymeric materials. In 1959, online Py-GC systems and their applications to polymer analysis were reported independently by three research groups: Lehrle and Robb, Radell and Strutz, and Martin. These achievements triggered a boom in Py-GC. Moreover, the dissemination of GC–MS after 1965 strongly accelerated the development of Py-GC. In 1966, Simon and co-workers reported the first directly coupled Py-GC/MS system using a rapid scanning MS. The high-resolution capillary columns introduced by Golay in 1958 had a strong impact on Py-GC. However, general application of their effectiveness was held back until the advent of the chemically inert fused silica capillary columns in 1979, since the earlier metal capillary columns were not suitable for the separation of polar and/or higher boiling point compounds. The chemical inertness and thermal stability of capillary separation columns are among the most important factors in achieving highresolution pyrograms of polymer samples by Py-GC/MS since the thermal degradation products of polymers usually consist of compounds with a wide range of boiling points Pyrolysis-GC/MS Data Book of Synthetic Polymers/Tsuge ISBN 978-0-444-53892-5, Doi:10.1016/B978-0-444-53892-5.10001-X
Ó 2011 Elsevier B.V. All rights reserved.
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[Analytical pyrolysis]
[Related techniques] 1945
Madorsky, et al., and Wall, et al., (1948)
Organic MS (EI) 1950
Bradt, et al., (1953)
GC (1952)
Davison, et al., (1954) Lehrle, et al., Radell, et al. and 1960 Martin (1959) Simon (1964)
Capillary GC/FID (1959)
[Intl. Symposium] 1st (1965) Paris
Simon (1966) Hummel, et al., (1968)
GC/MS (1965-1970) 1970
Meuzelaar, et al., (1973)
3rd (1976) Amsterdam
Tsuge (1973) <Micro-furnace pyrolyzer> J. Anal. Appl. Pyrol. <Elsevier>
2nd (1972) Paris
1980
4th (1979) Budapest th
Fused-silica capillary for GC (1979)
5 (1982) Vail, CO 6th (1984) Weisbaden
GC/FT-IR (1980-1990)
7th (1986) Reading
Tsuge, Ohtani (1989)
1990
8th (1988) Lund
GC/AED (1989)
9th (1990) Noordwijkerhout
Deactivated stainless steel capillary GC (1991)
10th (1992) Hamburg 11th (1994) Nagoya 12th (1996) Venice 2000
13th (1998) Munich 14th (2000) Seville 15th (2002) Leoben
Tsuge, Ohtani, Watanabe (2006)
16th (2004) Alicante 17th (2006) Budapest 18th (2008) Canary Islands
2010
Figure 1.1 Chronicle of analytical pyrolysis.
which often contain fairly polar compounds such as carboxylic acids, amines, nitriles, epoxides, and so on. Modern fused silica capillary columns and recently developed metal capillary ones with deactivated inner walls have drastically improved the situation of Py-GC/MS. During such developments in analytical pyrolysis, a number of books and commentaries have been released (most of these are listed in Appendix). In recent years, comprehensive monographs of analytical pyrolysis by Moldoveanu were published by focusing on natural4 and synthetic polymers,5 respectively. These books systematically discuss the latest trends in theory and techniques in analytical pyrolysis with featuring the representative applications. On the other hand, standardization and reliable compilation of
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Introduction
a standard database for various series of standard samples have been left among the important factors to promote interlaboratory data comparison in Py-GC. In the early stage of Py-GC, however, significant interlaboratory discrepancies between pyrolysis data (pyrograms) were reported even for the same polymer types. This was mainly caused by a diversity of pyrolysis devices operated under varied conditions. Owing to continued improvement of pyrolyzers and fundamental studies to control the operating conditions and obtain reproducible and characteristic degradation of the studied materials, most of the commercially available pyrolyzers (flash filament-, furnace-, and Curie-point types) have made the interlaboratory discrepancies, a minor problem. In this situation, a trial standard database for 136 kinds of typical synthetic polymers compiled under the same refined conditions using Py-GC was published by the authors in 1989,6 and its expanded revision was then issued in 2006.7 These data books, however, were written in Japanese. In order to respond to the international request, the authors have compiled a new English version Py-GC/MS data book covering most of the typical synthetic polymers.
1.2 EXPANDED APPLICABILITY OF GC/MS BY COMBINING WITH PYROLYSIS Modern GC/MS is widely recognized as one of the most powerful methodologies, where mass resolving and mass determining capabilities of MS are synergistically enhanced through direct combination with high-resolution ability of GC even for complex mixture samples provided that they might have moderate volatility. However, we have to comprehend that the ordinary limitation of GC/MS lies in the volatility of given samples. Generally speaking the samples to be fed on GC/MS analysis should have vapor pressure (volatility) at least in order of a few mmHg at the maximum GC column temperatures around 300 � C. Here, you should notice that ordinary high polymers in the category of non-volatiles should be out of GC/MS application. Figure 1.2 illustrates the situations of Py-GC (Py-GC/MS) together with ordinary GC (GC/MS) and LC (LC/MS) as a function of hypothetical volatility [molecular weight (MW) or polarity]. As shown at the top, the substances around us exist at ambient temperature as either gas, liquid or solid, mostly depending on their MW. Although, the substances called “molecules” are in the range between A and B have some solvents, and are in the applicability of either GC or LC depending on their volatility or solubility in given solvents. Roughly speaking among the whole molecules (100%), about 30% of them could be treated with GC, including those formed through derivatization to enhance volatility or thermal stability, while LC can be applied about 85% of them provided that some proper solvents can be found even for polymers. However, the insoluble substances between the ranges above B cannot be treated by any chromatographic techniques.
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Molecules
Insoluble substances [+α]
[ 100 % ]
Infinitive MW
MW / Polarity
Gas Liquid
[at ambient temp.]
Solid
Application range of LC, GC and Py-GC
LC (LC/MS)
[ 85 % ]
GC (GC/MS)
Non accessible by GC and LC
[ 30 % ] by derivatization
Py-GC (Py-GC/MS)
A
B
C
Figure 1.2 How “Pyrolysis” expanded the applicability of GC/MS for material characterization.
Three-dimensional polymeric materials, coal, lignin, soil, and most of biomass would be included in these category substances. However, the applicability of GC (GC/MS) combined with pyrolysis, Py-GC (Py-GC/MS) ranges the entire area of the organic substances if they could yield fragment by thermal energy or chemically assisted thermolysis. Thus, the modern Py-GC (Py-GC/ MS) is on the new horizon for the polymer characterization including intractable materials by conventional methodologies.
1.3 PY-GC/MS MEASURING PROCESS FOR POLYMER CHARACTERIZATION Figure 1.3 illustrates the flow diagram in Py-GC/MS and its complementary evolved gas analysis (EGA)–MS for polymer characterization. In Py-GC/MS measurements, usually a given polymer sample weighing about 10–100 mg is instantaneously pyrolyzed at about 400–600 � C with or without catalytic and/or reactive reagents under a flow of N2 or He carrier gas. The resulting decomposition products transferred into the separation column are separated to yield a pyrogram. The pyrolysis products of a given polymer sample are usually composed of very complex components each of which might reflect the original structures. Even for these conditions, Py-GC/ MS utilizing a chemically inert capillary column often provides highly efficient
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Polymer sample
Pyrolysis (with/without reagent)
Decomposition products
Vaporization and thermal decomposition by programmed heating
Evolved compounds
EGA-MS
Py-GC/MS
Separative analysis by GC/MS
On-line monitoring by MS
Specific pyrogram
Thermogram
Compositional and structural characterization, and thermal behaviors of polymer
Figure 1.3 Flow diagram for polymer characterization by Py-GC/MS and EGA/MS.
separation. The individual components on the pyrogram are continuously identified by use of the observed mass spectra. In addition, total ion monitoring (TIM) and selected ion monitoring (SIM) often provide supplemental and/or complement information of peak identification on the pyrogram. On the other hand, in EGA–MS, evolved gases formed during the programmed heating of the sample are directly transferred into MS to achieve on-line monitoring of the components. For the EGA–MS measurements, the separation column in Py-GC/ MS is replaced with a deactivated open transfer line connecting directly between a temperature programmable pyrolyzer and an ion source of MS. The resulting thermogram monitored by MS during the programmed heating reflects the evolved gas profile of the sample as a function of temperature. The observed specific pyrograms and/ or thermograms often provide valuable information regarding the composition and/or chemical structures of the original polymer sample as well as on the degradation mechanisms and related kinetics.
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REFERENCES 1. Tsuge S. J Anal Appl Pyrol 1995;32:1–6. 2. Tsuge S, Ohtani H. Polym Degrad Stab 1997;58:109–30. 3. Tsuge S, Ohtani H. Pyrolysis-gas chromatography/mass spectrometry (Py-GC/MS). In: Montaudo G, Lattimer RP, editors. Mass spectrometry of polymers. Boca Raton: CRC Press; 2002. 4. Moldoveanu SC. Analytical pyrolysis of natural organic polymers. Amsterdam: Elsevier; 1998. 5. Moldoveanu SC. Analytical pyrolysis of synthetic organic polymers. Amsterdam: Elsevier; 2005. 6. Tsuge S, Ohtani H. Pyrolysis-gas chromatography of polymers - fundamentals and data compilations. Tokyo: Techno System Co; 1989. 7. Tsuge S, Ohtani H, Watanabe C. Pyrolysis-GC/MS of high polymers - fundamentals and pyrogram compilations. Tokyo: Techno System Co; 2006.
PART 2
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates 2.1 EXPERIMENTAL CONDITIONS FOR MEASURING PYROGRAMS AND THERMOGRAMS OF HIGH POLYMERS, AND MS DATA FOR THE MAJOR PYROLYZATES BY MEANS OF PYROLYSIS-GC/MS AND EVOLVED GAS ANALYSIS (EGA)–MS TECHNIQUES 2.1.1 Polymer samples In the following data acquisition, the same 163 standard polymer samples used in the former editiony were adopted as a set of representative ones utilized in versatile fields, which include representative synthetic polymers [a) polyolefins (homopolymers) (001– 007), b) vinyl polymers with ethylene units (copolymers) (008–015), c) vinyl polymers with styrene units (016–028), d) vinyl polymers with styrene derivatives (029–035), e) acrylate-type polymers (036–049), f) chlorine-containing vinyl polymers (050–059), g) fluorine-containing vinyl polymers (060–066), h) the other vinyl polymers (067–070), i) diene-type elastomers (071–081), j) polyamides (082–090), k) polyacetals and polyethers (091–095), l) thermosetting polymers (096–106), m) polyimides and polyamide-type engineering plastics (107–114), n) polyesters (115–126), o) the other engineering plastics with phenylene skeletons (127–138), p) silicone polymers (139–143), and q) polyurethanes (144–147)] along with some natural polymers [r) cellulose-type polymers (148–155) and s) the other some natural polymers (156–163)].
2.1.2 Measuring conditions for the pyrograms of the polymers and the MS data of the major peaks on each pyrogram, and the thermograms of the polymers Figures 2.1 and 2.2 illustrate the schematic flow diagrams of the measuring systems of the pyrolysis (Py)-GC/MS and evolved gas analysis (EGA)–MS, respectively. In both systems, the vertical micro-furnace pyrolyzer (Frontier Lab., PY-2020iD) mounted on y Tsuge S, Ohtani H, Watanabe C. “Pyrolysis-GC/MS of high polymers - fundamentals and pyrogram compilations”. Techno System Co., Tokyo, 2006.
Pyrolysis-GC/MS Data Book of Synthetic Polymers/Tsuge ISBN 978-0-444-53892-5, Doi:10.1016/B978-0-444-53892-5.10002-1
Ó 2011 Elsevier B.V. All rights reserved.
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He
Pyrolyzer
pyrolysis tube micro furnace
He
interface heater sample cup GC splitter vent separation column
separation column GC/MS adaptor
GC Oven
Q-MS
Figure 2.1 Schematic flow diagram of Py-GC/MS System (from the upper to the lower flow). (a) Carrier gas: 100 ml/min of He flow at the pyrolyzer, 1 ml/min at the separation column through a splitter (1/ 100); (b) pyrolyzer: a micro-furnace pyrolyzer (Frontier Lab., PY-2020iD) at 600 � C; (c) pyrolyzer/GC interface temp.: 320 � C; (d) GC injection temp.: 320 � C; (e) sample size: ca. 0.2 mg of a sample cup (ECO cup-L: o.d. 4.2 � i.d. 4 � 8 mm height, deactivated stainless steel cup); (f) GC separation column: Ultra ALLOY-5 (0.25 mm � 30 m; 0.25 mm film of 5%diphenyl–95%dimethylpolysiloxane); (g) GC oven temp. programmed from 40 � C (2 min hold) – (20 � C/min) – 320 � C (13 min hold); (h) GC/MS adapter (Frontier Lab, Vent-free adapter); (i) GC/MS interface temp.: 320 � C; (j) EI source (70 eV) temp.: 230 � C; (k) MS, scan range: 29–600 (m/z) at 2000 amu/sec.
either a Shimadzu GCMS-QP2010 or an Agilent 6890 GC & 5975 MS was used under a flow of He carrier gas, and data search libraries of Frontier Lab., F-search (pyrolyzates MS08) and NIST/EPA/NIH (version 2.0f) were mostly used for the peak identification of the pyrolyzates together with their retention index (RI) data. However, any other GC/MS systems equipped with any type of pyrolyzers such as resistively heated filament devices and inductively heated ones could provide basically the same tendency data as those in this compilation. Pyrograms and MS data measurements The measurements of the pyrograms for the 163 polymer samples were carried out by the Py-GC/MS system shown in Figure 2.1. The flash pyrolysis temperature was fixed at 600 � C throughout the entire data acquisition, and the resulting pyrolyzates of the
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
He
Pyrolyzer
sample cup vent
transfer tube
GC Oven
GC/MS adaptor
Q-MS
Figure 2.2 Schematic Flow Diagram of EGA/MS System (from the upper to the lower flow). (a) Carrier gas: 50 ml/min at the pyrolyzer, 1 ml/min in the interface through a splitter (1/50); (b) pyrolyzer: the same pyrolyzer as in Figure 2.1, its temperature programmed from 100 to 700 � C at a rate of 20 � C/ min; (c) sample size: ca. 0.2 mg weighed into the same sample cup as in Figure 2.1; (d) deactivated and uncoated stainless steel transfer tube (i.d. 0.15 mm � 2 m length); (e) GC/MS adapter/MS interface temp.: 300 � C; (f) MS scan range: 29–600 (m/z) at 70 amu/sec.
polymer sample weighing ca. 0.2 mg were separated by a stainless steel capillary column (Frontier Lab. Ultra ALLOY-5) coated with 5%diphenyl–95%dimethylpolysiloxane liquid phase under a programming temperature condition; 40 � C (2 min hold) – (20 � C/ min) – 320 � C (13 min hold). The other experimental conditions are supplemented at the bottom of the figure. The resulting mass spectrometric data for all the peaks on the pyrograms stored as the total ion chromatogram (TIC), and the selected mass spectra for the top 10 major peaks at most were compiled on this data book, together with the RI data of the main peaks on the pyrograms. Here, the RI data for the components were estimated by comparison of the retention data for a series of hydrocarbon peaks with known carbon numbers appearing on the pyrogram of polyethylene observed under the same condition. As shown in Figure 2.2, the measurements of the EGA–MS thermograms for the polymer samples weighing ca. 0.2 mg were carried out separately by replacing the separation column with a deactivated and uncoated stainless steel transfer tube (i.d. 0.15 mm � 2 m length), where the column oven temperature was maintained at 300 � C to prevent condensations of less-volatile pyrolyzates in the transfer tube, and the temperature of the pyrolyzer was programmed from 100 to 700 � C at a rate of
9
10
Tsuge, Ohtani and Watanabe
20 � C/min to obtain the thermogram as a function of temperature. Here, in the mode change from the Py-GC/MS system to the EGA/MS system, the Vent-free adapter (Frontier Lab) played an important practical role enabling the rapid replacement of the separation column with the transfer tube without venting the working Q-MS under a high vacuum.y Thus obtained thermogram data of the polymer samples by monitoring the total ion current of MS are compiled in the upper right corner of the averaged mass spectrum for each thermogram as a function of the programmed temperature from 100 to 700 � C.
2.1.3 Data descriptions for the pyrograms and the MS data of the major peaks on the pyrograms, and the thermograms for 163 polymer samples In the following Chapter 2.2, two facing pages were allocated for each polymer sample. For example, two facing pages (pp. 12–13) are accommodated for polyethylene. On the left hand page (p. 12), you can find at the top:
001 Polyethylene (high density); PE(HDPE) CH2CH2
n
where the sample number, 001 is followed by the full name with its abbreviation, and then its chemical structure is given. The upper display is its pyrogram at 600 � C separated by the capillary separation column followed by TIC monitoring mentioned in Chapter 2.1.2 where C10, for example, designates hydrocarbons containing ten carbon atoms. The horizontal retention time scale can easily be converted into temperature axis by knowing the programmed temperature conditions for the separation column [from 40 � C (2 min hold) – (20 � C/min) – 320 � C (13 min hold)]. In the bottom, you can see the peak identification table for the pyrogram together with molecular weight, relative peak intensity, and retention index data. As the footnote, related references in which the concerned pyrolysis information is included were listed. On the right hand page (p. 13), its EGA thermogram taken as a function of temperature from 100 to 700 � C at a rate of 20 � C/min is shown at the right hand shoulder of its averaged mass spectrum for the temperature range (4) shown above the thermogram monitored by its TIC between 29 and 600 (m/z). By the thermogram profile, you can easily understand the whole thermal behavior, that the thermal decomposition of PE(HD) starting at ca. 400 � C passes through the peak top at ca. 480 � C, finishing at ca. 530 � C, which also tells us useful information to determine the y http://www.frontier-lab.com/product/catalogue/Vent-free_adapter.pdf.
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
optimum pyrolysis temperature to measure its pyrogram. Furthermore, by use of the average mass spectrum data search mentioned above, you could often make rapid identification of the polymeric materials. At the bottom on the right hand page, the selected mass spectra for the top 10 major peaks are compiled. (In some cases, where only a few significant pyrolyzates are observed, typically for depolymerizing polymers, the number of the mass spectra should be less than 10.)
11
12
Tsuge, Ohtani and Watanabe
2.2 DATA COMPILATION OF PYROGRAMS, THERMOGRAMS AND MS DATA OF MAJOR PYROLYZATES FOR 163 TYPICAL POLYMER SAMPLES 2.2.1 Polyolefins (homopolymers) 001 Polyethylene (high density); PE(HDPE) CH2CH2
n
C10 C28 C26
C22 C11
C14 C15 C12
C18 C20
C16
C13
C24
C30 C32 C34
C9
C36
C6 LB
C7
C8
C40
C41
TIC
0
10
Peak Notation LB C6 C7
C8
C9
C10
C11
C14
C20 C30 C40 C41
30 [min]
20
Assignment of Main Peaks
Molecular Weight
propylene + propane CH2=CH(CH2)3CH3 CH2=CH(CH2)4CH3 CH3(CH2)5CH3 CH2=CH(CH2)4CH=CH2 CH2=CH(CH2)5CH3 CH3(CH2)6CH3 CH2=CH(CH2)5CH=CH2 CH2=CH(CH2)6CH3 CH3(CH2)7CH3 CH2=CH(CH2)6CH=CH2 CH2=CH(CH2)7CH3 CH3(CH2)8CH3 CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH3(CH2)9CH3 CH2=CH(CH2)10CH=CH2 CH2=CH(CH2)11CH3 CH3(CH2)12CH3 CH2=CH(CH2)16CH=CH2 CH2=CH(CH2)17CH3 CH3(CH2)18CH7 CH2=CH(CH2)27CH3 CH2=CH(CH2)37CH3 CH2=CH(CH2)38CH3
42; 44 84 98 100 110 112 114 124 126 128 138 140 142 152 154 156 194 196 198 278 280 282 420 560 574
[ Related References ] 1) Michajlov, L.; Zugenmaier, P.; Cantow, H.-J. Polymer 1968, 9, 325. 2) Sugimura, Y.; Tsuge, S. Anal. Chem. 1978, 50, 1968. 3) Sugimura, Y.; Tsuge, S. Macromolecules 1979, 12, 512. 4) Ohtani, H.; Tsuge, S.; Usami, T. Macromolecules 1984, 17, 2557. 5) Duc, S.; Lopez, N. Polymer 1999, 40, 6723.
Retention Relative Index Intensity 300 583 689 700 782 791 800 883 892 900 983 991 1000 1083 1092 1100 1385 1392 1400 1985 1993 2000 2993 3997 4096
43.7 91.8 42.4 19.3 2.1 25.1 14.3 5.8 30.4 10.3 6.6 64.2 10.4 7.1 49.8 16.1 12.3 49.2 13.5 25.3 38.0 16.2 100.0 94.1 82.8
13
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
001
EGA thermogram
Averaged mass spectrum 41
55
83
69
100
200
300
400
500
97
600
700 ºC
programming rate: 20ºC/min
111 125
30 50
139
100
154
168
182
196
150
200
250 [m/z]
( m/z range : 29 - 600 amu )
C7 : 1-heptene
C10 : 1,9-decadiene 41
55
56 41
67 81
70
29
95
29
98
83
110 123
C10 : n-decane
C10 : 1-decene 41
57
43
56 70
29
71
83 111
98
140
C11 : 1-undecene 41
85
29
97
113
142
C14 : 1-tetradecene 41
55
55
70
69
83 97
83 29
29
97
111 111 126
125
154
140 153 168
196
C30 : 1-triacontene C20 : 1-eicosene
(mixed with 1,29-triacontadiene and n-triacontane) 57
43 55
83
43
97
69
97 69
111 29
111 125 139
168
196
224
252
418
C41 : 1-hentetracontene
(mixed with 1,39-tetracontadiene and n-tetracontane)
(mixed with1,40-hentetracontadiene and n-hentetracontane)
57
57
71
43 71 97
97
29
153
280
C40 : 1-tetracontene
43
125
29
111 125
153
559
29
111 125
153
572
14
Tsuge, Ohtani and Watanabe
002 Polypropylene(isotactic); iso-PP CH2CH(CH3 )
n
C15 C9
C12 C’13 C13
C’34 C16 C21 C18 C’25 C’28 C’31 C’37 C’22 C’16 C’19 C’40 C24
C’43
C11 C3 C10 C’10
C5 TIC
10
C’46
C’49
20
C6
0
10
Peak Notation
Assignment of Main Peaks
C3 C5 C6 C9 C10 C10’ C11
propylene n-pentane 2-methyl-1-pentene 2,4-dimethyl-1-heptene 2, 4, 6-trimethyl-1-heptene 2, 4, 6-trimethyl-1, 6-heptadiene 4, 6-dimethyl-2-nonene (meso form) 2, 4, 6-trimethyl-1-nonene (meso form) 2, 4, 6-trimethyl -1-nonene (racemic form) 2, 4, 6, 8-tetramethyl-1-nonene (meso form) 2, 4, 6, 8-tetramethyl-1, 8-nonadiene (meso form) 2, 4, 6, 8-tetramethyl-1-undecene (isotactic) 2, 4, 6, 8- tetramethyl-1-undecene (heterotactic) 2, 4, 6, 8- tetramethyl-1-undecene (syndiotactic) 2, 4, 6, 8, 10-pentamethyl-1-undecene (isotactic) 2, 4, 6, 8, 10-pentamethyl-1, 10-undecadiene (isotactic) 2, 4, 6, 8, 10-pentamethyl-1-tridecene (isotactic) 2, 4, 6, 8, 10, 12-hexamethyl-1, 12-tridecadiene (isotactic) 2,4,6,8,10,12,14,16,18,20,22-undecamethyl-1,22tricosadiene (isotactic)
C12 C13 C13’ C15 C16 C16’ C18 C19’ C34’
30 [min]
20
Molecular Retention Weight Index 42 72 84 126 140 138 154 168 168 182 180 210 210 210 224 222 252 264 476
295 500 584 844 895 916 996 1083 1087 1132 1156 1312 1320 1329 1356 1385 1531 1605 3397
[ Related References ] 1) Michajlov, L.; Zugenmaier, P.; Cantow, H.-J. Polymer 1968, 9, 325. 2) Tsuchiya, Y.; Sumi, K. J. Polym. Sci., Part-A1 1969, 7, 1599. 3) Seeger, M.; Cantow, H. -J. Makromol. Chem. 1975, 176, 2059. 4) Kiran, E.; Gillham, J. K. J. Appl. Polym. Sci. 1976, 20, 2045. 5) Kiang, J. K. Y.; Uden, P. C.; Chien, J. C. W. Polym. Degrad. Stab. 1980, 2, 113. 6) Sugimura, Y.; Nagaya, T.; Tsuge, S.; Murata, T.; Takeda, T. Macromolecules 1980, 2, 113. 7) de Amorim, M. T. S. P.; Comel, C.; Vermande, P. J. Anal. Appl. Pyrolysis 1982, 4, 73. 8) Ishiwatari, M. J. Polym. Sci., Polym. Lett. Ed. 1984, 22, 83. 9) Ohtani, H.; Tsuge, S.; Ogawa, T.; Elias, H. -G. Macromolecules 1984, 17, 465.
Relative Intensity 14.6 10.0 8.1 100.0 6.8 2.6 2.9 9.5 3.3 4.0 4.1 18.5 2.6 10.6 3.4 3.9 6.4 5.4 9.7
15
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
002
EGA thermogram
Averaged mass spectrum 41 69
55
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83 111
97
125
30 50
137
100
154
167
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C5 : n-pentane
C6 : 2-methyl-1-pentene 43
39 56 84
69
29 29 55
72
C10 : 2,4,6-trimethyl-1-heptene
C9 : 2,4-dimethyl-1-heptene 43
41
70
83
55
69 55
29
29 83 126 111
91
97
C12 : 2,4,6-trimethyl-1-nonene (meso form)
125
140
C12 : 2,4,6-trimethyl-1-nonene (racemic form)
41
41 55
69 55
29
83
111
69 83
29
112
125
97
C15 : 2,4,6,8-tetramethyl-1-undecene (isotactic)
125
97
153 168
168
C15 : 2,4,6,8-tetramethyl-1-undecene (heterotactic)
43 55 69
43 55 69 83
111 111
83
29
29 125
97
154 140
97 167
125
154
210
C34’ : 2,4,6,8,10,12,14,16,18,20,22-undecamethyl C15 : 2,4,6,8-tetramethyl-1-undecene (syndiotactic)
-1,22-tricosadiene (isotactic)
43 55
69 69 111
85
55
29
43 97
125
154 139
167
83 125 97111 153 139 165 179
283
313 327 355
16
Tsuge, Ohtani and Watanabe
003 Polypropylene(atactic); at-PP CH2CH(CH3 )
n
C15 C9 C12
C’13 C13
C18
C21
C’16
10
C3 C5
TIC
0
10
Assignment of Main Peaks
C3 C5 C6 C9 C10 C10’
propylene n-pentane 2-methyl-1-pentene 2,4-dimethyl-1-heptene 2, 4, 6-trimethyl-1-heptene 2, 4, 6-trimethyl-1, 6-heptadiene 2, 4, 6-trimethyl-1-nonene (meso form) 2, 4, 6-trimethyl-1-nonene (racemic form) 2, 4, 6, 8-tetramethyl-1-nonene (meso form) 2, 4, 6, 8-tetramethyl-1-nonene (racemic form) 2, 4, 6, 8-tetramethyl-1, 8-nonadiene (meso form) 2, 4, 6, 8-tetramethyl-1, 8-nonadiene (racemic form) 2, 4, 6, 8-tetramethyl-1-undecene (isotactic) 2, 4, 6, 8-tetramethyl-1-undecene (heterotactic) 2, 4, 6, 8-tetramethyl-1-undecene (syndiotactic) 2, 4, 6, 8, 10-pentamethyl-1, 10-undecadiene (isotactic) 2, 4, 6, 8, 10-pentamethyl-1, 10-undecadiene (heterotactic) 2, 4, 6, 8, 10-pentamethyl-1, 10-undecadiene (syndiotactic)
C13 C13’
C15
C16’
30 [min]
20
Peak Notation
C12
20
15
C10 C’10
C6
Molecular Retention Index Weight 42 72 84 126 140 138 168 168 182 182 180 180 210 210 210 222 222 222
295 500 584 845 896 916 1083 1087 1132 1138 1156 1159 1311 1320 1329 1385 1392 1401
[ Related References ] 1) Seeger, M.; Cantow, H. -J. Makromol. Chem. 1975, 176, 2059. 2) Sugimura, Y.; Nagaya, T.; Tsuge, S.; Murata, T.; Takeda, T. Macromolecules 1980, 13, 928. 3) de Amorim, M. T. S. P.; Comel, C.; Vermande, P. J. Anal. Appl. Pyrolysis 1982, 4, 73. 4) Ishiwatari, M. J. Polym. Sci., Polym. Lett. Ed. 1984, 22, 83. 5) Ohtani, H.; Tsuge, S.; Ogawa, T.; Elias, H. -G. Macromolecules 1984, 17, 465.
Relative Intensity 19.5 13.7 11.6 100.0 7.2 2.7 7.3 7.6 2.1 2.6 2.3 1.9 11.0 11.1 8.8 1.5 1.7 1.8
17
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
003
EGA thermogram
Averaged mass spectrum 43
69 55 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83 111 97
125
153
139 50
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
C5 : n-pentane
C3 : propylene 39
41
29 55
72
29
131
C9 : 2,4-dimethyl-1-heptene
C6 : 2-methyl-1-pentene 39
70
43 56
55
69 84
29
29
83
221
C12 : 2,4,6-trimethyl-1-nonene (meso form)
C10 : 2,4,6-trimethyl-1-heptene 41
41 69
55
83
69
55
83
29
29 91
109
125
111 125
97
140
C12 : 2,4,6-trimethyl-1-nonene (racemic form)
139 153 168
C15 : 2,4,6,8-tetramethyl-1-undecene (isotactic)
41
43 55
126 111
97
55
69
69
29
83
83 111 97
125 132
125
97 168
C15 : 2,4,6,8-tetramethyl-1-undecene (heterotactic)
139
154
167
210
C15 : 2,4,6,8-tetramethyl-1-undecene (syndiotactic) 43
43 55 69
55 69
85
111
83
111
29
111
29
29 97
97
125
154 139
167
210
125
154 139
167
210
18
Tsuge, Ohtani and Watanabe
004 Polypropylene (syndiotactic); syn-PP CH2CH(CH3 )
n
C15 C9 C12
C11
C’13 C13
C’16 C18 C16 C’19
C21 C’22
C’25 C24
C’28
C3 C5 TIC
10
C10
0
10
Assignment of Main Peaks
C3 C5 C6 C9 C10 C10’ C11
propylene n-pentane 2-methyl-1-pentene 2,4-dimethyl-1-heptene 2, 4, 6-trimethyl-1-heptene 2, 4, 6-trimethyl-1, 6-heptadiene 4, 6-dimethyl-2-nonene (racemic form) 2, 4, 6-trimethyl-1-nonene (meso form) 2, 4, 6-trimethyl-1-nonene(racemic form) 2, 4, 6, 8-tetramethyl-1-nonene (racemic form) 2, 4, 6, 8-tetramethyl-1, 8-nonadiene(racemic form) 2, 4, 6, 8-tetramethyl-1-undecene (isotactic) 2, 4, 6, 8-tetramethyl-1-undecene (heterotactic) 2, 4, 6, 8-tetramethyl-1-undecene (syndiotactic) 2, 4, 6, 8, 10-pentamethyl-1-undecene (syndiotactic) 2, 4, 6, 8, 10-pentamethyl -1, 10-undecadiene (syndiotactic) 2, 4, 6, 8, 10-pentamethyl -1-tridecene (syndiotactic) 2, 4, 6, 8, 10, 12-hexamethyl-1, 12-tridecadiene (syndiotactic)
C15 C16 C16’ C18 C19’
20
30 [min]
20
Peak Notation
C13 C13’
C’34
C’10
C6
C12
C’31
15
Molecular Retention Weight Index 42 72 84 126 140 138 154 168 168 182 180 210 210 210 224 222 252 264
295 500 586 844 895 916 1000 1081 1086 1138 1159 1312 1318 1327 1377 1399 1568 1641
[ Related References ] 1) Seeger, M.; Cantow, H. -J. Makromol. Chem. 1975, 176, 2059. 2) Sugimura, Y.; Nagaya, T.; Tsuge, S.; Murata, T.; Takeda, T. Macromolecules 1980, 13, 928. 3) Ohtani, H.; Tsuge, S.; Ogawa, T.; Elias, H. -G. Macromolecules 1984, 17, 465.
Relative Intensity 59.5 32.5 18.5 100.0 10.0 1.9 1.8 3.3 8.7 2.0 1.5 9.0 2.1 11.4 1.0 1.2 2.6 1.1
19
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
004
EGA thermogram
Averaged mass spectrum 41 55
69
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83 111 97
125 137
30 50
100
153
167
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C5 : n-pentane
C3 : propylene
43
41
55 29
72
29
C6 : 2-methyl-1-pentene
C9 : 2,4-dimethyl-1-heptene 43
56
70 55
41 84 69
83
29 29
126 91
C10 : 2,4,6-trimethyl-1-heptene
111
C12 : 2,4,6-trimethyl-1-nonene (meso form) 43
43
55 69
69
84 84
55
111 91
29
140
106
C12 : 2,4,6-trimethyl-1-nonene (racemic form) 43
168
193
C15 : 2,4,6,8-tetramethyl-1-undecene (isotactic)
69
69
43
55
55 85
84
111
112 97
29
125 132
168
C15 : 2,4,6,8-tetramethyl-1-undecene (heterotactic)
97
125
30
154
C15 : 2,4,6,8-tetramethyl-1-undecene (syndiotactic) 43
43
69 55
69
55 85 111
85 111
154 97
126
154 160
97 30
125 160
195 210
20
Tsuge, Ohtani and Watanabe
005 Polybutene-1 (isotactic) CH2CH(CH2CH3)
n
C20
C12 C16
C29 C25 C28
C24 C17
C15
C19
C33
C37
C32
C41 C45
10
C4 TIC C3
C21
C5
C7
C8
C6
20
C13 C9
C11
0
10
Peak Notation
Assignment of Main Peaks
C3 C4 C5 C6 C7 C8
propane + propylene 1-butene (monomer) 2-methyl-1-butene 1-hexene n-heptane 2-ethyl-1-hexene (dimer) 2-ethyl-4-methyl-1-hexene 2, 4-diethyl-1, 4-pentadiene 5-ethylnonene 5-ethylnonane 2, 4-diethyl-1-octene (trimer) 2, 4-diethyl-6-methyl-1-octene 2, 4, 6-triethyl-1, 6-heptadiene 2, 4, 6-triethyl-1-decene (meso form) 2, 4, 6-triethyl-1-decene (racemic form) 2, 4, 6, 8-tetraethyl-1-dodecene (isotactic) 2, 4, 6, 8-tetraethyl-1-dodecene (syndiotactic) 2, 4, 6, 8, 10-pentaethyl-1-tetradecene (isotactic) 2, 4, 6, 8, 10, 12-hexaethyl-1, 12-tridecadiene (isotactic)
C9 C11 C12 C13 C16 C20 C24 C25
C49
[ Related Reference ] 1) Seeger, M.; Cantow, H. -J. Makromol. Chem. 1975, 176, 2059.
30 [min]
20
Molecular Retention Weight Index 44; 42 56 70 84 100 112 126 124 154 156 168 182 180 224 224 280 280 336 348
300 385 480 585 700 790 853 858 1024 1056 1124 1176 1190 1424 1428 1707 1725 1983 2053
Relative Intensity 0.9 36.0 15.5 3.2 21.3 19.4 5.9 3.7 3.3 4.5 100.0 14.9 3.7 17.7 5.5 21.4 16.1 22.4 15.7
21
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
005
EGA thermogram
Averaged mass spectrum 55 41 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69 83
97 111
125
30 50
100
139
153
168
181
195
150
207 250 [m/z]
200
( m/z range : 29 - 600 amu )
C7 : n-heptane
C4 : 1-butene (monomer) 41
43
71 57
56 29 29
100 85
C8 : 2-ethyl-1-hexene (dimer)
C12 : 2,4-diethyl-1-octene (trimer)
70
55
57 70
41
98
41 29 29
83
112 83
111
95
95
83 57 71 81
41 55 29
151 29 126 137
153
166
123 137
182
166
C16 : 2,4,6-triethyl-1-decene (racemic form)
C16 : 2,4,6-triethyl-1-decene (meso form) 57
57 41
41
69
69 83
83
97 112
29
125
97
112
29
154 139
167
195
125
224
C20 : 2,4,6,8-tetraethyl-1-dodecene (isotactic)
154 137
167
57
41
97
69 83
97
69 83
111 153 125139
112 181 167
29 210
251
280
195
C20 : 2,4,6,8-tetraethyl-1-dodecene (syndiotactic)
57
29
110
69
112 97
41
168
C13 : 2,4,6-triethyl-1,6-heptadiene
C13 : 2,4-diethyl-6-methyl-1-octene 41
139 125
153 125139
181 167
210
251
22
Tsuge, Ohtani and Watanabe
006 Poly(4-methyl-1-pentene); PMP CH2CH(CH2CH(CH3)CH3)
n
C18
C4 C3 TIC
C20 C24 C19
C12 C6
C7 C8
C10 C’10
C11 C13 C14
0
C30
C36
C43 C37
10
Peak Notation
Assignment of Main Peaks
C3 C4 C6 C7 C8 C10’ C10
propane + propylene 1-butene 4-methyl-1-pentene 2, 4-dimethyl-1-pentene 6-methyl-1-heptene 2-isobutyl-4-methyl-1-pentene ? 8-methyl-1-nonene ? 2, 8-dimethyl-4-nonene ? 2, 8-dimethyl-3-nonene ? 2, 8-dimethylnonane 2-isobutyl-6-methyl-1-heptene (dimer) 2-isobutyl-4, 6-dimethyl-1-heptene 2-isobutyl-8-methyl-1-nonene ? 2, 4-diisobutyl-8-methyl-1-nonene (trimer) 2, 4-diisobutyl-6, 8-dimethyl-1-nonene C20H40 2, 4, 6-triisobutyl-10-methyl-1-undecene 2, 4, 6, 8-tetraisobutyl-12-methyl-1-tridecene
C11 C12 C13 C14 C18 C19 C20 C24 C30
C49
C55
C61 30 [min]
20
Molecular Retention Weight Index
[ Related Reference ] 1) Shimono, T.; Tanaka, M.; Shono, T. J. Anal. Apply. Pyrolysis 1980, 1, 189.
44; 42 56 84 98 112 140 ? 140 ? 154 ? 154 ? 156 168 182 194 ? 252 266 280 336 420
300 388 548 638 756 886 960 1016 1023 1031 1088 1119 1288 1497 1523 1693 1861 2194
Relative Intensity 20.0 100.0 29.5 19.6 15.4 6.6 6.3 3.3 5.9 4.7 18.4 6.7 5.3 79.8 13.7 21.4 15.1 10.8
23
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
006
EGA thermogram
Averaged mass spectrum 41 57 69
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83 111
97
123 50
137
100
154
182 193
167
150
207 250 [m/z]
200
( m/z range : 29 - 600 amu )
C4 : 1-butene
C6 : 4-methyl-1-pentene 41
41
56 56 69
84
C8 : 6-methyl-1-heptene
C7 : 2,4-dimethyl-1-pentene 56
55
41
69
41
70 83
30
C12 : 2-isobutyl-6-methyl-1-heptene (dimer)
30
112
C18 : 2,4-diisobutyl-8-methyl-1-nonene (trimer) 57
56 43
41
97
84
98
69 111
83
83
69
97 29
126
57 69
167
195
252
C20 : C20H40
111
83
126 139
154 168
C19 : 2,4-diisobutyl-6,8-dimethyl-1-nonene 43
154
29
97 111
43
57 69 111 83
97
29
97
125
182
168 137 153
29
139
C24 : 2,4,6-triisobutyl-10-methyl-1-undecene
197
223
280
C30 : 2,4,6,8-tetraisobutyl-12-methyl-1-tridecene
57 43
154167
125
205
57 69
43
111 83 97
69
111 85 97
182
125 139
154168
238 251
279
29
154 168 125 139 182 210 196
237 265 251
322
24
Tsuge, Ohtani and Watanabe
007 Isobutylene-isoprene rubber; IIR CH2C(CH3)2
CH2C(CH3)
CHCH2
n
C12 C4 C16 C8 C7
C20
C24 C28
C10 C9
C11
C13
C19
C15
C23
C27
C32 C31
C36 C35
C39
C40 20
10
TIC
0
10
Peak Notation
Assignment of Main Peaks
C4 C7
1-butene 2, 4-dimethyl-1, 3-pentadiene 2, 4, 4-trimethyl-1-pentene (dimer) 2, 4, 4-trimethyl-2-pentene 2, 2, 4, 4-tetramethylpentane 2, 2, 4, 4-tetramethyl-1-pentene 2, 4, 6-trimethyl-1, 3-heptadiene 2, 4, 4, 6-tetramethyl-1-heptene 2, 4, 4, 6-tetramethyl-2-heptene 2, 4, 4, 6, 6-pentamethyl-1-heptene (trimer) 2, 4, 4, 6, 6-pentamethyl-2-heptene C13H24 ? 2, 4, 4, 6, 6, 8-hexamethyl-1-nonene 2, 4, 4, 6, 6, 8-hexamethyl-2-nonene 2, 4, 4, 6, 6, 8, 8-heptamethyl-1-nonene (tetramer) 2, 4, 4, 6, 6, 8, 8-heptamethyl-2-nonene
C8 C9 C10 C11 C12 C13 C15 C16 C 20
30 [min]
20
2,4,4,6,6,8,8,10,10-nonamethyl-1-undecene 2,4,4,6,6,8,8,10,10-nonamethyl-2-undecene
[ Related References ] 1) Tsuchiya, Y.; Sumi, K. J. Polym. Sci., Part A1 1969, 7, 813. 2) Warren, D.; Gates, S.; Driscoll, L. J. Polym. Sci., Part A1 1971, 9, 717. 3) Seeger, M.; Cantow, H. -J. Makromol. Chem. 1975, 176, 2059. 4) Kiran, E.; Gillham, J. K. J. Appl. Polym. Sci. 1976, 20, 2045. 5) Smith, D. A.; Youren, J. W. Br. Polym. J. 1976, 8, 101. 6) Grimbley, M. R.; Lehrle, R. S. Polym. Degrad. Stab. 1995, 49, 223. 7) Grimbley, M. R.; Lehrle, R. S. Polym. Degrad. Stab. 1995, 48, 441.
Molecular Retention Weight Index 56 96 112 112 128 126 138 154 154 168 168 180 ? 210 210 224 224 280 280
398 702 710 726 769 774 873 970 984 1040 1065 1190 1289 1320 1368 1403 1703 1741
Relative Intensity 100.0 5.9 8.5 6.1 1.7 3.1 4.7 2.3 1.8 18.9 4.2 3.2 3.6 3.0 9.2 5.8 8.2 3.8
25
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
007
EGA thermogram
Averaged mass spectrum 97 41 57
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69
83
50
113
123
137
100
155
168
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C4 : 1-butene
C8 : 2,4,4-trimethyl-1-pentene 41
57 56 41 29
29
C8 : 2,4,4-trimethyl-2-pentene
112
97
69
81
C10 : 2,4,6-trimethyl-1,3-heptadiene 95
97 55
110
67
41
112
69
41
79
30
C12 : 2,4,4,6,6-pentamethyl-1-heptene (trimer)
57
55 41
41 69 81
112
69
97
41 111
224
C20 : 2,4,4,6,6,8,8,10,10-nonamethyl-1-undecene
69
29
169
57
97 41 69 81
153
C20 : 2,4,4,6,6,8,8,10,10-nonamethyl-2-undecene
57 41
113
83 125 137
97
29
168
57
57 69 81
113
83
C16 : 2,4,4,6,6,8,8-heptamethyl-2-nonene (tetramer)
97
29
97
29
168
C16 : 2,4,4,6,6,8,8-heptamethyl-1-nonene (tetramer)
41
77
C12 : 2,4,4,6,6-pentamethyl-2-heptene (trimer)
97
29
55
30
111
153
280
29
69
113
83 123 137 153
169
224
26
Tsuge, Ohtani and Watanabe
2.2.2 Vinyl polymers with ethylene units (copolymers) 008 Ethylene-propylene copolymer; P(E-P) CH2CH2 C10
C’9
C11
C’12
C12
C’11
C’14 C’15 C15 C14 C16
C’10
CH2CH(CH3 )
n
C18 C20 C22 C24 C26 C28 C30 C32 C34
C3 C4 TIC
C36
C8 C5 C6
10
20
C9
C7
0
10
Peak Notation
Assignment of Main Peaks
C3 C4 C5 C6 C7 C8 C9’
propylene 1-butene 1-pentene 1-hexene 1-heptene 2-methylheptene 2, 4-dimethyl-1-heptene (P trimer) 1-nonene 2, 4, 6-trimethyl-1-heptene n-nonane 4-methylnonane 2-methyl-1-nonene 1-decene dimethylnonene dimethylnonene 2, 4, 6-trimethyl-1-nonene (P tetramer; meso form) 1-undecene 2-methyl-1-undecene 1-dodecene n-dodecane 2, 6, 8-trimethyl-1-undecene 2, 4, 6, 8-tetramethyl-1-undecene (isotactic) (P pentamer) 2, 4, 6, 8-tetramethyl-1-undecene (syndiotactic) 1-tetradecene
C9 C10’ C10 C11’ C12’ C11 C12 C14’ C15’ C14
30 [min]
20
Molecular Retention Weight Index 42 56 70 84 98 112 126 126 140 128 142 140 140 154 154 168 154 168 168 170 196 210 210 196
295 385 492 585 690 787 844 893 896 900 964 987 992 1037 1047 1083 1092 1186 1192 1200 1290 1311 1329 1394
[ Related References ] 1) Michajlov, L.; Zugenmaier, P.; Cantow, H.-J. Polymer 1968, 9, 325. 2) Michajlov, L.; Cantow, H. -J.; Zugenmaier, P. Polymer, 1971, 12, 70. 3) Tsuge, S.; Sugimura, Y.; Nagaya, T. J. Anal. Appl. Pyrolysis 1980, 1, 221. 4) Wampler, T.; Zawodny, C.; Mancini, L.; Wampler, J. J. Anal. Appl. Pyrolysis 2003, 68-69, 25
Relative Intensity 100.0 60.3 43.6 25.5 39.9 90.7 9.8 8.6 6.3 5.9 3.7 17.3 7.0 7.3 11.9 14.9 7.1 10.7 8.7 15.0 13.4 5.2 11.8
27
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
008
EGA thermogram
Averaged mass spectrum 41 55 69 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83 97
111
30 50
125
139
100
154 165
182
196
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C5 : 1-pentene
C6 : 1-hexene 39
39
56 55
29
84
69
29
70
C9’ : 2,4-dimethyl-1-heptene (P-trimer)
C8 : 2-methylheptene 56
43
41
70 55
29
29
83
69
126
112 84
97
111
91
C9 : 1-nonene
C10’ : 4-methylnonane 41
41
57
29
55
29
70
98
69 83
97 81
126
104
112
127
C12’ : 2,4,6-trimethyl-1-nonene (P-tetramer; meso form)
C10 : 1-decene 41
41
55
29
55
69
29
70 83
83
97 111
111 125
97
168
139
140
C15’ : 2,4,6,8-tetramethyl-1-undecene (isotactic) C14’ : 2,6,8-trimethyl-1-undecene 41
29
142
(P-pentamer) 43 55
55
69
83
97
69
83
111
29 97
140 109
125
196
125 141
154
28
Tsuge, Ohtani and Watanabe
009 Ethylene-propylene-diene rubber; EPDM CH2CH2
C3
C5
CH2CH(CH3)
X
n
C4
C6 C7
C10
C8
C11 C9
C12 C13
C15 C17
C20
C25
TIC
0
10
Peak Notation
Assignment of Main Peaks
C3 C4 C5 C6 C7 C8 C9 C10 C11 C12 C13
propylene 1-butene 1-pentene 1-hexene 1-heptene 2-methyl-1-heptene 1-nonene 1-decene 1-undecene 2-methyl-1-undecene 1-tridecene
30 [min]
20
Molecular Retention Index Weight 42 56 70 84 98 112 126 140 154 168 182
[ Related References ] 1) Smith, D. A.; Youren, J. W. Br. Polym. J. 1976, 8, 101. 2) Tsuge, S.; Sugimura, Y.; Nagaya, T. J. Anal. Appl. Pyrolysis 1980, 1, 221. 3) Kretzschmar, H. -J.; Tobisch, K.; Gross, D. Kautsch. Gummi Kunstst. 1987, 40, 447. 4) Yamada, T.; Okumoto, T.; Ohtani, H.; Tsuge, S. Rubber Chem. Technol. 1990, 63, 191. 5) Yamada, T.; Okumoto, T.; Ohtani, H.; Tsuge, S. Rubber Chem. Technol. 1991, 64, 708.
295 382 492 592 693 788 892 992 1091 1186 1292
Relative Intensity 100.0 41.1 32.8 34.4 17.3 7.7 11.1 8.8 7.7 4.2
29
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
009
EGA thermogram
Averaged mass spectrum 55
41
69 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83
97 111 125
50
137
151
100
168 200 [m/z]
150
( m/z range : 29 - 600 amu )
C3 : propylene
C4 : 1-butene 41
41
56
29
29
C5 : 1-pentene
C6 : 1-hexene 56
42 41
55
70 69
84
104
126
29 29
C8 : 2-methyl-1-heptene
C9 : 1-nonene 41
56
56
69 41 84
29
69
29
97
112 84
97
C10 : 1-decene
C11 : 1-undecene 41
41
55
55
70
70
83 83
29
97 29
97 111
111
140
126
154
125
140 154
C13 : 1-tridecene
C12 : 2-methyl-1-undecene
41
56
55 69
83 97
41 29
69 83
97
112 125
140 153 168
29
111 182
30
Tsuge, Ohtani and Watanabe
010 Ethylene-methyl methacrylate copolymer; P(E-MMA) CH2CH2
CH2C(CH3)(COOCH3)
n
C10 C11
C14 C15
C12 C6
C9
MMA LB C7
C13
C26
C30 C32
C8
a
C28
C24
C20 C22
b TIC
C18
C16
c
C34 C36
d
0
C39 10
Peak Notation LB C6 C7 MMA a C8
C9 b C10 c C11 d C14 C20 C30 C39
30 [min]
20
Assignment of Main Peaks
Molecular Weight
propylene, isobutene 1-butene CH2=CH(CH2)3CH3 CH2=CH(CH2)4CH3 CH3(CH2)5CH3 CH2=C(CH3)COOCH3 unidentified* CH2=CH(CH2)5CH3 CH3(CH2)6CH3 CH2=CH(CH2)5CH=CH2 CH2=CH(CH2)6CH3 CH3(CH2)7CH3 unidentified* CH2=CH(CH2)7CH3 CH3(CH2)8CH3 2-methyloctanoic acid methylester CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH3(CH2)9CH3 unidentified* CH2=CH(CH2)10CH=CH2 CH2=CH(CH2)11CH3 CH3(CH2)12CH3 CH2=CH(CH2)17CH3 CH2=CH(CH2)27CH3 CH2=CH(CH2)36CH3
42, 56 56 84 98 100 100 112 114 124 126 128 140 142 172 152 154 156 194 196 198 280 420 546
* bonding in MMA and C1-C5 alkyls.
[ Related Reference ] 1) Sugimura, Y.; Tsuge, S.; Takeuchi, T. Anal. Chem. 1978, 50, 1173.
Retention Relative Intensity Index 298 385 591 693 700 710 777 790 800 882 895 900 982 991 1000 1054 1085 1092 1100 1151 1385 1392 1400 1993 2995 3895
100.0 76.1 35.6 8.2 45.8 8.1 26.5 8.3 4.9 25.4 4.7 7.5 47.6 5.1 13.9 7.9 35.7 7.0 6.5 12.2 31.9 5.4 16.9 33.1 18.6
31
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
010
EGA thermogram
Averaged mass spectrum 41 55 100
69
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
88 97 111 30 50
125
139
157
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
C7 : 1-heptene
C6 : 1-hexene 41
56
56
41
70
29
29
84
69
98 83
MMA : methyl methacrylate
C8 : 1-octene
41
55
41 69
70
O
O
100 59
29
83
29
112
85
97
C11: 1-undecene
C10 : 1-decene 41
41
55
55
70
70 83 83
29
29
97 111
111
140
C14 : 1-tetradecene 41
97 154
C20 : 1-eicosene
55
83 97
43 57 69
126
83 69
97
111 29
111
125
29 125
140 154 168
57
83 97
69 43 111
29
280
(mixed with 1,38-nonatriacontadiene and n-nonacosane)
(mixed with 1,29-triacontadiene and n-triacontane) 43
252
C39 : 1-nonatriacontene
C30 : 1-triacontene 57
139 153 168182
196
125 153 167
418
29
71 97
111 125 139 153 167
504
545 552
32
Tsuge, Ohtani and Watanabe
011 Ethylene-acrylic acid copolymer; P(E-AA) CH2CH2
CH2CH(COOH)
n
C10
C11
C14 C15
C12 C13
C16 C18
C9
C20
C22
C24 C28 C26
C30 C32
LB C6
C7
C8
C34
C36
TIC
0
10
Peak Notation LB C6 C7 C8
C9
C10
C11
C13
C14
C18 C34
30 [min]
20
Assignment of Main Peaks
Molecular Retention Index Weight
propylene + propane 1-butene CH2=CH(CH2)3CH3 CH2=CH(CH2)4CH3 CH3(CH2)5CH3 CH2=CH(CH2)5CH3 CH3(CH2)6CH3 CH2=CH(CH2)5CH=CH2 CH2=CH(CH2)6CH3 CH3(CH2)7CH3 CH2=CH(CH2)6CH=CH2 CH2=CH(CH2)7CH3 CH3(CH2)8CH3 CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH3(CH2)9CH3 CH2=CH(CH2)9CH=CH2 CH2=CH(CH2)10CH3 CH3(CH2)11CH3 CH2=CH(CH2)10CH=CH2 CH2=CH(CH2)11CH3 CH3(CH2)12CH3 CH2=CH(CH2)14CH=CH2 CH2=CH(CH2)15CH3 CH3(CH2)16CH3 CH2=CH(CH2)31CH3
42; 44 56 84 98 100 112 114 124 126 128 138 140 142 152 154 156 180 182 184 194 196 198 250 252 254 476
300 385 597 694 700 794 800 882 893 900 984 993 1000 1084 1093 1100 1285 1293 1300 1386 1393 1400 1787 1794 1800 3398
Relative Intensity 100.0 84.5 38.3 16.7 36.2 13.4 5.2 36.7 9.5 8.2 68.8 8.1 8.4 50.5 10.8 10.8 35.9 8.5 10.5 47.6 8.3 14.7 34.4 8.4 41.1
33
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
011
EGA thermogram
Averaged mass spectrum 41 55 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
71 83
97 111
30 50
125
138
152
100
165 200 [m/z]
150
( m/z range : 29 - 600 amu )
C7 : 1-heptene
C6 : 1-hexene 41
41
56
29 56
29
70 84
69
83
C8 : 1-octene
98
C9 : 1-nonene 41
41
55
29
55
29 70
69 83 97
83
112
C10 : 1-decene
97
104
126
C11 : 1-undecene
41
41
55
55
29
29
70
69 83
97
111
83 97 111
140
126
154
125
140 154 168
C14 : 1-tetradecene
C13 : 1-tridecene 41
41 55 55
29
69
83
29
69
97
83
97 111
111 125 139
154
182
196
C34 : 1-tetratriacontene (mixed with 1,33-tetratriacontadiene and n-tetratriacontane)
C18 : 1-octadecene 41
43
57
55 69 69 83 97 29
111 125
29 139 153 168
224
97 83 111 125 153 195 139 165 207
269 282
343 356
405 429
34
Tsuge, Ohtani and Watanabe
012 Ethylene-vinyl acetate copolymer; EVA CH2CH2
CH2CH(OCOCH3)
n
C10 C11
LB
C14 C15
C12 C13
C16 C18
C6 C9
AC
C20
C24 C26 C22 C28
C7
C30
C8
C32 C34
TIC
0
10
Peak Notation LB C6 AC C7
C8
C9 C10
C11
C12
C14
C16
C19 C21
C36
30 [min]
20
Assignment of Main Peaks
Molecular Retention Index Weight
propylene, butane etc. CH2=CH(CH2)3CH3 CH3COOH CH2=CH(CH2)4CH3 CH3(CH2)5CH3 CH2=C(CH2)4CH=CH2 CH2=CH(CH2)5CH3 CH3(CH2)6CH3 CH2=CH(CH2)6CH3 CH3(CH2)7CH3 CH2=CH(CH2)6CH=CH2 CH2=CH(CH2)7CH3 CH3(CH2)8CH3 CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH3(CH2)9CH3 CH2=CH(CH2)8CH=CH2 CH2=CH(CH2)9CH3 CH3(CH2)10CH3 CH2=CH(CH2)10CH=CH2 CH2=CH(CH2)11CH3 CH3(CH2)12CH3 CH2=CH(CH2)12CH=CH2 CH2=CH(CH2)13CH3 CH3(CH2)14CH3 CH2=CH(CH2)15CH=CH2 CH2=CH(CH2)16CH3 CH3(CH2)17CH3 CH2=CH(CH2)19CH3
42, 58 84 60 98 100 110 112 114 126 128 138 140 142 152 154 156 166 168 170 194 196 198 222 224 226 264 266 268 294
[ Related Reference ] 1) Haeussler, L.; Pompe, G.; Albrecht, V.; Voigt, D. J. Thermal Anal. 1998, 52, 131.
298 595 606 689 700 782 792 800 894 900 986 994 1000 1087 1095 1100 1188 1195 1200 1388 1396 1400 1590 1593 1600 1892 1898 1900 2094
Relative Intensity 81.8 51.4 100.0 27.7 8.9 4.0 23.5 10.7 25.2 7.6 6.5 44.8 8.3 7.1 33.9 8.3 6.1 24.4 9.7 5.8 27.7 7.7 6.4 21.6 10.3 7.7 21.3 9.8 35.7
35
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
012
EGA thermogram
Averaged mass spectrum 43 55 100
69
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83
97
29
111 50
123
135
149
100
165 200 [m/z]
150
( m/z range : 29 - 600 amu )
AC : acetic acid
C8 : 1-octene 43
43
O
55
60
70
OH 29
83
29 67
112
97
82
C9 : 1-nonene
C10 : 1-decene 43
41
56
56
70 69
29
29 83
83 97
97
111
126
108
C12 : 1-dodecene
C11 : 1-undecene 43 55
43 55 70
69 83 29
97 111
111 126 134
125
154
140
168
C16 : 1-hexadecene
C14 : 1-tetradecene
43
43 55
55 83 97
83 69
69
97
29
111
29
111 125
125 140 154 168
139 154 168
196
196
224
C21 : 1-heneicosene
C19 : 1-nonadecene
43
57
97
83
83 69
69 111
29
83 97
29
43 57
140
125 139 154168182
29 238
266
97
111
125 139 153 168 182 196
36
Tsuge, Ohtani and Watanabe
013 Ethylene-ethyl acrylate copolymer; P(E-EA) CH2CH2
CH2 CH(COOC2 H5)
n
C10 C14 C11
C15 C12
C16 C13
C28 C18 C20
C9
C26 C22 C24
C30 C32
LB C6 TIC
C8 C7
C34 a
C36
b
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
LB C6
propylene, 1-butene 42, 56 CH2=CH(CH2)3CH3 84 CH2=CH(CH2)4CH3 98 CH3(CH2)5CH3 100 CH2=CH(CH2)4CH=CH2 110 CH2=CH(CH2)5CH3 112 CH3(CH2)6CH3 114 ethyl (2E)-2-methyl-2-butenoate CH3CH=C(COOC2H5)CH3 128 CH2=CH(CH2)4CH=CH2 124 CH2=CH(CH2)6CH3 126 CH3(CH2)7CH3 128 CH2=CH(CH2)6CH=CH2 138 CH2=CH(CH2)7CH3 140 CH3(CH2)8CH3 142 unidentified* CH2=CH(CH2)7CH=CH2 152 CH2=CH(CH2)8CH3 154 CH3(CH2)9CH3 156 CH2=CH(CH2)8CH=CH2 166 CH2=CH(CH2)9CH3 168 CH3(CH2)10CH3 170 CH2=CH(CH2)9CH=CH2 180 CH2=CH(CH2)10CH3 182 CH3(CH2)11CH3 184 CH2=CH(CH2)11CH=CH2 208 CH2=CH(CH2)12CH3 210 CH3(CH2)13CH3 212 *bonding in ethyl acrylate and alkyls
C7
C8 a C9
C10 b C11
C12
C13
C15
[ Related Reference ] 1) McNeil, I. C.; Mohammed, M. H. Polym. Degrad. Stab. 1995, 48, 175.
Molecular Retention Weight Index 300 593 694 700 782 794 800 876 885 893 900 984 993 1000 1056 1084 1093 1100 1185 1193 1200 1286 1294 1300 1486 1494 1500
Relative Intensity 100.0 74.9 33.6 14.9 5.4 32.4 16.0 5.1 5.0 30.7 10.7 5.6 61.4 7.5 6.7 11.7 48.2 9.6 10.1 38.0 9.7 11.8 35.3 8.0 12.9 40.3 9.3
37
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
013
EGA thermogram
Averaged mass spectrum 41 55 100
83
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69 97 111
125
31 50
100
139
152
169 179
194
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C6 : 1-hexene
C8 : 1-octene 41
41
56
55
29
70
29 69
83
84
112
97
a : ethyl(2E)-2-methyl-2-butenoate
C9 : 1-nonene O
55 29
41
O
83
55
39
29
113 100
69 83
67
97
128
104
C10 : 1-decene
126
b : unidentified 29 39
41
87
55
55
111
70
29
69 83
128
99
97 111 125
156 141
140
C12 : 1-dodecene
C11 : 1-undecene
41
41
55
55 29
69
69
29
83
83
97 111
126
97 111
154
C13 : 1-tridecene
125
140
168
C15 : 1-pentadecene 41
41
55 55 29
69
83
69 83 97 29
97
111
111 125
141 154
182
125
140 154 169 182
210
38
Tsuge, Ohtani and Watanabe
014 Ethylene-vinyl alcohol copolymer; P(E-VA) CH2CH2
CH2CH(OH)
n
c
A
a
d e
b B
DF TIC
C
20
10
H DP
0
10
Peak Notation
Assignment of Main Peaks
A B DF C DP H a b c d e
acetaldehyde acetone 2,5-dihydrofuran crotonaldehyde 6-methyl-3,4-dihydro-2H-pyran 3-hexene-2,5-diol
kinds of aldehyde?
30 [min]
20
Molecular Retention Weight Index 44 58 70 70 98 116 -
408 465 571 637 772 997 1183 1200 1269 1388 2010
Relative Intensity 39.6 20.6 2.6 4.6 2.9 100.0 10.9 5.3 11.5 15.8 7.3
39
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
014
EGA thermogram
Averaged mass spectrum 43
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55
29
69 81
98
50
105
123
139
149
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
A : acetaldehyde
B : acetone 43
44
O
O
58 30
30
C : crotonaldehyde
DF : 2,5-dihydrofuran 39
39
O
70
O
70 50
30
DP : 6-methyl-3,4-dihydro-2H-pyran 43
50
30
H : 3-hexene-2,5-diol 43
55
O
OH
98 OH
83
58 31
70
30
71
98 83
112
c : unidentified
a : unidentified 69
41
43
55 58 31 84 68
31 97
83
112
43
55
126
95
71 55
71 97
31
111
e : unidentified
d : unidentified 41
97
81
81
111
31 111
170 125 137 152
129 133
151 169 185197
224
40
Tsuge, Ohtani and Watanabe
015 Polyethylene ionomer; IO CH2CH2
CH2C(CH3)(COO)
n
Zn OCO C10
C11 C12
C14 C15 C13
C16 C18 C20 C22 C26 C28 C24
C9
LB C6 C7
C30
C8
C32 C34 C36
TIC
0
10
Peak Notation LB C6 C7
C8
C9
C10
C11
C12
C13
C14
C18 C22
30 [min]
20
Assignment of Main Peaks
Molecular Retention Index Weight
propylene, 1-butene 2-butene CH2=CH(CH2)3CH3 CH2=CH(CH2)4CH3 CH3(CH2)5CH3 CH2=CH(CH2)4CH=CH2 CH2=CH(CH2)5CH3 CH3(CH2)6CH3 CH2=CH(CH2)5CH=CH2 CH2=CH(CH2)6CH3 CH3(CH2)7CH3 CH2=CH(CH2)6CH=CH2 CH2=CH(CH2)7CH3 CH3(CH2)8CH3 CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH3(CH2)9CH3 CH2=CH(CH2)8CH=CH2 CH2=CH(CH2)9CH3 CH3(CH2)10CH3 CH2=CH(CH2)9CH=CH2 CH2=CH(CH2)10CH3 CH3(CH2)11CH3 CH2=CH(CH2)10CH=CH2 CH2=CH(CH2)11CH3 CH3(CH2)12CH3 CH2=CH(CH2)14CH=CH2 CH2=CH(CH2)15CH3 CH3(CH2)16CH3 CH2=CH(CH2)19CH3
42, 56 56 84 98 100 110 112 114 124 126 128 138 140 142 152 154 156 166 168 170 180 182 184 194 196 198 250 252 254 308
300 385 593 693 700 783 792 800 884 892 900 983 992 1000 1083 1091 1100 1184 1192 1200 1284 1292 1300 1384 1392 1400 1786 1793 1800 2194
Relative Intensity 100.0 60.5 29.4 18.0 4.7 26.5 12.3 4.2 22.0 7.9 8.0 36.3 8.9 9.0 30.7 10.0 8.6 25.8 12.4 10.3 25.9 7.2 10.0 30.8 10.7 13.5 25.5 7.9 40.1
41
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
015
EGA thermogram
Averaged mass spectrum 41 55 100
69
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
83
97 111
30 50
124
100
139
155 165
180
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C8 : 1-octene
C6 : 1-hexene 56
41
41
55 70
84
69
83
29
29
112 97
C10 : 1-decene
C9 : 1-nonene 56
41
41 55
70
69
83
29
97 111
126
104
125
140
C12 : 1-dodecene
C11 : 1-undecene 41
83
29
97
41
55
55
70
69 83
83
97 97
29
29 111
111 126
154
125
C13 : 1-tridecene 41
140
168
C14 : 1-tetradecene 41
55 69
55 69
83
83 97
97
29
125
140 154
125
182
C18 : 1-octadecene
97 55 83 43 69
43 69 111
29
196
139 153 168
C22 : 1-docosene
83 97
55
111
29
111
111 125 139153168
224
252
29
125 139 153 182 167196
308
403
553
42
Tsuge, Ohtani and Watanabe
2.2.3 Vinyl polymers with styrene units 016 Polystyrene; PS CH2CH(C6 H5)
n
SSS
SS S AB
D4
D2 D3 D1
αS
D5 D7 D6
10
20
TIC
T 0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Weight Index
T S AB αS D1 D2 D3 D4 SS D5 D6 D7 SSS
toluene 92 styrene 104 allylbenzene 118 α methylstyrene 118 C(Ph)-C-Ph 182 C-C(Ph)-C-Ph 196 C=C-C(Ph)-C-Ph 208 C(Ph)-C-C-Ph 196 C=C(Ph)-C-C-Ph (dimer) 208 C=C(Ph)-C-C(Ph)-C 222 C(Ph)=C-C-C-Ph 208 C=C(Ph)-C-C-C(Ph)=C 234 C=C(Ph)-C-C(Ph)-C-C-Ph (trimer) 312 * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
765 898 952 988 1542 1579 1647 1678 1749 1759 1851 1924 2488
Relative Intensity 1.9 100.0 0.3 0.7 0.6 0.3 0.2 0.3 10.2 0.9 1.2 1.0 26.7
[ Related References ] 1) Tsuge, S.; Okumoto, T.; Takeuchi, T. J. Chromatogr. Sci. 1969, 7, 250. 2) Sugimura, Y.; Tsuge, S. Anal. Chem. 1978, 50, 1968. 3) de Amorim, M. T. S. P.; Bouster, C.; Vermande, P.; Veron, J. J. Anal. Appl. Pyrolysis 1981, 3, 19. 4) Sugimura, Y.; Nagaya, T.; Tsuge, S. Macromolecules 1981, 14, 520. 5) Schroeder, U. K. O.; Ebert, K. H. Makromol. Chem. 1984, 185, 991. 6) Dean, L.; Groves, S.; Hancox, R.; Lamb, G.; Lehrle, R. S. Polym. Degrad. Stab. 1989, 25, 143. 7) Ohtani, H.; Yuyama, T.; Tsuge, S.; Plage, B.; Schulten, R. -H. Eur. Polym. J. 1990, 26, 893. 8) Atkinson, D. J.; Lehrle, R. S. J. Anal. Appl. Pyrolysis 1991, 19, 319. 9) Gardner, P.; Lehrle, R. Eur. Polym. J. 1993, 29, 425. 10) Ito, Y.; Ohtani, H.; Ueda, S.; Nakashima, Y.; Tsuge, S. J. Polym. Sci., Part A 1994, 32, 383. 11) Nonobe, T.; Ohtani, H.; Usami, T.; Mori, T.; Fukumori, H.; Hirata, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis 1995, 33, 121. 12) Yang, M.; Shibasaki, Y. J. Polym. Sci. A, Polym. Chem. 1998, 36, 2315. 13) Liu,Y.; Guo, S.; Qian, J. Petrol. Sci. Technol. 1999, 17, 1089.
43
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
016
EGA thermogram
Averaged mass spectrum 104
91 78
100
200
300
400
500
39
600
700 ºC
programming rate: 20ºC/min
51 117
63
130 143 50
100
165 179 194 207 221
150
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
S : styrene
T : toluene
104
91
103
78 51 39
65
51
63
39
89
αS : α-methylstyrene
D1 : 1,2-diphenylethane 91
118 117 103 78
182
51
39
65
63
39
D2 : propane-1,2-diyldibenzene
51
77
39
51
65
77
91
91 152 165 178
39 51
196
104
65 77
141152 165 180
105
91
208
130 193
D6 : (E)-1-butene-1,4-diyldibenzene
D5 : 1-pentene-2,4-diyldibenzen
77
128 141 152 165
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
105
32
104
117
91
115
115
194
39 51 65
144 165 152
179 205
222
D7 : hexa-1,5-diene-2,5-diyldibenzene
39 51 65 77
208 139 152 165 178 189
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer) 91
130
115 117
91 77 39
51 65
194 207
143 234 156 178 165 189 205 219
39
51 6577
115
221
297 312
44
Tsuge, Ohtani and Watanabe
017 Styrene-methyl acrylate copolymer; P(S-MA) CH2CH(C6H5)
CH2CH(COOCH3)
n
SMS
S
SMM MMS MSM SM MS
MM MM’
SS
SSM
MMM
SSS
MS’ 20
10
TIC
M T
αS 10
0
30 [min]
20
Peak Notation
Assignment of Main Peaks
M T S αS MM’ MM MS’ MS SM MMM SS MSM MMS SMM
methyl acrylate 86 toluene 92 styrene 104 α-methylstyrene 118 C(COOC)-C-C-COOC 160 C=C(COOC)-C-C-COOC (M dimer) 172 C(COOC)-C-C-Ph 178 C=C(COOC)-C-C-Ph (hybrid dimer) 190 C=C(Ph)-C-C-COOC 190 C=C(COOC)-C-C(COOC)-C-C-COOC (M trimer) 258 C=C(Ph)-C-C-Ph (S dimer) 208 C=C(COOC)-C-C(Ph)-C-C(COOC) 276 C=C(COOC)-C-C(COOC)-C-C-Ph 276 C=C(Ph)-C-C(COOC)-C-C-COOC (hybrid trimer) 276 C=C(Ph)-C-C(Ph)-C-C-COOC 294 + C=C(COOC)-C-C(Ph)-C-C-Ph 294 C=C(Ph)-C-C(COOC)-C-C-Ph 312 C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer) * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
SSM SMS SSS
Molecular Retention Weight Index
Relative Intensity
610 766 892 987 1118 1189 1386 1438 1465 1659 1737 1913 1925 1932
12.6 1.6 100.0 1.7 1.1 2.1 2.0 5.4 7.4 6.1 0.5 11.5 10.8 20.1
2191
8.1
2213 2482
25.1 0.7
[ Related References ] 1) Tsuge, S.; Hiramitsu, S.; Horibe, T.; Yamaoka, M.; Takeuchi, T. Macromolecules 1975, 8, 721. 2) Blazso, M.; Varhegyi, G. Eur. Polym. J. 1978, 14, 625. 3) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988. 4) Blazso, M.; Ujszaszi, K.; Jakab, E. Chromatographia 1980, 13, 151.
45
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
017
EGA thermogram
Averaged mass spectrum 91 104 117 78
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
129
51
65
39
143
31 50
100
212 216
177 190 157 170
150
244
200
263
294 300 [m/z]
250
( m/z range : 29 - 600 amu )
M : methyl acrylate
S : styrene 55
104
O
O 42
29
103
78
85
51 74
39
68
MMM : trimethyl hex-5-ene-1,3,5-tricarboxylate SM : methyl 4-phenylpent-4-enoate
(M trimer)
131
O
59
O 91
115
O
O
O
167
190 132
63
O
194
106
O
77 51
29 39
O
134
79
125
39
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
227
97
67
29
160 176 159
153
MSM : dimethyl 2-methylene-4-phenylheptanedioate
91
117 O
O
O
O
177 39 51
115 130
65 77
91
208 165 180 193
39
MMS : dimethyl 2-methylene-4-phenethylpentanedioate
129
59 77 65
145
216
157 171
244
SMM : dimethyl 2-(2-phenylallyl)pentanedioate
112
142 O
91
O
O
O
O
O
O
O
129
212
115 140
170
77 91 39
65 59 77
129
157
244
213
185 172
29
39
157
59 65
184 244
276
SSM :methyl 4,6-diphenylhept-6-enoate SMS : methyl 2-phenethyl-4-phenylpent-4-enoate
+ methyl 2-methylene-4,6-diphenylhexanoate
91
117 O
O
O
131
O
+
115 O
91
O
115 39 51 65
77
145
177 189
65 207220
262
294
39 51
77
176 190 143 158 171
203
263
294
46
Tsuge, Ohtani and Watanabe
018 Styrene-methyl acrylate alternating copolymer CH2 CH(C6H5 )
CH2CH(COOCH3)
n
SMS S MSM MS SM MM
SS SSM
MS’
20
10
TIC
M T
αS
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
M T S αS MM MS’ MS SM SS MSM
methyl acrylate 86 toluene 92 styrene 104 α-methylstyrene 118 C=C(COOC)-C-C-COOC (M dimer) 172 C(COOC)-C-C-Ph 178 C=C(COOC)-C-C-Ph (hybrid dimer) 190 C=C(Ph)-C-C-COOC 190 C=C(Ph)-C-C-Ph (S dimer) 208 C=C(COOC)-C-C(Ph)-C-C-COOC 276 C=C(Ph)-C-C(Ph)-C-C-COOC (hybrid trimer) 294 + C=C(COOC)-C-C(Ph)-C-C-Ph C=C(Ph)-C-C(COOC)-C-C-Ph 294 * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
SSM SMS
Molecular Retention Weight Index
Relative Intensity
615 766 892 983 1189 1385 1438 1465 1737 1913
15.9 3.0 100.0 4.2 1.7 3.1 8.9 7.2 5.6 14.4
2191
0.7
2212
27.8
[ Related Reference ] 1) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988.
47
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
018
EGA thermogram
Averaged mass spectrum 117 91 104 100
78
300
400
500
600
700 ºC
programming rate: 20ºC/min
129
55 39
200
65
177
143 157
31 50
100
171
150
190
203 216
244
200
263 300 [m/z]
250
( m/z range : 29 - 600 amu )
M : methyl acrylate
T : toluene 55
91
O
O 85
42
29
39 68
65
51
89
32
αS : α-methylstyrene
S : styrene
118 117
104
103 103
78
78
51
51
39
63
39
MS' : methyl 4-phenylbutanoate 91
63
MS : methyl 2-methylene-4-phenylbutanoate 91
O
O
O
104
O
74
147 29
43 51
130
178
117
78
29
39
65 51
77
158
115
190
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
SM : methyl 4-phenylpent-4-enoate 131
91
O O
115
91
190
77 29 39
51
159
63
39 51
176
MSM : dimethyl 2-methylene-4-phenylheptanedioate
115 130
65 77
208 180 193
SMS : methyl 2-phenethyl-4-phenylpent-4-enoate 91
117 O
O
O
O
O
O
131 115 177 91 39
59 65 77
129 145
157 171
216 212 230 244
65 39 51
77
143 158
176 190 203 234
263
294
48
Tsuge, Ohtani and Watanabe
019 Styrene-methyl methacrylate copolymer; P(S-MMA) CH2 CH(C6H5)
CH2 C(CH3)(COOCH3 )
SS
S
SMS
n
SSS SSM
SM M
MS’ MS 20
TIC
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
M S MS’ MS SM SS
methyl methacrylate 100 styrene 104 C(COOC)=C-C-Ph 176 C=C(COOC)-C-C-Ph (hybrid dimer) 190 C=C(Ph)-C-C(COOC)-C 204 C=C(Ph)-C-C-Ph (S dimer) 208 C=C(Ph)-C-C(Ph)-C-C(COOC)-C 308 (diastereoisomer) C=C(Ph)-C-C(Ph)-C-C(COOC)-C 308 C=C(Ph)-C-C(C)(COOC)-C-C-Ph 308 C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer) 312 * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
SSM SMS SSS
Molecular Retention Weight Index 709 892 1338 1438 1483 1737 2166 2195 2294 2482
[ Related References ] 1) Shimono, T.; Tanaka, M.; Shono, T. J. Anal. Appl. Pyrolysis 1979, 1, 77. 2) Tsuge, S.; Kobayashi, T.; Nagaya, T.; Takeuchi, T J. Anal. Appl. Pyrolysis 1979, 1, 133. 3) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988. 4) Shadrina, N. E.; Dmitrenko, A. V.; Pavlova, V. F.; Ivanchev, S. S. J. Chromatogr. 1987, 404, 183. 5) Dean, L.; Groves, S. ; Hancox, R. ; Lamb, G. ; Lehrle, R. S. Polym. Degrad. Stab. 1989, 25, 143. 6) Atkinson, D. J.; Lehrle, R. S. J. Anal. Appl. Pyrolysis 1991, 19, 319. 7) Wang, F. C.-Y. ; Smith, P. B. Anal. Chem. 1996, 68, 3033. 8) Ohtani, H.; Suzuki, A.; Tsuge, S. J. Polym. Sci., A, Polym. Chem. 2000, 38, 1880. 9) Wang, F. C.-Y. J. Anal. Appl. Pyrolysis 2004, 71, 83.
Relative Intensity 50.1 100.0 0.5 0.3 0.9 1.9 1.3 1.1 1.9 1.8
49
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
019
EGA thermogram
Averaged mass spectrum 104
78
100
103
39
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69
50
91
131
30 50
145
100
172179
191
221
208
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
M : methylmethacrylate
S : styrene
41
104 O
69
O
100
103
78 51
29
59
85
63
39
MS' : (E)-methyl 4-phenylbut-2-enoate
MS : methyl 2-methylene-4-phenylbutanoate 91
116
O
O
O O
91 31
39
51
176
144
89
65
39
161
51
115 130
65 89
32
SM : methyl 2-methyl-4-phenylpent-4-enoate
145
158
176 190
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
145
91 O
O
117129 77 91
204
39 51 63
39 51
173
115
65 77
130
208 151 165 180 193
SMS : methyl 2-methyl-2-phenethyl-4-phenylpent SSM : methyl 2-methyl-4,6-diphenyl hept-6-enoate
-4-enoate 91
131 O
145 O
O
O
91 118 115
44
65
77
191
115 159
221 208
65 248
276
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer) 91
117 3951
6577
129
178
194 207 221
297312
39 51
190
77
204
158172 217
277
50
Tsuge, Ohtani and Watanabe
020 Styrene-methyl methacrylate alternating copolymer CH2CH(C6H5)
CH2C(CH3)(COOCH3)
n
SMS S
SS
MS SM MS’
M
SSM
SSS
10
20
TIC
T 0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
M T S MS’ MS SM SS
methyl methacrylate 100 toluene 92 styrene 104 C(COOC)=C-C-Ph 176 C=C(COOC)-C-C-Ph (mixture of dimer) 190 C=C(Ph)-C-C(COOC)-C 204 C=C(Ph)-C-C-Ph (S dimer) 208 C=C(Ph)-C-C(Ph)-C-C(COOC)-C 308 (diastereoisomer) C=C(Ph)-C-C(Ph)-C-C(COOC)-C 308 C=C(Ph)-C-C(C)(COOC)-C-C-Ph 308 C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer) 312 * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
SSM SMS SSS
Molecular Retention Weight Index 711 766 892 1338 1437 1482 1736 2166 2194 2294 2480
[ Related Reference ] 1) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988.
Relative Intensity 47.3 0.4 100.0 0.6 0.4 0.4 2.6 0.2 0.2 4.7 0.1
51
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
020
EGA thermogram
Averaged mass spectrum 104
78
100
103
39
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69
51
91 131
30 50
145
100
158
190
172
204
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
M : methyl methacrylate
S : styrene 104
41
O
69
O
100
103
78 51
29
59
85
63
39
MS' : (E)-methyl 4-phenylbut-2-enoate
MS : methyl 2-methylene-4-phenylbutanoate 91
115
O
O
O O 176
91 39
51
32
65
144
89
161
32
39
51
115
65
145 158
176 190
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
SM : methyl 2-methyl-4-phenylpent-4-enoate 145
91 O
O
115 129 39 51 63 29
130
77
77 91
204
39 51
173
SSM : methyl 2-methyl-4,6-diphenyl hept-6-enoate
65
115 130 77
165 180 193
208
SMS : methyl 2-phenylethyl-4-phenylpent-4-enoate
131
91 O
145
O
O
O
91 118 115 32
65 77
115
44 59
77
159
191
221
41 51
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer) 91
117 44 32 51 6977
129
165178 194
281
190 204 158172
277
52
Tsuge, Ohtani and Watanabe
021 Methyl methacrylate-butadiene-styrene copolymer; MBS CH2 C(CH3)(COOCH3 )
CH2 CH
CHCH2
CH2 CH(C6H5)
n
SSS S
SS M
D 20
10
EB TIC B
T 0
V
αS 10
Peak Notation
Assignment of Main Peaks
B M T V EB S αS D SS SSS
1,3-butadiene methyl methacrylate toluene 4-vinylcyclohexene ethylbenzene styrene α -methylstyrene C(Ph)-C-C-Ph C=C(Ph)-C-C-Ph (S dimer) C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer)
30 [min]
20
Molecular Retention Weight Index 54 100 92 108 106 104 118 196 208 312
*bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
395 710 766 835 866 892 983 1668 1736 2482
Relative Intensity 5.0 59.1 2.7 3.4 0.9 100.0 2.5 0.9 3.2 9.3
53
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
021
EGA thermogram
Averaged mass spectrum 91 104 39 78
100
200
300
400
500
69
600
700 ºC
programming rate: 20ºC/min
117
51
129 30 50
143
100
165
150
194 207 221
312
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
M : methyl methacrylate
B : 1,3-butadiene 39
41 O
69 54 O
100 29
59
85
31
V : 4-vinylcyclohexene
T : toluene
79
91
39
54 93
66 39
65
51
89
108
29
S : styrene
EB : ethylbenzene 91
104
103
78 106 51 39
51
65
78
63
39
32
αS : α−methylstyrene
D : 1,3-diphenylpropane 118 117
92
103 105 39
196
65 77
78
51 63
41 51
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
128 141 152
170
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
91
91
117 39 51
65
115 130 77
208 180 193
51
6577
129
194207 178
297 312
54
Tsuge, Ohtani and Watanabe
022 Acrylonitrile-styrene copolymer; AS CH2CH(C6H5)
CH2CH(CN)
ASA
S
AS SA
n
SAS
AAS SAA SSA
SA’ αS
SS
AA
ASS
20
10
TIC
A
T
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Weight Index
A T S αS AA AS SA SA’ SS AAS ASA SAA ASS SSA SAS
acrylonitrile 53 toluene 92 styrene 104 α-methylstyrene 118 C=C(CN)-C-C-CN (A dimer) 106 C=C(CN)-C-C-Ph 157 C=C(Ph)-C-C-CN (hybrid dimer) 157 C-C(Ph)-C-C-CN 159 C=C(Ph)-C-C-Ph (S dimer) 208 C=C(CN)-C-C(CN)-C-C-Ph 210 C=C(CN)-C-C(Ph)-C-C-CN 210 C=C(Ph)-C-C(CN)-C-C-CN (hybrid trimer) 210 C=C(CN)-C-C(Ph)-C-C-Ph 261 C=C(Ph)-C-C(Ph)-C-C-CN 261 C=C(Ph)-C-C(CN)-C-C-Ph 261 * bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
565 766 892 983 1059 1342 1424 1435 1737 1812 1846 1866 2129 2175 2200
[ Related References ] 1) Vukovic, R. ; Gnjatovic, V. J. Polym. Sci. A-1 1970, 8, 139. 2) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988. 3) Blazso, M.; Varhegyi, G.; Jakab, E. J. Anal. Appl. Pyrolysis 1980, 2, 177. 4) Blazso, M.; Ujszaszi, K.; Jakab, E. Chromatographia 1980, 13, 151. 5) Nagaya, T.; Sugimura, Y.; Tsuge, S. Macromolecules 1980, 13, 353. 6) Shadrina, N. E.; Dmitrenko, A. V.; Pavlova, V. F.; Ivanchev, S. S. J. Chromatogr. 1987, 404, 183.
Relative Intensity 5.6 1.0 100.0 1.2 2.7 9.3 8.4 2.5 2.9 7.2 19.1 7.4 3.1 2.9 15.1
55
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
022
EGA thermogram
Averaged mass spectrum 91
104
78
100
39
65
300
400
500
170
700 ºC
150
261 255
210 220
182 193 100
600
programming rate: 20ºC/min
156
129
50
200
144
115
51
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
A : acrylonitrile
S : styrene 104
53
N 103
78 38
51 63
39
SA : 4-phenylpent-4-enenitrile
AS : 2-methylene-4-phenylbutanenitrile 91
115
N
N
157
91 103
77
130
51 39
51
65 77
128
AAS : 2-methylene-4-phenethylpentanedinitrile 91
ASA : 2-methylene-4-phenylheptanedinitrile 144
N
N
65 51
91 104 117
77
119
143
156 195
118 115
77
77
39 51
209
N
103
129
210
170
39 51
182
210
N
65 77
128
156169
91
N
261
N 170
115 118
91 115 118
65 220 233 205
195
SAS : 2-phenethyl-4-phenylpent-4-enenitrile
144
77
182
117 142 156
SSA : 4,6-diphenylhept-6-enenitrile
39 51 65
157
91
N
91
65
127
ASS : 2-methylene-4,6-diphenylhexanenitrile
SAA : 2-(2-phenylallyl)pentanedinitrile
39 51
N
N
105 39
142
63
39
157
261
39 51
77
105
156 142 246261
56
Tsuge, Ohtani and Watanabe
023 Acrylonitrile-styrene alternating copolymer CH2CH(CN)
CH2CH(C6H5)
S
ASA
AS SA SA’ αS
AA
AAS SAA SS
n SAS
SSA ASS 20
10
TIC
A
T
0
10
Peak Notation
Assignment of Main Peaks
A T S αS AA AS SA SA’ SS AAS ASA SAA ASS SSA SAS
acrylonitrile toluene styrene α-methylstyrene C=C(CN)-C-C-CN (A dimer) C=C(CN)-C-C-Ph C=C(Ph)-C-C-CN (hybrid dimer) C-C(Ph)-C-C-CN C=C(Ph)-C-C-Ph (S dimer) C=C(CN)-C-C(CN)-C-C-Ph C=C(CN)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-CN (hybrid trimer) C=C(CN)-C-C(Ph)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-Ph
30 [min]
20
Molecular Retention Weight Index 53 92 104 118 106 157 157 159 208 210 210 210 261 261 261
566 765 892 983 1058 1341 1422 1434 1734 1809 1844 1863 2126 2172 2199
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group) [ Related Reference ] 1) Tsuge, S.; Kobayashi, T.; Sugimura, Y.; Nagaya, T.; Takeuchi, T. Macromolecules 1979, 12, 988.
Relative Intensity 5.5 1.1 100.0 0.9 2.0 8.8 7.4 2.0 2.8 1.2 19.2 0.9 1.7 1.6 18.2
57
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
023
EGA thermogram
Averaged mass spectrum 104
91
78
100
200
300
400
500
144
51
600
700 ºC
programming rate: 20ºC/min
117 39
65
156
129
50
170 210
182 193
100
150
261
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
S : styrene
A : acrylonitrile
104
53
N 103
78 51
38 39
AS : 2-methylene-4-phenylbutanenitrile
AA : 2-methylpentanedinitrile (A dimer) 66
N
39
63
91
N
N
106
52 79
39
92
51
65 77
157
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
SA : 4-phenylpent-4-enenitrile 115
N
128 140
91 157
77
51 39
91 103 129 142
63
39 51
165 180 193
91
N
N
115 130 104
77
208
ASS : 2-methylene-4,6-diphenylhexanenitrile
ASA : 2-methylene-4-phenylheptanedinitrile 144
65
91
N
117 117
39 51 63
77
128
157
182
65 77 39 51
210
SSA : 4,6-diphenylhept-6-enenitrile
156169
91
N
115 77
65 205
220233
261
N 170
115 118
91
118
195
SAS : 2-phenethyl-4-phenylpent-4-enenitrile
144
39 51 65
128
260
39 51
77
105
156 142 246261
58
Tsuge, Ohtani and Watanabe
024 Acrylonitrile-butadiene-styrene copolymer; ABS CH2CH
CHCH2
m
+
CH2CH(CN)
CH2 CH(C6H5)
n
SAS
S
AS
SA
AAS ASA
SS
SA’
SSA ASS
SAA SSS
AA 10
TIC
B
A
T
0
V
20
S 10
Peak Notation
Assignment of Main Peaks
B A T V S S AA AS SA SA’ SS AAS ASA SAA ASS SSA SAS SSS
1,3-butadiene acrylonitrile toluene 4-vinylcyclohexene styrene -methylstyrene C=C(CN)-C-C-CN (A dimer) C=C(CN)-C-C-Ph C=C(Ph)-C-C-CN (hybrid dimer) C-C(Ph)-C-C-CN C=C(Ph)-C-C-Ph (S dimer) C=C(CN)-C-C(CN)-C-C-Ph C=C(CN)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-CN (hybrid trimer) C=C(CN)-C-C(Ph)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer)
30 [min]
20
Molecular Retention Weight Index 54 53 92 108 104 118 106 157 157 159 208 210 210 210 261 261 261 312
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
395 560 766 835 892 983 1058 1342 1424. 1435 1736 1811 1843 1865 2129 2175 2200 2479
Relative Intensity 0.7 3.4 1.9 0.4 100.0 1.8 1.0 7.6 5.7 1.5 5.1 1.5 6.2 1.7 4.3 3.6 10.1 0.7
59
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
024
EGA thermogram
Averaged mass spectrum 104
91
78
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51 39
117
144
65
156
129
50
100
170
150
182 193
261 255
210 220 233 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
A : acrylonitrile
S : styrene 104
53
N 103
78 51
38
63
39
68
AS : 2-methylene-4-phenylbutanenitrile 91
SA : 4-phenylpent-4-enenitrile 115
N
N
157
39
51
77
39
157
115 128 140
129 142
63
32
SA' : 4-phenylpentanenitrile
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
103
91
N 169
77 39
103
77
51 65
154 115
51
141
63
128
39 51
ASA : 2-methylene-4-phenylheptanedinitrile 144
65
180 193
208
ASS : 2-methylene-4,6-diphenylhexanenitrile 91
N
N
115 130 104 77
N
91 117
104 39 51
77
128
66
157 170182
194 210
39 51
SSA : 4,6-diphenylhept-6-enenitrile 144
65 77
77
156 169
91
65 260 202220233244
261
N 115 118
115 118 157 170
195
SAS : 2-phenethyl-4-phenylpent-4-enenitrile N
91
39 51 65
128
39 51
77
105
170 156 142 178
246 261
60
Tsuge, Ohtani and Watanabe
025 Acrylonitrile-acrylate-styrene copolymer; AAS CH2CH(COOC4 H9)
m
+
CH2CH(CN)
CH2CH(C6 H5 )
n
SAS
S
SSA AS αS AA
SA
AAS SS
SA’
ASA ASS SAA SSS 20
10
TIC
B A
BO T
0
10
Peak Notation
Assignment of Main Peaks
B A BO T S αS AA AS SA SA’ SS AAS ASA SAA ASS SSA SAS SSS
1-butene acrylonitrile 1-butanol toluene styrene α-methylstyrene C=C(CN)-C-C-CN (A dimer) C=C(CN)-C-C-Ph C=C(Ph)-C-C-CN (hybrid dimer) C-C(Ph)-C-C-CN C=C(Ph)-C-C-Ph (S dimer) C=C(CN)-C-C(CN)-C-C-Ph C=C(CN)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-CN (hybrid of trimer) C=C(CN)-C-C(Ph)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer)
30 [min]
20
Molecular Retention Weight Index 56 53 74 92 104 118 106 157 157 159 208 210 210 210 261 261 261 312
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
383 568 657 765 892 982 1057 1341 1422 1434 1734 1809 1842 1864 2128 2172 2199 2478
Relative Intensity 1.6 3.3 1.1 1.6 100.0 1.6 0.9 6.4 5.4 1.1 5.1 1.5 7.0 1.7 6.0 5.1 11.1 1.0
61
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
025
EGA thermogram
Averaged mass spectrum 104
91 78
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
117
39
144
65
129
50
100
170
156
31
150
193
208 220 233 246 200
260 300 [m/z]
250
( m/z range : 29 - 600 amu )
B : 1-butene
A : acrylonitrile 39
53
N
56 38 29
S : styrene
AS : 2-methylene-4-phenylbutanenitrile 91
104
103
78 51 39
39
63
SA : 4-phenylpent-4-enenitrile
51
65
157
77
115 128 140
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
115
N
N
91 157
103 77
51
129
63
39
142
39 51
91 39 51
91
N
N
N
117
77
128
66
157
182
210
39 51
65 77
128
156 169
195
261
SAS : 2-phenethyl-4-phenylpent-4-enenitrile
144
91
N
N 115 118
91
77
208
104 117
SSA : 4,6-diphenylhept-6-enenitrile
39 51 65
165 178 193
ASS : 2-methylene-4,6-diphenylhexanenitrile
ASA : 2-methylene-4-phenylheptanedinitrile 144
115 130
65 77
105
115 118
170 156
77 65 170
203
220 233
260
39 51
142 246261
62
Tsuge, Ohtani and Watanabe
026 Acrylonitrile-EPDM-styrene copolymer; AES CH2CH2
CH2CH(CH3)
X
m
+
CH2CH(CN)
CH2CH(C6H5)
n
SAS S ASA AS SA
AAS SS
SSA SAA ASS
SA’ S AA
SSS 10
20
TIC
A
T
0
10
Peak Notation
Assignment of Main Peaks
A T S S AA AS SA SA’ SS AAS ASA SAA ASS SSA SAS SSS
acrylonitrile toluene styrene -methylstyrene C=C(CN)-C-C-CN (A dimer) C=C(CN)-C-C-Ph C=C(Ph)-C-C-CN (mixture of dimer) C-C(Ph)-C-C-CN C=C(Ph)-C-C-Ph (S dimer) C=C(CN)-C-C(CN)-C-C-Ph C=C(CN)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-CN (mixture of trimer) C=C(CN)-C-C(Ph)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-CN C=C(Ph)-C-C(CN)-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer)
30 [min]
20
Molecular Retention Weight Index 53 92 104 118 106 157 157 159 208 210 210 210 261 261 261 312
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group)
563 766 891 982 1057 1341 1422 1434 1734 1809 1842 1864 2126 2172 2197 2478
Relative Intensity 3.9 1.9 100.0 1.4 1.7 8.8 7.5 1.8 4.8 2.9 9.3 3.4 4.6 4.1 12.2 0.5
63
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
026
EGA thermogram
Averaged mass spectrum 91
104
78 100
200
300
400
500
117
39
65
144 129
50
156
100
600
700 ºC
programming rate: 20ºC/min
51 170
150
261 255
210 220
182 193 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
S : styrene
A : acrylonitrile 53
104
N 103
78 38
51 63
39
SA : 4-phenylpent-4-enenitrile
AS : 2-methylene-4-phenylbutanenitrile 91
N
115
N
157
91 103
77
130
51 39
51
65 77
157
128
104
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
142
63
39
AAS : 2-methylene-4-phenethylpentanedinitrile
91
91
N
N
105 39 51
65
104115 130
77
39
208 180 193
ASA : 2-methylene-4-phenylheptanedinitrile 144
65 77
51
91
91
66
128
157168 182
210
39 51
SSA : 4,6-diphenylhept-6-enenitrile
182
209
N
65 77
128
169
91
N
N 115 118
91
105
115 104
65
77 220233
261
SAS : 2-phenethyl-4-phenylpent-4-enenitrile
144
39 51 65
156
117
104 117 39 51
77
143
ASS : 2-methylene-4,6-diphenylhexanenitrile N
N
119
260
39 51
77
170 156
142 129
246261
64
Tsuge, Ohtani and Watanabe
027 Styrene-maleic anhydride copolymer; P(S-Mah) CH2 CH(C6H5)
CH(CO) CH(CO)
n
O S
SSS
SS
D1
D5 D2 MS D6
MA
TIC
T
20
10
αS AB
0
10
Peak Notation
Assignment of Main Peaks
T MA S AB αS D1 D2 MS SS D5 D6 SSS
toluene maleic anhydride styrene allyl benzene α-methylstyrene C(Ph)-C-Ph C-C(Ph)-C-Ph (hybrid dimer) C=C(Ph)-C-C-Ph (S dimer) C=C(Ph)-C-C(Ph)-C C(Ph)=C-C-C-Ph C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer)
30 [min]
20
Molecular Retention Weight Index 92 98 104 118 118 182 196 202 208 222 208 312
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group) [ Related References ] 1) Yamaguchi, S. ; Hirano, J. ; Isoda, Y. J. Anal. Appl. Pyrolysis 1989, 16, 159 2) Wang, F. C.-Y. J. Chromatogr. A 1997, 765, 279. 3) Wang, F. C.-Y. J. Anal. Appl. Pyrolysis 2004, 71, 83.
764 848 892 947 982 1536 1568 1661 1735 1746 1837 2181
Relative Intensity 2.0 1.3 100.0 0.7 1.8 2.1 1.9 1.5 7.1 1.2 1.6 8.1
65
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
027
EGA thermogram
Averaged mass spectrum 104 91
78
100
200
300
400
500
39
600
700 ºC
programming rate: 20ºC/min
51 117
63
129 50
141 153 165 179 194 207 221
100
150
200
312 250
350 [m/z]
300
( m/z range : 29 - 600 amu )
MA : maleic anhydride
S : styrene 54
O
O
104
O 103
78 51 98
44
29
αS : α-methylstyrene
39
63
D1 : 1,2-diphenylethan 91
118 117 103 78 51
39
91
182
65
63
39
D2 : propane-1,2-diyldibenzene
89
51
104
128 139 152 165
MS : (hybrid dimer) 129
105 115
202 174
51 39
51
65
77
39
91 165 178
63 77
SS : 3-butene-1,3-diyldibenzene (styrene dimer)
D5 : 1-pentene-2,4-diylbenzen
91
39 51
105
115
115 130 104
65 77
208 180 193
77
115
179
194 222
117
65 77
165
91
117
39 51
91
39 51 65
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
D6 : (E)-1-butene-1,4-diyldibenzene
91
145 156
102
196
152
178190
208
39 51
6577
129
194207 221
297312
66
Tsuge, Ohtani and Watanabe
028 Styrene-divinylbenzene copolymer; P(S-DVB) CH2CH(C6H5 )
CH2CH(C6 H4)
CH2CH(C6H4 CH2CH3)
n
CHCH2 SS
S
SSS ES DV D5 αS MS
DS D7
D1 D4
TS
D6
10
20
TIC
T 0
10
Peak Notation
Assignment of Main Peaks
T S αS
D1 D4 SS D5 D6 D7
toluene styrene α-methylstyrene m-methylstyrene p-methylstyrene m-ethylstyrene p-ethylstyrene m-divinylbenzene p-divinylbenzene C(Ph)-C-Ph C(Ph)-C-C-Ph C=C(Ph)-C-C-Ph (S dimer) C=C(Ph)-C-C(Ph)-C C(Ph)=C-C-C-Ph C=C(Ph)-C-C-C(Ph)=C
DS
(hybrid dimer)
SSS TS
C=C(Ph)-C-C(Ph)-C-C-Ph (S trimer) C=C(Ph)-C-C(Ph)-C-C-Ph (hybrid trimer)
MS ES DV
30 [min]
20
Molecular Retention Weight Index 92 104 118 118 118 132 132 130 130 182 196 208 222 208 234 248 234 312 312
* bonding hydrogen is omitted ; Ph represents C6H5 (phenyl group) [ Related References ] 1) Nakagawa, H.; Tsuge, S. Macromolecules 1985, 18, 2068. 2) Nakagawa, H.; Matsushita, Y.; Tsuge, S. Polymer 1987, 28, 1512.
766 892 983 944 998 1087 1104 1116 1129 1536 1666 1735 1747 1836 1910 1940 1947 2487 2582
Relative Intensity 1.2 100.0 1.1 0.5 0.1 4.8 1.4 4.1 1.6 1.2 0.2 7.1 0.7 0.5 1.3 0.8 0.8 6.5 0.4
67
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
028
EGA thermogram
Averaged mass spectrum 104 78
91 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51 117
39
63
130
50
152 165 178 193 207
100
150
200
234
312 250
350 [m/z]
300
( m/z range : 29 - 600 amu )
ES : m-ethylstyrene
S : styrene
117
104
103
78
132 115
51 39
63
51
39
ES : p-ethylstyrene
91
77
63
DV : m-divinylbenzene 117
130
132
115
115 51
39
91
77
63
51
39
DV : p-divinylbenzene
102
91
115 51
63
SS : 3-butene-1,3-diyldibenzene (styrene dimer) 130
39
77
77
63
103
39 51
DS : (hybrid dimer)
104115 130
65 77
208 193
DS : (hybrid dimer)
91
117 131
115 65 39 51
130
91
77
234 141
234 205 248 220
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
77
39 51 65
143 156
TS : (hybrid trimer) 129
91 91
207 117 6577 39 51
65 77
129
178
194207 221
297 312
32 39 51
105 143
178 191 165
219
254
312
68
Tsuge, Ohtani and Watanabe
2.2.4 Vinyl polymers with styrene units’ derivatives 029 Poly(α α-methylstyrene); P-α-MS CH2C(CH3)(C6H5)
n
αS S PX
PP
T BA
B
2
3
4
5
6
7
8
9
TIC
0
10
Peak Notation
Assignment of Main Peaks
B T PX S BA αS PP
benzene toluene p-xylene styrene benzaldehyde α-methylstyrene 2-phenylpropenal [ Related Reference ] 1) Okumoto, T.; Takeuchi, T. Bull. Chem. Soc. Jpn 1973, 46, 1717.
30 [min]
20
Molecular Retention Weight Index 78 92 106 104 106 118 132
658 764 869 890 961 985 1158
Relative Intensity 0.02 0.02 0.03 0.03 0.02 100.0 0.03
69
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
029
EGA thermogram
Averaged mass spectrum 118 117 103 100
78
51
200
300
400
500
39
600
700 ºC
programming rate: 20ºC/min
91
63
50
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
B : benzene
T : toluene 78
91
39 51
63 32
PX : p-xylene
S : styrene 104
91
106 78 103
77
39
51
50
65 38
63
αS : α-methylstyrene
BA : benzaldehyde 105
118
O
77
117 103
51
78 39
PP : 2-phenylpropenal 103
O
104 77 51 44
63
132
51
63
91
70
Tsuge, Ohtani and Watanabe
030 Polydivinylbenzene; PDVB CH2CH(C6H4)
CH2CH(C6H4CH2CH3)
n
CHCH2 dimer D2
ES
DV D1
MS 10
EB
20
PS
S
TIC
PB
0
DD 10
Peak Notation
Assignment of Main Peaks
EB S PB
ethylbenzene styrene isopropylbenzene m-methylstyrene p-methylstyrene m-ethylstyrene p-ethylstyrene m-divinylbenzene p-divinylbenzene m-isopropenylstyrene 1-dodecanol dimer (DVB) dimer (DVB)
MS ES DV PS DD D1 D2
[ Related Reference ] 1) Nakagawa, H.; Tsuge, S. Macromolecules 1985, 18, 2068.
30 [min]
20
Molecular Retention Index Weight 106 866 104 896 120 969 118 999 118 1006 132 1097 132 1104 130 1120 130 1140 144 1210 186 1478 264 2083 262 2124
Relative Intensity 3.3 2.8 7.6 21.6 9.5 100.0 36.6 61.2 27.4 12.7 5.8 1.9 9.0
71
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
030
EGA thermogram
Averaged mass spectrum 117
100
39
51
77
63
300
400
500
600
700 ºC
programming rate: 20ºC/min
103
50
200
132 130
91
144
100
169
150
205
236 248
200
262 300 [m/z]
250
( m/z range : 29 - 600 amu )
EB : ethylbenzene
S : styrene 104
91
106
103
78 51
51
39
63
77
63
39
MS : m-methylstyrene
PB : isopropylbenzene
117 118
105
91
120 39
51
65
77
91
39
ES : m-ethylstyrene
51
63
77
DV : m-divinylbenzene 130
117
132 115
115 91 51
39
63
51
77
39
PS : m-isopropenylstyrene
63
77
102
DD : 1-dodecanol 144
55 41
OH
69 83
128
97 29
104 51
39
63
77
111
103
125
D1 : dimer (DVB)
91 41 51 65
155 168
D2 : dimer (DVB) 117
119
77
140
91 117 132
235 158
219
248
264
248 262
130 39 51 65
77
156
233
72
Tsuge, Ohtani and Watanabe
031 Poly(p-chlorostyrene) CH2CH(C6 H4 Cl)
n
CC
C
CCC CB
IC
d
b a
c 20
10
TIC
CT
C’
0
10
Peak Notation
Assignment of Main Peaks
CT C’ C CB IC a b CC c d CCC
p-chlorotoluene chlorostyrene ( m- and o- ) p-chlorostyrene p-chlorobenzaldehyde 4-chloroisopropenylbenzene C(Ph)=C-C-PhCl ? C(PhCl)-C-PhCl C=C(PhCl)-C-C-PhCl (dimer) C(PhCl)=C-C-C-PhCl C=C(PhCl)-C-C-C(PhCl)=C C=C(PhCl)-C-C(PhCl)-C-C-PhCl (trimer)
30 [min]
20
Molecular Retention Weight Index 126 138 138 140 152 228 ? 250 276 276 302 414
958 1071 1080 1130 1170 1906 1975 2168 2288 2328 3150
* bonding hydrogen is omitted ; PhCl represents C6H4Cl (4-chlorophenyl group) ; Ph represents C6H5 (phenyl group) [ Related References ] 1) Okumoto, T.; Takeuchi, T.; Tsuge, S. Macromolecules 1973, 6. 922. 2) Okumoto, T.; Tsuge, S.; Yamamoto, Y.; Takeuchi, T. Macromolecules 1974, 7, 376. 3) Bertini, F.; Audisio, G.; Kiji, J. J. Anal. Appl. Pyrolysis 1994, 28, 205. 4) Zuev, V. V.; Bertini, F ; Audisio, G. Polym. Degrad. Stab. 2001, 71, 213.
Relative Intensity 0.8 1.7 100.0 0.3 0.5 0.4 1.3 9.4 0.6 1.4 5.6
73
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
031
EGA thermogram
Averaged mass spectrum 138
103
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
77 51 63
39
112125 151164
50
100
241
150
200
250
276
414 300
350
400
450 [m/z]
( m/z range : 29 - 600 amu )
CT : p-chlorotoluene
C' : m-chlorostyrene and o-chlorostyrene 91
103
138
Cl + Cl 126 63 39
Cl
77 75
51
89
50
39
C : p-chlorostyrene
CB : p-chlorobenzaldehyde 138
139
O
103 111
Cl 51
75
50
77 75
Cl
77
112
39
38
123
a : 1-chloro-4-cinnamylbenzene ? 165 178
b : 1,2-bis(4-chlorophenyl)ethane 125
228
193
Cl Cl
Cl 115 125
75 89
39 51 32
139
89
152 39 51 63
99
139
250
178
CC : 4,4'-(but-3-ene-1,3-diyl)bis(chlorobenzene) (dimer)
c : (E)-4,4'-(but-1-ene-1,4-diyl)bis(chlorobenzene) Cl
125
Cl
151
Cl
115 Cl 125
51
75
89
115 89 101
138
39 51 63
276
241
101
276
202
CCC : 4,4',4''-(hex-5-ene-1,3,5-triyl) d : 4,4'-(hexa-1,5-diene-2,5-diyl)bis(chlorobenzene) 129
tris(chlorobenzene) (trimer) 125
Cl
Cl
Cl
Cl
115 138
3951
101 75 89
164 151 177
Cl 202
302
89 115 138 51 75
275 262
416
74
Tsuge, Ohtani and Watanabe
032 Poly(p-methylstyrene); PMS CH2CH(C6H4 CH3)
n
MMM
M
MM c IP
a
d
b
20
10
S
TIC
X
ET
0
10
Peak Notation
Assignment of Main Peaks
X S ET M IP
p-xylene styrene p-ethyltoluene p-methylstyrene p-isopropenyltoluene C(PhC)-C-C-PhC C(PhC)=C-C-PhC C=C(PhC)-C-C-PhC (dimer) C(PhC)=C-C-C-PhC ? C=C(PhC)-C-C(PhC)=C C=C(Ph)-C-C(PhC)-C-C-PhC C=C(PhC)-C-C(PhC)-C-C-PhC (trimer)
a MM b c d MMM
30 [min]
20
Molecular Retention Weight Index 106 104 120 118 132 224 222 236 236 248 340 354
870 890 964 1000 1090 1877 1882 1946 2295 2084 2663 2745
* bonding hydrogen is omitted ; PhC represents C6H4CH3 (p-tolyl group) ; Ph represents C6H5 (phenyl group)
[ Related References ] 1) Schroeder, U. K. O.; Ederer, H. J.; Ebert, K. H. Makromol. Chem. 1987, 188, 561. 2) Nakagawa, H.; Tsuge, S.; Mohanraj, S.; Ford, W. T. Macromolecules 1988, 21, 930. 3) Luda, M. P.; Guaita, M.; Chiantore, O. Makromol. Chem., Macromol. Symp. 1989, 25, 101. 4) Zuev, V. V. ; Bertini, F. ; Audisio, G. Polym. Degrad. Stab. 2001, 71, 213.
Relative Intensity 2.1 6.2 0.1 100.0 0.6 0.4 0.4 2.8 0.3 2.1 0.6 6.8
75
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
032
EGA thermogram
Averaged mass spectrum 117
100
200
300
400
500
91
600
700 ºC
programming rate: 20ºC/min
105 39 51 63 77 144156 50
100
207 221 236248
178
150
200
354
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
X : p-xylene
S : styrene 91
104
106
51
39
78
77
65
63
39
M : p-methylstyrene
a : 1,3-bis(4-tolyl)propane 106
117 118
91
51
119
224
77
91 39
103
51
65
63
39 51 32
89
132
MM : 4,4'-(but-3-ene-1,3-diyl)bis(methylbenzene) (dimer)
a : 1,3-bis(4-tolyl)-1-propene 117
105
105
40 50 64 89
222 130
255
327
405
b : (E)-4,4'-(but-1-ene-1,4-diyl)bis(methylbenzene)
39 51 65
77 91
236 91
77 144
51 65
248 233
MMM : (Z)-4,4',4''-(hex-5-ene-1,3,5-triyl)tris
(methylbenzene)
(methylbenzene) (trimer)
105
115 131 143
130 156 141
3951 65 77
d : 4,4''-(5-phenylhex-5-ene-1,3-diyl)bis
91
221
117
91 106
77 65
144
105
207221 193
340
403
236
c : 4,4'-(penta-1,4-diene-2,4-diyl)bis(methylbenzene)
117
39
118
91 6577
131 143
222235
354
76
Tsuge, Ohtani and Watanabe
033 Poly(2-vinylpyridine) CH2CH(C5H4N)
n
VV
V
IP
VVV
c b d
a
e
10
TIC
20
MP
0
10
Peak Notation
Assignment of Main Peaks
MP V IP a VV b c d e VVV
2-methylpyridine 2-vinylpyridine 2-isopropenylpyridine C(C5N)-C-C-C5N C=C(C5N)-C-C-C5N (dimer) C=C-C(C5N)=C-C-C5N C(C5N)=C-C-C-C5N C=C(C5N)-C=C-C5N C=C(C5N)-C-C(C5N)=C C(C5N)=C-C(C5N)-C-C-C5N (trimer)
30 [min]
20
Molecular Retention Weight Index 93 105 119 198 210 222 210 208 222 301
811 933 1023 1613 1832 1921 1935 1988 2101 2619
Relative Intensity 1.9 100.0 1.9 1.8 29.1 1.2 0.6 2.4 0.7 27.1
* bonding hydrogen is omitted ; C5N represents 2-pyridyl group [ Related Reference ] 1) Ohtani, H. ; Kotsuji, ; H. Momose, H. ; Matsushita, Y. ; Noda, I. ; Tsuge, S. Macromolecules 1999, 32, 6541.
77
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
033
EGA thermogram
Averaged mass spectrum 79 105 51
100
93
200
300
210
65
144 154
50
500
600
700 ºC
programming rate: 20ºC/min
132
39
400
118
100
169
223
195
182
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
V : 2-vinylpyridine
MP : 2-methylpyridine 93
N
105
N 79
66 51
39
78
51
39
74
a : 1,3-bis(4-pyridyl)propane
IP : 2-isopropenylpyridine 118
106
N N
N 184
79
51
39
93
63
N
65
N
51 39
169
N
130
118 117 78
130 141 154
92
b : (Z)-4,4-(penta-2,4-diene-1,3-diyl)dipyridine
VV : 4,4'-(but-3-ene-1,3-diyl)dipyridine (dimer) 132
78
51
39
N
117 144
78
195 209
93
51
65
39
154 169181
c : 1,4-di(pyridin-4-yl)butane
195
104 93
65
221 210
168
d : (Z)-4,4-(buta-1,3-diene-1,3-diyl)dipyridine
93
N
N
193
N
117 132 N 130 39
51 65 78
195 210
106
51 63 78 39
96
140
208
165
VVV : (Z)-4,4',4''-(pent-1-ene-1,3,5-triyl)tripyridine e : 4,4'-(penta-1,4-diene-2,4-diyl)dipyridine N
N
(trimer) 210
144
223
N
N
N
118 93 130
39
51
78 63
90
78
222
117 130 105 167
194206
39
51 65
106
144
195 169 286
315
78
Tsuge, Ohtani and Watanabe
034 Acrylonitrile-p-chlorostyrene copolymer CH2CH(CN)
CH2 CH(C6H4Cl)
n
CAC
C ACA AC CA’ AAC
CAA CC
CCA ACC
AC’ CB
IC
CCC
A
S
20
10
AA TIC
CT
0
10
Peak Notation
Assignment of Main Peaks
A S CT AA C CB IC AC AC’ CA’ AAC ACA CAA CC ACC CCA CAC CCC
acrylonitrile styrene p-chlorotoluene C=C(CN)-C-C-CN (A dimer) p-chlorostyrene p-chlorobenzaldehyde 4-chloroisopropenylbenzene C=C(CN)-C-C-PhCl C(PhCl)-C-C-CN (hybrid dimer) C=C(PhCl)-C-C(CN)-C C=C(CN)-C-C(CN)-C-C-PhCl C=C(CN)-C-C(PhCl)-C-C-CN (hybrid trimer) C=C(PhCl)-C-C(CN)-C-C-CN C=C(PhCl)-C-C-PhCl (C dimer) C=C(CN)-C-C(PhCl)-C-C-PhCl C=C(PhCl)-C-C(PhCl)-C-C-CN (hybrid trimer) C=C(PhCl)-C-C(CN)-C-C-PhCl C=C(PhCl)-C-C(PhCl)-C-C-PhCl (C trimer)
30 [min]
20
Molecular Retention Weight Index 53 104 126 106 138 140 152 191 179 205 244 244 244 276 329 329 329 414
570 889 957 1056 1081 1128 1168 1562 1558 1644 2051 2075 2101 2179 2597 2629 2657 3144
* bonding hydrogen is omitted ; PhCl represents C6H4Cl (4-chlorophenyl group) [ Related Reference ] 1) Okumoto, T.; Tsuge, S.; Yamamoto, Y.; Takeuchi, T. Macromolecules 1974, 7, 376.
Relative Intensity 2.1 0.1 1.2 1.1 100.0 0.7 1.0 6.3 0.7 7.5 4.1 8.2 3.3 4.2 2.9 2.4 9.7 0.4
79
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
034
EGA thermogram
Averaged mass spectrum 138 103 125 100
200
300
400
500
600
77 75
51
700 ºC
programming rate: 20ºC/min
178
115
39 50
152 165
100
190
150
244
202 216 200
276
329
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
C : p-chlorostyrene
A : acrylonitrile
138
53
N 103
38
Cl
77 75
51
112
39
AC : 4-(4-chlorophenyl)-2-methylenebutanenitrile 125
CA' : 4-(4-chlorophenyl)-2-methylpent-4-enenitrile
N
Cl
115 N
75 39
89
51 63
99
115
138
39 51 63
191
156
191
129 151 137
Cl 101 89
168 176
203
AAC : 2-(4-chlorophenethyl)ACA : 4-(4-chlorophenyl)-2-methyleneheptanedinitrile
4-methylenepentanedinitrile 125
N
N
178
Cl N
Cl 89 39 51 63
77
125 103115
N
139
106 103
156
244
190
77
39 51
138 151 244
CC : 4,4'-(but-3-ene-1,3-diyl)bis(chlorobenzene) CAA : 2-(2-(4-chlorophenyl)allyl)pentanedinitrile 115
152
(C dimer)
Cl
Cl
125 N
39 51
75 89
102
127137
163
177 190 204
N 244
75
39 51
ACC : 4,6-bis(4-chlorophenyl)-
115 89 101
Cl 138
164
241
276
CAC : 2-(4-chlorophenethyl)-4-
2-methylenehexanenitrile
(4-chlorophenyl)pent-4-enenitrile
125
125
Cl
Cl
115
N
N 152
75 39 51 75
89103 115 138
263
329 355
Cl
39 51
89 101
139 204 190 177
Cl 329
80
Tsuge, Ohtani and Watanabe
035 Chloromethylated styrene-divinylbenzene copolymer CH2CH(C6H5)
CH2CH(C6H4)
CS
S
X
TIC
LB B
T
S EB
CH2CH(C6H4CH2Cl)
n
CHCH2
MS ET ME DE DM ES
0
D dimers
10
Peak Notation
Assignment of Main Peaks
LB B T EB X S ET S MS ME DE DM ES CS D
hydrogen chloride etc. benzene toluene ethylbenzene p-xylene styrene p-ethyltoluene -methylstyrene p-methylstyrene p-isopropyltoluene p-diethylbenzene ,p-dimethylstyrene p-ethylstyrene p-chloromethylstyrene unidentified
30 [min]
20
Molecular Retention Weight Index 36 78 92 106 106 104 120 118 118 134 134 132 132 152 210
[ Related References ] 1) Nakagawa, H.; Tsuge, S.; Mohanraj, S.; Ford, W. T. Macromolecules 1988, 21, 930. 2) Boinon, B.; Ainad-Tabet, D.; Montheard, J. P. J. Anal. Appl. Pyrolysis 1988, 13, 171. 3) Mao, S.; Tsuge, S.; Ohtani, H ; Uchijima, S.; Kiyokawa, A. Polymer 1998, 39, 143.
655 767 866 875 895 968 989 1005 1033 1065 1098 1102 1265 1767
Relative Intensity 43.6 1.7 42.9 30.0 81.6 107.7 78.8 7.7 100.0 8.7 11.2 8.5 15.9 161.8 13.0
81
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
035
EGA thermogram
Averaged mass spectrum 91
105117
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
39 51 63
77 152
132 50
100
165 178 195
150
232 246 265 279 296 310 324 338
200
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
LB : hydrogenchloride
T : toluene
36
H
91
Cl
39
65
51
89
X : p-xylene
EB : ethylbenzene 91
91
106 106 39
51
65
77
51
39
65
77
ET : p-ethyltoluene
S : styrene
105
104
103
78
120 51 63
39
39
MS : p-methylstyrene
51
65
77
91
ES : p-ethylstyrene 117
117 118
132
91 39
51
63
89
39
CS : p-chloromethylstyrene
51
77
63
91
D : unidentified 181
117
210
152 39
51 63
165
Cl
91 39 51 63
77
105
118
141152
195
82
Tsuge, Ohtani and Watanabe
2.2.5 Acrylate-type polymers 036 Poly(methyl methacrylate); PMMA CH2C(CH3)(COOCH3)
n
M T D2 D1 D3 D4 d2 d4
5
10
15
20
TIC
0
10
Peak Notation M d2 d4 D1 D2 D3 D4 T
Assignment of Main Peaks methyl methacrylate C=C(C)-C-C(C)(COOC)-C ? C=C(C)-C=C(COOC)-C ? C=C(COOC)-C-C(C)(COOC)-C ? C-C(COOC)=C-C(COOC)-C ? C-C(COOC)=C-C(C)(COOC)-C C11H18O4 ? C-C(COOC)=C-C(C)(COOC)-C-C(C)(COOC)-C * bonding hydrogen is omitted
30 [min]
20
Molecular Retention Index Weight 100 156 140 200 186 200 214 300
? ? ? ? ? ?
710 1035 1090 1256 1274 1310 1332 1830
Relative Intensity 100.0 <0.1 <0.1 0.1 <0.1 0.1 <0.1 0.1
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Ohtani, H.; Ishiguro, S.; Tanaka, M.; Tsuge, S. Polym. J., 1989, 21, 41. 3) Ohtani, H.; Tanaka, M.; Tsuge, S. J. Anal. Appl. Pyrolysis, 1989, 15, 167. 4) Ohtani, H.; Tanaka, M.; Tsuge, S. Bull. Chem, Soc. Jpn. 1990, 63, 1196. 5) Ohtani, H.; Luo, Y. F.; Nakashima, Y.; Tsukahara, Y.; Tsuge, S. Anal. Chem. 1994, 66, 1438. 6) Ito, Y.; Tsuge, S.; Ohtani, H.; Wakabayashi, S.; Atarashi, J.; Kawamura, T. Macromolecules 1996, 29, 4516 7) Nonobe, T.; Tsuge, S.; Ohtani, H.; Kitayama, T.; Hatada, K. Macromolecules 1997, 30, 4891. 8) Ohtani, H.; Takehana, Y.; Tsuge, S. Macromolecules 1997, 30, 2542.
83
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
036
EGA thermogram
Averaged mass spectrum 41 69
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
100 59
30
85
50
150 [m/z]
100
( m/z range : 29 - 600 amu )
M : methyl methacrylate
d2 : methyl 2,2,4-trimethylpent-4-enoate
41
125
81 69
O
O
39
O
59
29
109
53
32 100
140
O
85
d4 : (Z)-methyl 2,4-dimethylpenta-2,4-dienoate
D1 : dimethyl 2,2-dimethyl-4-methylenepentanedioate
127
81
140 109
O
59
O
O
O
O
O 41
69
39
99
101
53 29
D2 : (Z )-dimethyl 2,4-dimethylpent-2-enedioate 67
67
125
D3 : (Z)-dimethyl 2,4,4-trimethylpent-2-enedioate 69
127
41
95 O
O
O
O
O
O
O
O
115 41
99
59
111
59
154
88
32
D4 : C11H18O4
T : (Z)-trimethyl 4,6-dimethylhept-2-ene-2,4,6-tricarboxylate 121
81
O
39
41
95 55
69
O
O
O
O
O
149
123 109 139
59
32 67
79
111 93
167 139
181
212 241
84
Tsuge, Ohtani and Watanabe
037 Poly(n-butyl methacrylate); PBMA CH2 C(CH3 )(COOC4H9)
n
M MMA
PB Be MA
BT 2
4
DP
6
8
10
12
B TIC
0
10
Peak Notation
Assignment of Main Peaks
B BT Be MMA MA M DP PB
1-butene n-butanal benzene methyl methacrylate methacrylic acid n-butyl methacrylate diphenyl phenyl benzoate
30 [min]
20
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Mao, S.; Ohtani, H.; Tsuge, S. J. Anal. Appl. Pyrolysis, 1995, 33, 181. 3) Bertini, F.; Audisio, G.; Zuev. V. V. Polym. Degrad. Stab. 2005, 89, 233.
Molecular Retention Weight Index 56 72 78 100 86 142 154 198
386 600 656 709 788 979 1390 1668
Relative Intensity 1.8 0.2 0.5 1.3 1.1 100.0 0.1 0.4
85
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
037
EGA thermogram
Averaged mass spectrum 41 69
87 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
56 100
31 50
113 150 [m/z]
100
( m/z range : 29 - 600 amu )
BT : n-butanal
B : 1-butene
29
41
41
O 72 56 57 29
Be : benzene
MMA : methyl methacrylate 78
39 O 69 O
50
100
43 63
33
59
85
30
M : n-butyl methacrylate
MA : methacrylic acid
69
39
87 O
41
OH 86
O
56 O 29 58
68 99
DP : diphenyl
113
127
143
PB : phenyl benzoate 105
154
O O
77
39 50
63
76
102
115 128
139
39
51
65
93
198
86
Tsuge, Ohtani and Watanabe
038 Poly(2-hydroxyethyl methacrylate); PHEMA CH2C(CH3)(COOCH2CH2OH)
M’
n
ED
M
TIC
8
LB A
9
10
11
12
MA
0
10
Peak Notation
Assignment of Main Peaks
LB A MA M M’ ED
CO2 acetaldehyde methacrylic acid 2-hydroxyethyl methacrylate CH2=CHCH(CH3)COOCH2CH2OH CH2=C(CH3)COOCH2CH2OCOC(CH3)=CH2
[ Related References ] 1) Razga, J. R.; Petranek, J. Eur. Polym. J. 1975, 11, 805. 2) Choudhary, M. S.; Lederer, K. Eur. Polym. J. 1982, 18, 1021. 3) Braun, D.; Steffan, R. Polym. Bull. 1983, 3, 111. 4) Cascaval, C. N.; Poinescu, Ig. Polym. Degrad. Stab. 1995, 48, 55.
30 [min]
20
Molecular Retention Weight Index 44 44 86 130 144 198
150 408 798 1029 1284 1315
Relative Intensity 2.2 1.6 5.3 100.0 2.9 2.6
87
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
038
EGA thermogram
Averaged mass spectrum 69
41
100
87
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31 59
100
50
100
150
[m/z]
( m/z range : 29 - 600 amu )
LB : carbon dioxide O
C
A : acetaldehyde 44
O
44
O
30
29
MA : methacrylic acid
58
M : 2-hydroxyethyl methacrylate 69
86
41
O 41
OH
OH
O 87
O 57
69 31
100
59
31
ED : ethane-1,2-diyl bis(2-methylacrylate)
M' : 2-hydroxyethyl-2-methylbut-3-enoate 69
O
69 O
41
O
OH
O 101
31 55
112
O
O 41
113
113
88 131
143
31
53
82
99
125 136
155
170
88
Tsuge, Ohtani and Watanabe
039 Poly(methyl acrylate); PMA CH2CH(COOCH3)
n
M3
M2 M5
M2’
M1
M4
M’ TIC
MO
M6
M
0
10
Peak Notation MO M1 M M’ M 2’ M2 M3 M4
M5 M6 M7
Assignment of Main Peaks
M7 30 [min]
20
Molecular Retention Weight Index
methanol methyl acrylate methyl methacrylate C=C-C(COOC)-C C(COOC)-C-C-COOC C=C(COOC)-C-C-COOC (dimer) C=C(COOC)-C-C(COOC)-C-C-COOC (trimer) C=C(COOC) C-C(COOC) C-C-COOC (meso (m)) 2 (tetramer) C=C(COOC) C-C(COOC) 2 C-C-COOC (racemic (r)) C=C(COOC) C-C(COOC) 3 C-C-COOC (mm) (pentamer C=C(COOC) C-C(COOC) 3 C-C-COOC (mr) ;diastereomer) C=C(COOC) C-C(COOC) 3 C-C-COOC (rr) C=C(COOC) C-C(COOC) 4 C-C-COOC (hexamer) C=C(COOC) C-C(COOC) 5 C-C-COOC (heptamer) *bonding hydrogen is omitted
32 86 100 114 160 172 258 344 344 430 430 430 516 602
310 607 711 804 1138 1198 1675 2101 2111 2521 2526 2530 2932 3328
[ Related References ] 1) Yamamoto, Y.; Tsuge, S.; Takeuchi, T. Macromolecules 1972, 5. 325. 2) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 3) Tsuge, S.; Hiramitsu, S.; Horibe, T.; Yamaoka, M.; Takeuchi. T. Macromolecules 1975, 8, 721. 4) Gunawan, L.; Haken, J. K. J. Polym. Sci., Polym. Chem. Ed. 1985, 23, 2539. 5) Haken, J. K.; Tan, L. J. Polym. Sci., Part A, 1988, 26, 1315. 6) Lehrle, R. S.; Place, E. J. Polym. Degrad. Stab. 1997, 56, 215. 7) Bertini, F.; Audisio, G ; Zuev. V. V. Polym. Degrad. Stab. 2005, 89, 233.
Relative Intensity 5.5 24.0 3.5 6.8 15.4 28.4 100.0 8.0 7.8 6.3 12.4 4.9 7.6 4.0
89
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
039
EGA thermogram
Averaged mass spectrum 59
79 41
100
31 67
300
400
500
153
100
600
700 ºC
programming rate: 20ºC/min
125
50
200
134
100112
194
167
227 215
186
150
200
275
306
250
334
300
399
366
350
[m/z]
400
( m/z range : 29 - 600 amu )
MO : methanol
M1 : methyl acrylate H
31
O
O
H
H
41
55
O
H
85
42
31
56
68
M' : methyl-2-methylbut-3-enoate
M : methyl methacrylate
55
41
O
O
O
69
83 O 100
59
29
O
M2 : dimethyl 2-methylenepentanedioate
59
O
114
71
M2' : dimethyl glutarate O
99
39
29
85
O
100
O
O
112 O
129
140 O
42
53 87
29
39
74
O
O
O
O
(meso form) (tetramer) O
194
134
79
59 106
167
59
67
29
153
179
O
O
O
O
O
O
O
O
O
O
220 252
313
280
67
M6 : hexamethyl dodec-11-ene-1,3,5,7,9,11-hexacarboxylate
O
O
O
O
O
O
O
O
O
O
O
O
O
59
59 172
275 306 334
100 79 41 67 29
O
(hexamer)
(pentamer; diastereoisomer ) O
O
79
29
211
M5 : pentamethyl dec-9-ene-1,3,5,7,9-pentacarboxylate O
192
O
100 41
97
O
161 133
227
125
41
125
M4 : tetramethyl oct-7-ene-1,3,5,7-tetracarboxylate
M3 : trimethyl hex-5-ene-1,3,5-tricarboxylate O
97
71
31
113
O
81
112 139
399
79
247
187
172
100 112
215 366
41 67
227
361
138
128
185 213
273
301
333
420
485
392 452
380
31
90
Tsuge, Ohtani and Watanabe
040 Poly(ethyl acrylate); PEA CH2CH(COOC2H5)
n
M3
M2 M1
M2
EO LB
M5 TIC
M4
M’
0
10
Peak Notation LB EO M1 M M2’ M2 M3 M4
M5
30 [min]
20
Assignment of Main Peaks CO2 ethanol ethyl acrylate ethyl methacrylate C(COOC2)-C-C-COOC2 C=C(COOC2)-C-C-COOC2 (dimer) C=C(COOC2)-C-C(COOC2)-C-C-COOC2 (trimer) C=C(COOC2) C-C(COOC2) 2C-C-COOC2 (meso form) C=C(COOC2) C-C(COOC2) 2C-C-COOC2 (racemic form) (tetramer) C=C(COOC2) C-C(COOC2) 3C-C-COOC2 (pentamer) *bonding hydrogen is omitted
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Haken, J. K.;Tan, L. J. Polym. Sci, Part-A, 1988, 26, 1315. 3) Mao, S.; Ohtani, H.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1995, 33, 181. 4) McNeil, I. C.; Mohammed, M. H. Polym. Degrad. Stab. 1995, 48, 175. 5) Bertini, F.; Audisio, G.; Zuev. V. V. Polym. Degrad. Stab. 2005, 89, 233.
Molecular Retention Weight Index
Relative Intensity
44 46 100 114 188 200 300 400 400
150 462 695 786 1280 1333 1846 2301 2309
19.5 28.6 30.7 28.6 26.1 21.8 100.0 2.2 1.8
500
2738
10.6
91
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
040
EGA thermogram
Averaged mass spectrum 31
100
45
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55 69
79
98
50
134 125
114
100
154 166 150
181
200
208
226
255
243
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
EO : ethanol
LB : carbon dioxide O
C
44
O
31
OH 45
29
M' : ethyl methacrylate
M1 : ethyl acrylate 55
69
O
O
O
41
O
29
29
45
73
M2 : diethyl 2-methylenepentanedioate (dimer) 98
143 O
O
114
58
M2' : diethyl glutarate
O
115
O 42
43
101
O
127
29
55 73
O
O O 154
87 29
99
86
99
82
53 69
129
81
109
143
172
200
M4 : tetraethyl oct-7-ene-1,3,5,7-tetracarboxylate M3 : triethyl hex-5-ene-1,3,5-tricarboxylate (trimer) 208
134 O
O
O
O
O
(meso form) (tetramer) 29
255
O
O
O
O
O
O
O
O
200
29
79
181
106 152
55 41
67
97
226
125
206 234 262280 308
M5 : pentaethyl dec-9-ene-1,3,5,7,9-pentacarboxylate (pentamer)
(racemic form) (tetramer)
455
29
29 O
O
O
O
O
O
55
105 91 79
206 179
O
O
O
O
355
161 133
O
355
179
79
41
M4 : tetraethyl oct-7-ene-1,3,5,7-tetracarboxylate
41
105 133
55
200
161
235
55 280 308 262
O
O
O
O
200 114 79
98
187 155 215 131 167
O
O
O
O
289 334
261 306
362 380 408
92
Tsuge, Ohtani and Watanabe
041 Poly(butyl acrylate); PBA CH2CH(COOC4H9)
n
M3
M2
M1
B
M2
BO TIC
BT
A
M4
0
10
Peak Notation B BT BO A M1 M2’ M2 M3 M4
30 [min]
20
Assignment of Main Peaks 1-butene n-butanal 1-butanol acrylic acid n-butyl acrylate C(COOC4)-C-C-COOC4 C=C(COOC4)-C-C-COOC4 (dimer) C=C(COOC4)-C-C(COOC4)-C-C-COOC4 (trimer) C=C(COOC4) C-C(COOC4) 2C-C-COOC4 (meso form) C=C(COOC4) C-C(COOC4) 2C-C-COOC4 (racemic form) (tetramer) *bonding hydrogen is omitted
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Haken, J. K.;Tan, L. J. Polym. Sci, Part A, 1987, 25, 1451. 3) Haken, J. K.;Tan, L. J. Polym. Sci, Part A, 1988, 26, 1315. 4) Bertini, F.; Audisio, G.; Zuev. V. V. Polym. Degrad. Stab. 2005, 89, 233.
Molecular Retention Weight Index 56 72 74 72 128 244 256 384 512 512
392 605 657 697 892 1648 1696 2352 2929 2938
Relative Intensity 64.6 5.3 43.8 1.3 47.3 44.7 46.0 100.0 1.5 1.1
93
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
041
EGA thermogram
Averaged mass spectrum 41
100
56
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31
98
115 127 134
73 79 50
100
181 236 171 199 208 226
153 150
255
200
311
282
250
300
350
[m/z]
( m/z range : 29 - 600 amu )
BT : n -butanal
B : 1-butene
29
41
41
O 72
56 57 29
BO : 1-butanol
A : acrylic acid 31
56
41
OH
72
55
OH O 45
74 78
M1 : n-butyl acrylate
M2' : dibutyl glutarate
55
115
O O
O
O
O
57
70
O
73 41
29
99
113
M2 : dibutyl 2-methylenepentanedioate (dimer)
171
87
41
29
85
142 98
181 O
O
O
O
29
154
109
201
79
67
256
124 98109
311 170
208 226 199
255 282 267
M4 : tetrabutyl oct-7-ene-1,3,5,7-tetracarboxylate
M4 : tetrabutyl oct-7-ene-1,3,5,7-tetracarboxylate
(rasemic form)(tetramer)
(meso form)(tetramer)
41
41 O
29
153
57
183
81
O O
236
41 71
O O
O O
134
41
98
57
189
M3 : tributyl hex-5-ene-1,3,5-tricarboxylate (trimer)
127
29
129
O
O
O
O
O
O
O
29
57
O
O
O
57 161 73 98
127 151
179
207 253 223 262 290308 336
439
98115 78
O
O
O
O
O
207
133 160
181
234253
439 290
327
364
403
94
Tsuge, Ohtani and Watanabe
042 Poly(acrylic acid; isotactic); PAA CH 2CH(COOH)
n
h e
LB d b
c
j
f g i
X
a
T MA
5
3
A TIC
7
11
9
13
17
15
B
0
10
Peak Notation LB B A T MA X a b c d e f g h i j
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
CO2 1-butene acrylic acid toluene methacrylic acid xylene 3-methyl-2-cyclohexenone o-cresol 2,6-xylenol
unidentified (these pyrolyzates are expected to be cyclic ketones, esters, and acid anhydrides)
[ Related References ] 1) McGaugh, M. C.; Kottle, S. Polym. Lett. 1967, 5, 817. 2) Fyfe, C. A.; Mckinnon, M. S. Macromolecules 1986, 19, 1909. 3) Maurer, J. J.; Eustace, D. J.; Ratchliffe, C. T. Macromolecules 1987, 20, 196. 4) Lattimer, R. T. J. Anal. Appl. Pyrolysis 2003, 68-69, 3.
44 56 72 92 86 106 110 108 122 162 160 174 178 210 246 260
150 382 709 768 790 874 999 1057 1113 1478 1543 1610 1769 1880 2323 2340
Relative Intensity 100.0 10.3 0.8 3.2 1.0 5.5 4.4 6.4 6.2 10.9 13.4 11.5 6.7 12.9 4.6 10.4
95
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
042
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
77
91 115 131
65
50
165 178 195 202 216
146
100
150
239 246 260 272 286
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
LB : carbon dioxide O
C
B : 1-butene 44
O
41
56
29
A : acrylic acid
64
X : xylene 72
OH
91
55
O
106 45 29 81
b : o-cresol
51
39
29
65
77
c : 2,6-xylenol
OH
OH
108
122 107
79
77
90 29
39
51
63
119
134
29
39
51
91
65
e : unidentified
d : unidentified 162
160
134
91
132
120 39
51
65 77
51
105
152
63
39
178
77
103 150
j : unidentified
f : unidentified 145
260
174
146 163
39
51 63
77
91
115
41
131
55 29
69
91
134 105 121
189
204
232
96
Tsuge, Ohtani and Watanabe
043 Methyl methacrylate-methyl acrylate copolymer; P(MMA-MA) CH2C(CH3)(COOCH3)
CH2CH(COOCH3)
n
A2’ M
D1 A2 d4 d1 d2
D3
HT D4
T
d5
5
TIC
HT ’
10
15
A
0
10
Peak Notation A M d1 d2 d4 d5 A2 A2’ D1 D3 D4
HT
HT’ T
Assignment of Main Peaks methyl acrylate methyl methacrylate C=C(C)-C-C(COOC)-C ? C=C(C)-C-C(C)(COOC)-C ? C=C(C)-C=C(COOC)-C ? C-C(C)-C-C(C)(COOC)-C ? C-C(COOC)-C-C-COOC (MA dimer) C=C(COOC)-C-C-COOC C=C(COOC)-C-C(COOC)-C ? C=C(COOC)-C-C(C)(COOC)-C ? C-C(COOC)=C-C(C)(COOC)-C ? C11H18O4 ? either one of the following: C-C(COOC)=C-C(COOC)-C-C(COOC)-C C=C(COOC)-C-C(COOC)-C-C(COOC)-C C-C(COOC)=C-C(C)(COOC)-C-C-COOC C=C(COOC)-C-C(C)(COOC)-C-C-COOC C=C(COOC)-C-C(C)(COOC)-C-C(C)(COOC)-C C-C(COOC)=C-C(C)(COOC)-C-C(C)(COOC)-C *bonding hydrogen is omitted
30 [min]
20
Molecular Retention Weight Index 86 100 142 156 140 158 174 172 186 200 200 214 272 272 272 272 300 300
? ? ? ?
? ? ? ?
Relative Intensity
613 710 937 984 1035 1088 1166 1187 1209 1256 1309 1327
4.5 100.0 0.1 0.1 0.2 0.1 0.1 0.2 0.5 0.4 0.2 0.2
1648 1655 1671 1728 1735 1829
0.2 0.1 0.2 0.2 0.1 0.2
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Kiura, M ; Atarashi, J.; Ichimura, K.; Ito, H.; Ohtani, H.; Tsuge, S. J. Appl. Polym. Sci. 2000, 78, 2140.
97
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
043
EGA thermogram
Averaged mass spectrum 41
100
69
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
100
55
85
31
113
50
126
153
100
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
A : methyl acrylate
M : methyl methacrylate 41
55
O
O
69
O O
100 85
42
29
59
29
68
A2' : dimethyl 2-methyl-4-methylenepenatanedioate
85
D1 : dimethyl 2,2-dimethyl-4-methylenepentanedioate 81
126
140 109 O
O
O 67
O
O
41
O
O
O
111 59
95
39
59
29
83
HT : trimethyl hept-1-ene-2,4,6-tricarboxylate
93
79 O
152 120
59 79
29
O
O
O
O
O
32 41
125
95
O
O
O
O
113 121
141 O
O
O
241 111
181
137
29
O
-2,4,6-tricarboxylate 121
107 O
59 69
O
O
O
O
O
O
O
O
127 79
O
T : (Z)-trimethyl 4,6-dimethylhept-2-ene
-2,4,6-tricarboxylate
40
O
213
212
HT' : trimethyl 4,6-dimethylhept-1-ene
O
186 153
55 67
39
120 81
67
O
166
79 41
O
227
93
93
29
O
198
HT : trimethyl 3-methylhex-5-ene-1,3,5-tricarboxylate
-1,3,5-tricarboxylate
59
O
241
HT : (Z)-trimethyl 3-methylhex-4-ene
O
O
134
68
180
152
O
106
59
172
113
69
125 169
HT : (Z)-trimethyl hept-2-ene-2,4,6-tricarboxylate
41
101 67
155
95
O
O
149
O
59 139
155
186 194
139
41 32
79 65
97 111
167 176
241
98
Tsuge, Ohtani and Watanabe
044 Higher methacrylate copolymer CH2C(CH3)(COOR)
n
R=C1, C12 – C16, C18 (including branched isomers) M13 M12 M14 M13’ C13 TIC
M1
MA
C12
0
M15
M12’ C14
M14’ M16
M15’ M18
10
Peak Notation
Assignment of Main Peaks
M1 MA C12 C13 C14 M12’ M12 M13’ M13 M14’ M14 M15’ M15 M16 M18
methyl methacrylate methacrylic acid 1-dodecene 1-tridecene 1-tetradecene 2-methylundecyl methacrylate dodecyl methacrylate 2-methyldodecyl methacrylate tridecyl methacrylate 2-methyltridecyl methacrylate tetradecyl methacrylate 2-methyltetradecyl methacrylate pentadecyl methacrylate hexadecyl methacrylate octadecyl methacrylate [ Related References ] 1) Ohtani, H.; Asai, T.; Tsuge, S. Macromolecules 1985, 18, 1148.
30 [min]
20
Molecular Retention Index Weight 100 86 168 182 196 254 254 268 268 282 282 296 296 310 338
711 801 1193 1292 1393 1714 1776 1814 1876 1914 1976 2014 2075 2175 2377
Relative Intensity 7.9 1.6 7.8 11.5 6.8 7.3 70.3 10.9 100.0 6.3 55.1 3.2 25.2 6.1 1.9
99
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
044
EGA thermogram
Averaged mass spectrum 41
69 87
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55 97
111
31 50
125
140
100
153
168
182
196
150
211 250 [m/z]
200
( m/z range : 29 - 600 amu )
MA : methacrylic acid
M1 : methyl methacrylate 41
39 O 69
29
OH 86
O
O
100
59
85
58
29
C13 : 1-tridecene
68
M12' : 2-methylundecyl methacrylate 69
41 41
55
O 56
69
29
O
83 97 111
29 125 139
154
M12 : dodecyl methacrylate 41
83
O
41
O
O
56
55 97
29
111 125140 152 168 181195 211
83
29
111
126
139
154 167 182 195
M14 : tetradecyl methacrylate
69
41
69
O
87
97
255
M13 : tridecyl methacrylate
O
87
O
O
55
55 97
29
97
29 111
125 182 139 154 169 195
111 125 139
269
M15 : pentadecyl methacrylate
196
239
69
41
O
O
87 O
55
168
M18 : octadecyl methacrylate
69 87
O
55 97
97 29
140 153 168
69 O 87
41
111 125
M13' : 2-methyldodecyl methacrylate
69
41
97
182
111
29 125 139153
182
210
237 253
297
111
125
139
207
283
100
Tsuge, Ohtani and Watanabe
045 Acrylic rubber; ACM CH2CH(COOC2H5)
CH2CH(COOC2H4OCH3)
CH2CH(COOC4H9)
B
EB’
EBM EBB
BM’ EM’ BA
VM LB
BO
BB’
EEB
EE’ EE
BMA
ME
n
BBB BBM
EEM
BMM
EEE EMM
M
MMM
E 8
6
12
10
14
16
TIC
0
10
Peak Notation LB B VM ME BO E BA M BMA EE’ EE EB’ EM’ BB’ BM’ EEE EEB
EEM
EBB
EBM
EMM BBB BBM BMM MMM
Assignment of Main Peaks CO2 1-butene vinyl methyl ether 2-methoxy ethanol 1-butanol ethyl acrylate n-butyl acrylate 2-methoxy ethylacrylate n-butyl methacrylate C(COOC2)-C-C-COOC2 C=C(COOC2)-C-C-COOC2 (E dimer) C(COOC2)-C-C-COOC4 C(COOC2)-C-C-COOC2OC C(COOC4)-C-C-COOC4 C(COOC4)-C-C-COOC2OC C=C(COOC2)-C-C(COOC2)-C-C-COOC2 (E trimer) Either one of the C=C(COOC2)-C-C(COOC2)-C-C-COOC4 following C=C(COOC2)-C-C(COOC4)-C-C-COOC2 C=C(COOC4)-C-C(COOC2)-C-C-COOC2 C=C(COOC2)-C-C(COOC2)-C-C-COOC2OC Either one of the following C=C(COOC2)-C-C(COOC2OC)-C-C-COOC2 C=C(COOC2OC)-C-C(COOC2)-C-C-COOC2 C=C(COOC2)-C-C(COOC4)-C-C-COOC4 Either one of the following C=C(COOC4)-C-C(COOC4)-C-C-COOC2 C=C(COOC4)-C-C(COOC2)-C-C-COOC4 C=C(COOC2)-C-C(COOC4)-C-C-COOC2OC Either one of the following C=C(COOC2OC)-C-C(COOC2)-C-C-COOC4 C=C(COOC2OC)-C-C(COOC4)-C-C-COOC2 C=C(COOC2)-C-C(COOC2OC)-C-C-COOC2OC Either one of the following C=C(COOC2OC)-C-C(COOC2)-C-C-COOC2OC C=C(COOC2OC)-C-C(COOC2OC)-C-C-COOC2 , etc. C=C(COOC4)-C-C(COOC4)-C-C-COOC4 (B trimer) C=C(COOC4)-C-C(COOC4)-C-C-COOC2OC + 2 isomers C=C(COOC4)-C-C(COOC2OC)-C-C-COOC2OC + 2 isomers C=C(COOC2OC)-C-C(COOC2OC)-C-C-COOC2OC (M trimer) *bonding hydrogen is omitted
[ Related References ] 1) Haken, J. K.; Mckay, T. R. Anal. Chem. 1973, 45, 1251. 2) Yamaguchi, S.; Hirano, J.; Isoda, Y. Polym. J. 1985, 17, 1105.
30 [min]
20
Molecular Retention Weight Index 44 150 56 388 58 390 76 627 74 657 100 696 128 892 130 913 142 976 188 1269 200 1322 216 1459 218 1475 244 1648 246 1664 300 1828 328 1996 328 2004 328 2008 330 2018 330 2021 330 2029 356 2170 356 2177 356 2187 358 2319 358 2199 358 2204 360 2211 360 2219 360 2223 384 2352 386 2370 388 2391 390 2412
Relative Intensity 30.9 100.0 13.4 42.5 34.6 32.9 54.3 39.1 6.1 10.8 7.1 25.8 16.3 15.4 21.1 11.2 9.1 9.4 8.5 8.6 5.0 5.9 11.0 8.9 18.0 6.6 9.2 8.9 3.1 4.9 6.0 9.4 21.1 15.2 3.7
101
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
045
EGA thermogram
Averaged mass spectrum 41 56 31
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
98
79 73 50
115
134 127
152
100
181 164
150
208 199
227236
255
200
283
313
250
300
350
[m/z]
( m/z range : 29 - 600 amu )
B : 1-butene
VM : vinyl methyl ether 43
41
O 29
58
56 29
ME : 2-methoxyethanol
BO : 1-butanol
45
O
56
41
31
OH
OH 29
76
58
69
78
BA : n-butyl acrylate
E : ethyl acrylate O
55
O
55
O
O 73
29 45
72
41
29
99
82
85
M : 2-methoxyethyl acrylate
99
113
EB' : butyl ethyl glutarate O
55
115
O
143 O
O
45
O
O
O 87
42
29
29 71
55
87
99
70
98
171
129
BBM : 3,5-dibutyl 1-(2-methoxyethyl) hex-5-eneBM' : butyl 2-methoxyethyl glutarate
1,3,5-tricarboxylate
115
O
59 29
181
O
O
O
87
42
O
41 59 29
134 79
173 70
98
118
142
69 159
106125 153 97 162
O
O
O
O
O
O
236 199 225
313 258 284 329 355
O
102
Tsuge, Ohtani and Watanabe
046 Polyacrylonitrile; PAN CH2CH(CN)
n
AA2 AAA2 AA3 AAA1
AAA3 AAA4
LB TIC
AAA5 T1
AA1 A
MA
T2
T3
AA’ 0
10
Peak Notation LB A MA AA’ AA1 AA2 AA3 AAA1 AAA2 AAA3 AAA4 AAA5 T1 T2 T3
Molecular Retention Weight Index
Assignment of Main Peaks low boiling point components acrylonitrile (monomer) methacrylonitrile C(CN)=C-C-CN C-C(CN)-C=C-CN + C=C(CN)-C-C(CN)-C C=C(CN)-C-C-CN + C(CN)-C-C-CN + C=C(CN)-C-C(CN)=C C-C(CN)-C-C-CN C=C(CN)-C-C(CN)-C-C-CN C-C(CN)-C-C(CN)-C-C-CN (trimer) C(CN)-C-C(CN)-C-C-CN C-C(CN)-C-C(CN)-C=C-CN C9H9N3 (isomer of trimer) C=C(CN)-C-C(CN)-C-C(CN)-C-C-CN C=C(CN)-C-C(CN)-C-C(CN)-C-C(CN)=C C(CN)-C-C(CN)-C-C(CN)-C-C-CN? *bonding hydrogen is omitted
30 [min]
20
(dimer)
(tetramer)
53 67 92 106; 120 106 94; 118 108 159 161 147 159 159 212 224 200
470 567 602 834 1045
Relative Intensity 1.4 6.2 1.1 0.9 1.2
1059
64.9
1071 1513 1540 1564 1655 1743 2022 2155 2294
24.4 23.9 100.0 35.9 39.9 13.5 23.9 12.0 9.9
[ Related References ] 1) Yamamoto, Y.; Tsuge, S.; Takeuchi, T. Macromolecules 1972, 5, 325. 2) Tsuchiya, Y.; Sumi, K. J. Appl. Polym. Sci. 1977, 21, 975. 3) Nagaya, T.; Sugimura, Y.; Tsuge, S. Macromolecules 1980, 13, 353. 4) Usami, T.; Itoh, T.; Ohtani, H.; Tsuge, S. Macromolecules 1990, 23, 2460. 5) Minagawa, M.; Onuma, H.; Ogita, T.; Uchida, H. J. Appl. Polym. Sci. 2001, 79, 473. 6) Sanchez-Soto, P. J.; Aviles, M. A.; del Rio, J. C.; Gines, J. M.; Pascual, J.; Perez-Rodriguez, J. L. J. Anal. Appl. Sci. 2001, 58-59, 155.
103
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
046
EGA thermogram
Averaged mass spectrum 54 66 39 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
106 119 79
94 133
50
147
100
160
174 200 [m/z]
150
( m/z range : 29 - 600 amu )
AA2 : 2-methylenepentanedinitrile (+ glutaronitrile + 2,4-dimethylenepentanedinitrile) (dimer)
A : acrylonitrile 53
66 N
N
N
N
+ 41
N
N
N
+
54 106
38 79
29
AAA1 : hex-5-ene-1,3,5-tricarbonitrile (trimer)
AA3 : 2-methylpentanedinitrile N
91
N
39
N
171
118
N
143 156
205
AAA3 : pentane-1,3,5-tricarbonitrile (trimer) N
106 66
N
105 78 91
78
N
66 52
64
AAA2 : hexane-1,3,5-tricarbonitrile (trimer) N
N
119
39 52
91
N
N
107
54
119 41
39
80
52
66
92 78
29
AAA4 : (Z)-hex-1-ene-1,3,5-tricarbonitrile (trimer) N
106
N
93
29
132
N
119
146
T1 : oct-7-ene-1,3,5,7-tetracarbonitrile (tetramer) N
N
N
119
N
54
106
66
39
66
79 92
29
39
119 132
32
158
T2 : nona-1,8-diene-2,4,6,8-tetracarbonitrile (tetramer) N
N
N
N
78
172 107
107 66
159
172
N
N
145
145 131
79
145
54
39
32
92
T3 : heptane-1,3,5,7-tetracarbonitrile (tetramer)
171
54
54
39
158
158
66 79
92
119 91
183
29
208
N
N
104
Tsuge, Ohtani and Watanabe
047 Acrylonitrile-methyl acrylate copolymer CH2CH(CN)
M2A
CH2CH(COOCH3)
n
M3
MAA
A2M
A MO LB
MMA
M
A
AM
MA AA
TIC
MM
AM
MM
M
0
pentamers
MA
trtramers
10
Peak Notation LB MO A MA M A’ MMA M’ AA AM’ AM MM’ MA’ MM
A2M MAA
M2A M3
30 [min]
20
Assignment of Main Peaks CO2 methanol acrylonitrile methacrylonitrile methyl acrylate C-C-C=C-CN methyl methacrylate C=C-C(COOC)-C C(CN)-C-C-CN + C=C(CN)-C-C-CN (A dimer) C(CN)-C-C-COOC + C=C(CN)-C-C(CN)=C C=C(CN)-C-C(COOC) (hybrid dimer) C(COOC)-C-C-COOC + C-C(CN)-C=C(COOC) C=C(COOC)-C-C(CN)=C C=C-C(COOC)-C-C-COOC (M dimer) Either one of the following: C=C(CN)-C-C(CN)-C-C-COOC C=C(CN)-C-C(COOC)-C-C-CN C=C(COOC)-C-C(CN)-C-C-CN (hybrid trimer) Either one of the following: C=C(COOC)-C-C(COOC)-C-C-CN C=C(COOC)-C-C(CN)-C-C-COOC C=C(CN)-C-C(COOC)-C-C-COOC C=C(COOC)-C-C(COOC)-C-C-COOC *bonding hydrogen is omitted
[ Related References ] 1) Yamamoto, Y.; Tsuge, S.; Takeuchi, T. Macromolecules 1972, 5, 325. 2) Saglam, M. J. Appl. Polym. Sci. 1986, 32, 5719.
Molecular Retention Weight Index
Relative Intensity
44 32 53 67 86 81 100 114 94; 106 127; 118 139 160; 139 151 186
150 320 567 602 608 699 714 803 1063 1076 1088 1134 1150 1194
27.6 38.6 33.8 5.4 47.1 6.6 6.5 5.9 14.6 23.2 9.2 34.4 5.2 16.5
192 192 192
1522 1545 1563
2.0 41.1 51.4
225 225 225 258
1582 1619 1628 1667
100.0 69.6 34.8 83.4
105
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
047
EGA thermogram
Averaged mass spectrum 39
55 106
79 31
100
66
200
300
400
500
94
50
600
700 ºC
programming rate: 20ºC/min
134 120
161 152
100
194 187 203
150
227 235246 261274
200
305
250
333
366
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
A : acrylonitrile
MO : methanol H
31
53
H
H
H
41
N
O
38
29
56
74
MM' : dimethyl glutarate
M : methyl acrylate
( + (Z)-methyl 4-cyanopent-2-enoate) 55
O
O
59
N O
O
O
100
O
108
29
68
A2M : methyl 4,6-dicyanohept-6-enoate (hybrid trimer) 106
N
66
O
129
69
138
MAA : methyl 4,6-dicyano-2-methylenehexanoate (hybrid trimer) O
N
O
80
42
85
42
29
O
+
N
O
N
106
92
133
O
119 55
55
79
O
177
192
M2A : dimethyl 4-cyano-2-methyleneheptanedioate (hybrid trimer)
4-methylenepentanedioate (hybrid trimer) O
152
29
192
M2A : dimethyl 2-(2-cyanoethyl)O
161 131
177
149
N
66
161
134
92
29
O
79
39
39
106
O
N
O
O
161
O 133 106
79
194
99
59 41
152
65
O
O
79
59 39 29
O
69
O
134
O
106 99
120
185
O
O
O
79
194 152 161
67
153
M3 : trimethyl hex-5-ene-1,3,5-tricarboxylate
(hybrid trimer) N
125
93
29
177
M2A : dimethyl 2-(2-cyanoallyl)pentanedioate
194
79
120
39 29
165
134
59
O
O
194
134
106
167
59 210
41
178 224
29
227
125 67
97
153
230
106
Tsuge, Ohtani and Watanabe
048 Polyacrylamide; PAAm CH2CH(CONH2)
n
D3
D2 D5 T1
AN
D1 AN2
LB
TIC
T3
AN3
D4
MA
T4
a T2
P
0
10
Peak Notation LB AN P MA
AN2
D1 a D2 D3
D5 AN3
T2 T3
T4
CO2 etc. acrylonitrile propanenitrile methacrylonitrile C-C(CN)-C=C-CN C(CN)-C-C-CN C=C(CN)-C-C-CN C-C(CN)-C-C-CN
Molecular Retention Weight Index
Relative Intensity
44 53 55 67 106 94 106 108
150 560 567 602 1045 1053 1057 1073
27.9 17.3 3.3 18.1 7.8 18.6 30.7 4.9
113
1176
53.4
C7H9NO ?
123
1202
C-C-C-C | | O=C-N-C=O
6.5
127
1216
38.2
125
1228
100.0
141
1252
18.3
139
1261
60.6
159 147
1528 1551
41.9 5.0
178
1679
36.0
192
1692
8.1
166
1697
69.5
180
1713
35.9
C-C-C | | O=C-N-C=O
C-C-C=C | | O=C-N-C=O C-C-C-C-C | | O=C-N-C=O
D4
T1
Assignment of Main Peaks(*bonding hydrogen is omitted)
30 [min]
20
C-C-C-C=C | | O=C-N-C=O
C=C(CN)-C-C(CN)-C-C-CN C(CN)-C-C(CN)-C-C-CN C=C(CN)-C-C-C-C | | O=C-N-C=O C=C(CN)-C-C-C-C-C-C | | O=C-N-C=O C(CN)-C-C-C-C | | O=C-N-C=O C-C(CN)-C-C-C-C | | O=C-N-C=O
*bonding hydrogen is omitted [ Related References ] 1) Leung, W. M.; Axelson, D. E. J. Polym. Sci., Polym. Chem. Ed. 1987, 25, 1825. 2) Tutas, M.; Saglam, M.; Yuksel, M. J. Anal. Appl. Pyrolysis 1991, 22, 129. 3) Wang, F. C.-Y. J. Chromatogr. A 1996, 753, 101. 4) Ishida, Y.; Tsuge, S.; Ohtani, H.; Inokuchi, F.; Fujii, Y.; Suetomo, S. Anal. Sci. 1996, 12, 831.
107
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
048
EGA thermogram
Averaged mass spectrum 42
56 100
67
200
300
400
500
96
700 ºC
125
82
139
154 164 176
30 50
600
programming rate: 20ºC/min
113
100
192
150
210
225 235
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
AN : acrylonitrile
MA : methacrylonitrile 53
N
41
N
67 52 38
AN2 : 4-methylpent-2-enedinitrile
D1 : piperidine-2,6-dione
79
N
N
42
O
52
N
O
113
66
106
39
70
92
120
55
30
84
D3 : 3-methylenepiperidine-2,6-dione
D2 : 3-methylpiperidine-2,6-dione 56
125 54
99
42
O
N
O
O
N
O 39
127 29
70
84
82
112
70
29
T1 : 2-(2,6-dioxopiperidin-3-yl)but-3-enenitrile
D5 : 3-methyl-5-methylenepiperidine-2,6-dione 67
N
106
O
39
N
111
123
39
O
96
66 133
178
O
150 161
T4 : 3-(2,6-Dioxopiperidin-3-yl)2-methylpropanenitril
T3 : 3-(2,6-dioxopiperidin-3-yl)propanenitrile 113
N
O
92
29
124
81
79
55
139
53
29
96
N
127 55 39 O
55
N
67 95
29 123 137 149
166
192
N
O
N
99
67 29
O
O
85
42
112 78
145
161
190
108
Tsuge, Ohtani and Watanabe
049 Poly(maleic anhydride); PMAH CH(CO)CH(CO)
n
O M
LB D B
X1 EB S X2
TIC
0
SM
10
Peak Notation LB B A M EB X1 S X2 SM D
Assignment of Main Peaks CO2 butene acrylic acid maleic anhydride ethylbenzene xylene (m- or p-) styrene o-xylene styrene-maleic anhydride (hybrid dimer) unidentified unidentified unidentified
30 [min]
20
Molecular Retention Weight Index 44 56 72 98 106 106 104 106 202 204 204 204
150 389 702 849 862 869 890 892 1614 1693 1707 1732
Relative Intensity 51.5 3.4 8.7 100.0 10.5 22.1 5.3 4.6 8.2 18.3 19.2 33.9
109
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
049
EGA thermogram
Averaged mass spectrum 44 54
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
91 65
31
105
77
128
50
145
100
150
165 178 189
204 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
LB : carbon dioxide O
C
B : 1-butene 44
O
39
56 29 29
A : acrylic acid
M : maleic anhydride
OH
54
72 55
O
O
O
45
29
98
44
29
81
69
X1 : xylene
EB : ethylbenzene 91
91
106 106 39
51
65
77
39
51
32
63
77
X2 : o-xylene
S : styrene 104
78
39
51
91
103
106 39
74
SM : styrene-maleic anhydride (hybrid dimer)
51
65
77
D : unidentified
115
105 129
174 39
O
51 63 77
162 202
103
39 145157
29
51
65
77
91
204 132 186
110
Tsuge, Ohtani and Watanabe
2.2.6 Chlorine-containing vinyl polymers 050 Poly(vinyl chloride); PVC CH2CHCl
n
N HCL
S E X1
B TIC
5
MI
I
MN
X2
6
AC
7
8
9
AN
F
10
11
12
13
T
0
10
Peak Notation HCL B T E X1 S X2 I MI N MN AC F AN
Assignment of Main Peaks hydrogen chloride benzene toluene ethylbenzene xylene (m- or p-) styrene o-xylene indene 1-methylindene 3-methylindene naphthalene 2-methylnaphthalene 1-methylnaphthalene acenaphthene fluorene anthracene
30 [min]
20
Molecular Retention Weight Index 36 78 92 106 106 104 106 116 130 130 128 142 142 154 166 178
651 766 867 875 896 898 1057 1167 1183 1204 1320 1338 1403 1622 1832
[ Related References ] 1) Tsuge, S.; Okumoto, T.; Takeuchi, T. Makromol. Chem. 1969, 123, 123. 2) Chang, E. P.; Salovery, R. J. Polym. Sci., Polym. Chem. Ed. 1974, 12, 2927. 3) Lattimer, R. P.; Kroenke, W. J. J. Appl. Polym. Sci. 1980, 25, 101 4) Lattimer, R. P.; Kroenke, W. J. J. Appl. Polym. Sci. 1982, 27, 1355. 5) Matsusaka, K.; Tanaka, A.; Murakami, I. Polymer 1984, 25, 1337. 6) Dadvand, N.; Lehrle, R. S.; Parsons, I. W.; Rollinson, M. Polym. Degrad. Stab. 1999, 66, 247. 7) Tienpont, B.; David, F.; Vanwalleghem, F. ; Sandra, P. J. Chromatogr. A 2001, 911, 235. 8) Starnes Jr., W. H. Prog. Polym. Sci. 2002, 27, 2133.
Relative Intensity 100.0 16.0 4.3 0.5 0.8 1.3 1.0 1.8 1.8 1.3 3.5 1.7 1.2 0.9 0.8 0.8
111
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
050
EGA thermogram
Averaged mass spectrum
36 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
78 51 31
91 115 128 141 152 165 178 191 202
63
50
100
150
229 239
258
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
HCL : hydrogen chloride
B : benzene 36
78
Cl
H
52
39
T : toluene
74
S : styrene 91
104
103 78
51 39
65
51
39
89
63
MI : 1-methylindene
l : indene
130
116 115
57 63
39
119
90
64
51 39
132
N : naphthalene
132 77
91
MN : 1-methylnaphthalene 142
128
115 39
51
64
77
102
116
132
57
36
146
71
91
129
158
AN : anthracene
AC : acenaphthene 154
76 36
51 63
102 115 128
178
36
143
- 127 -
50
75
89 91
115 128 141
152
165
194
112
Tsuge, Ohtani and Watanabe
051 Vinyl chloride-vinylidene chloride copolymer; P(VC-VdC) CH2CHCl
CH2CCl2
n
LB
P3 TIC
CN
V
BO
O
CB DC TC
0
CS
TN
10
Peak Notation LB V BO O CB DC TC CS TN CN P3
Assignment of Main Peaks hydrogen chloride vinylidene chloride 1-butanol C8H16 ? C8H16 ? C8H16 ? chlorobenzene m-dichlorobenzene 1,3,5-trichlorobenzene trichlorostyrene(2,4,6- ?) trichloronaphthalene tetrachloronaphthalene plasticizer of fatty acid ester
30 [min]
20
Molecular Retention Weight Index 36 96 74 112 112 112 112 146 180 206 230 264 -
530 652 787 798 810 850 1014 1149 1367 1762 2000 2407
Relative Intensity 100.0 9.9 2.3 1.2 2.1 0.7 0.9 4.9 3.8 1.9 0.6 0.9 12.9
[ Related References ] 1) Tsuge, S.; Okumoto, T.; Takeuchi, T. Makromol. Chem. 1969, 123, 123. 2) Tsuge, S.; Okumoto, T.; Takeuchi, T. Bull. Chem. Soc. Jpn. 1969, 42, 2870. 3) Montaudo, G.; Puglisi, C.; Scamporrino, E.; Vitalini, D. J. Polym. Sci., Polym. Chem. Ed. 1986, 24, 301. 4) Wang, F. C.-Y.; Smith, P. B. Anal. Chem. 1996, 68, 425. 5) Wang, F. C.-Y. J. Anal. Appl. Pyrolysis 2004, 71, 83.
113
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
051
EGA thermogram
Averaged mass spectrum 36 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
57 31
129 112 101
70 83
50
185
147
100
150
213
259
241
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
V : vinylidene chloride 36
Cl
61
Cl
H
96
Cl 63 36
BO : 1-butanol
82
O : C8H16 55
56 31
OH
41
41 70 78
112
146
Cl
Cl
Cl
77 51
111 75
50
74
37
TC : 1,3,5-trichlorobenzene
85
CS : trichlorostyrene 180
Cl
171 Cl
Cl
Cl
Cl
37
84 90
136
145 147
109
74
50
Cl 50 36
119
TN : trichloronaphthalene
85 99 109
206 159
175
Cl
266 Cl
Cl
Cl
Cl
62
74
CN : tetrachloronaphthalene 230
Cl
36
112
DC : m-dichlorobenzene
CB : chlorobenzene
36
83
29
160 80
98
116 125
159
194
Cl 195
98 222
36
61 74
123 133 115
159
231
114
Tsuge, Ohtani and Watanabe
052 Chlorinated poly(vinyl chloride); CPVC CH2CHCl
CHClCHCl
CH2CCl2
n
N HCL I
DP
DC
CN
MN
CB
B
TIC
6
7
8
AN
F
9
10
12
11
13
T
0
10
Peak Notation HCL B T CB DC I N MN DP CN F AN
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
hydrogen chloride benzene toluene chlorobenzene m-dichlorobenzene p-dichlorobenzene o-dichlorobenzene indene naphthalene 2-methylnaphthalene 1-methylnaphthalene diphenyl 2-chloronaphthalene fluorene anthracene [ Related References ] 1) Tsuge, S.; Okumoto, T.; Takeuchi, T. Bull. Chem. Soc. Jpn. 1969, 42, 2870. 2) Tsuge, S.; Okumoto, T.; Takeuchi, T. Macromolecules 1969, 2, 277. 3) Okumoto, T.; Ito, H.; Tsuge, S.; Takeuchi, T. Makromol. Chem. 1972, 151, 285.
36 78 92 112 146 146 146 116 128 142 142 154 162 166 178
650 766 850 1015 1021 1047 1057 1205 1319 1338 1403 1405 1622 1831
Relative Intensity 100.0 9.9 2.8 7.9 0.9 1.1 1.1 1.2 3.5 0.7 0.6 2.1 2.6 1.0 1.0
115
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
052
EGA thermogram
Averaged mass spectrum 36
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
78 74
50
91
112
50
128
100
141 152
165
178 188
202
150
216
200
250
[m/z]
( m/z range : 29 - 600 amu )
HCL : hydrogen chloride
B : benzene 36
78
Cl
H
52 39
T : toluene
74
CB : chlorobenzene 91
112
Cl
77 39
65
51
32
51 38
89
DC : o-dichlorobenzene
74
97
I : indene
Cl
116
146 Cl
111 37
75
50
118
85
57 63
39
140
N : naphthalene
89
CN : 2-chloronaphthalene 128
162
Cl
127
39
51
64
77
102
50
F : fluorene
68
81
99
136
AN : anthracene 166
178
82 39 51
69
98
115126 139
196
76 39
51
98 111
126 139
152 191
116
Tsuge, Ohtani and Watanabe
053 Chlorinated polyethylene; CM CH2CHCl
CH2CH2
n
C10 LB
C11 S
C12
C13
C14
C15 C16
I
C4
5
B TIC
6
10
Peak Notation
S C10 I C11 MI C12 C13 C14 C15 C16 C17
8
9
10
11
12
13
14
15
T
0
LB C4 B T
7
C17
MI
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
hydrogen chloride 1,3-butadiene benzene toluene 1-nonene styrene o-xylene 1-decene indane 1-undecene 1-methylindene tetrahydronaphthalene 3-methylindene 1-dodecene 1-tridecene 1-tetradecene 1-pentadecene 1-hexadecene 1-heptadecene [ Related References ] 1) Tsuge, S.; Okumoto, T.; Takeuchi, T. Macromolecules 1969, 2, 200. 2) Tsuge, S.; Okumoto, T.; Takeuchi, T. Bull. Chem. Soc. Jpn. 1969, 42, 2870. 3) Wang, F. C.-Y.; Smith, P. B. Anal. Chem. 1997, 69, 618.
36 54 78 92 126 104 106 140 118 154 130 132 130 168 182 196 210 224 238
395 653 767 894 896 899 995 1048 1096 1166 1180 1183 1196 1295 1396 1496 1592 1697
Relative Intensity 100.0 16.7 4.4 4.4 2.1 1.6 1.2 3.5 2.1 2.7 2.3 1.4 1.0 2.2 2.3 2.0 1.8 1.6 1.6
117
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
053
EGA thermogram
Averaged mass spectrum 41 55
67
91
79
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
105 129
50
100
141
155 165
178 189
150
202
216
231 250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
C4 : 1,3-butadiene 36
39
Cl
H
54
29
B : benzene
64
T : toluene 91
78
52
39
39
74
32
S : styrene
79
65
51
29
C10 : 1-decene 104
56
41
70 103 78
51 29
29
83 97
39
111
63
I : indane
140
MI : 1-methylindene 117
130 115
118 132 32 39
58 65
79
91
39
136
MI : tetrahydronaphthalene
51
64 81
91
MI : 3-methylindene
104
91
130
132 115
39 29
51
65 77
131
148 29
39
51
64 77
102
134
118
Tsuge, Ohtani and Watanabe
054 Vinyl chloride-vinyl acetate copolymer; P(VC-VAc) CH2CHCl
CH2CH(OCOCH3)
n
N LB
S X I MN
A 5
6
7
8
9
10
11
B TIC
T
0
10
Peak Notation LB A B T S X I N MN
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
hydrogen chloride acetic acid benzene toluene styrene o-xylene indene naphthalene 2-methylnaphthalene 1-methylnaphthalene [ Related Reference ] 1) Okumoto, T.; Takeuchi, T.; Tsuge, S. Bull. Chem. Soc. Jpn. 1970, 43, 2080.
36 60 78 92 104 106 116 128 142 142
605 650 766 895 899 1057 1204 1320 1339
Relative Intensity 100.0 20.8 13.8 3.3 1.2 0.6 1.7 3.4 1.0 0.9
119
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
054
EGA thermogram
Averaged mass spectrum 36
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
78
60 29
91 115 128 141 152 165 178 189 202
67 50
100
150
229 239 252
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
A : acetic acid 36
43
Cl
H
60
29
B : benzene
62
T : toluene 91
78
52
39
39
74
S : styrene
65
51
89
I : indene 104
115
103 78
51 44
63
39
57 63
89
118
MN : 2-methylnaphthalene
N : naphthalene
142
128
115 39
51
64
102
77
44 115
MN : 1-methylnaphthalene 142
115 44
57
71
91
129
158
132
146
57
7177
91
129
158
120
Tsuge, Ohtani and Watanabe
055 Chlorosulfonated polyethylene; CSM CH2
CH2(SO2Cl)
n
MI
C10
T
LB
CHCl
S
C11
I
MD
N
ID
C14
P
C4 3
TIC
4
5
6
7
8
10
9
C6 B
0
10
Peak Notation LB C4 C6 B T S P C10 I ID C11 MI
N MD C14 C15
Assignment of Main Peaks hydrogen chloride 1,3-butadiene 1-hexene benzene toluene 1-nonene styrene o-xylene phenol 1-decene indane indene 1-undecene 1-methylindene 3-methylindene tetrahydronaphthalene naphthalene C11H12 ? 1-tetradecene 1-methylnaphthalene
[ Related Reference ] 1) Smith, D. A.; Youren, J. W. Br. Polym. J. 1976, 8, 101.
30 [min]
20
Molecular Retention Index Weight 36 54 84 78 92 126 104 106 94 140 118 116 154 130 130 132 128 144 ? 196 210
395 594 653 767 894 897 899 986 995 1048 1057 1096 1167 1173 1179 1204 1296 1397 1497
Relative Intensity 100.0 17.4 5.3 4.9 4.3 1.6 2.1 1.5 0.9 2.1 1.7 1.6 1.7 2.7 1.4 1.6 1.3 1.5 1.0 0.7
121
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
055
EGA thermogram
Averaged mass spectrum 41 55
91
67 81
100
105
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
131 141 32 50
100
155 165 178 189 202 216 150
239 252
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
C4 : 1,3-butadiene
36
H
39
Cl
54
64
48
29
B : benzene
T : toluene 78
91
52
39
39
74
29
79
65
51
29
S : o-xylene
S : 1-nonene
91
56 43
106 69
29
83
97
39
108
126
C10 : 1-decene 41
51
29
65
77
ID : indene 116
56
70 29
83
97 111 122
C11 : 1-undecene 43
140
39
57 63
89 90
132
N : naphthalene 128
56 70 83
29
97 111119 134
154
43
57 64
85
102 117
132 146
122
Tsuge, Ohtani and Watanabe
056 Acrylonitrile-vinyl chloride copolymer; P(AN-VC) CH2CH(CN)
CH2CHCl
n
b BN
LB
AA
PN
TN
a
BA
P
MA B A TIC
7
6
CB
8
0
10
Peak Notation LB A MA B CB T CB BN AA TN BA PN a P b
9
10
11
12
13
14
T
Assignment of Main Peaks hydrogen chloride acetonitrile acrylonitrile methacrylonitrile benzene cyanobutadiene toluene cyanobutadiene cyanobenzene CH2(CN)CH2CH2CN CH2=C(CN)CH2CH2CN tolunitrile (m- ?) benzoic acid isophthalonitrile unidentified diethyl phthalate dibutyl phthalate
30 [min]
20
(A dimer)
[ Related Reference ] 1) Tanaka, M.; Nishimura, F.; Shono, T. Anal. Chim. Acta 1975, 74, 119.
Molecular Retention Weight Index 36 41 53 67 78 79 92 79 103 94 106 117 122 128 132 222 278
470 567 605 652 748 767 774 991 1065 1068 1101 1169 1276 1413. 1610 1980
Relative Intensity 100.0 4.6 7.3 2.5 1.5 3.5 1.3 4.1 3.9 1.5 1.8 2.0 3.8 3.2 3.2 1.6 3.0
123
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
056
EGA thermogram
Averaged mass spectrum 36
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
67
77
91 116
130
144 156
168
30 50
100
181
195
150
207
220
233
200
250
[m/z]
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
A : acrylonitrile 36
53
Cl
H
N
38
29
67
B : benzene
MA : methacrylonitrile 41
78
N
67 52
52 39
63
29
29
BN : cyanobenzene
T : toluene 91
103
N
76 39
50
65
51
39
89
TN : m-tolunitrile
AA : 2-methylenepentanedinitrile (A dimer) 66
N
117
N
39
N
106 52 79
90 89 63
51
118
PN : isophthalonitrile
BA : benzoic acid O
39
119
91
105
OH
128
122
77
N
N 51 39
104
75
91 50 66
92
38
76 116
144
124
Tsuge, Ohtani and Watanabe
057 Acrylonitrile-vinyl chloride alternating copolymer CH2CH(CN) CH2CHCl
n
c
LB
a CP
A
b PN
AV
6
5
TIC
VAV BN TN 7
0
10
Peak Notation LB A CB CP AV a BN TN PN VAV b c
8
9
10
11
12
CB
30 [min]
20
Assignment of Main Peaks hydrogen chloride acetonitrile acrylonitrile cyanobutadiene cyanobutene cyanobutadiene cyanopentadiene CH2=C(CI)CH2CH2CN (hybrid dimer) unidentified cyanobenzene tolunitrile (m- ?) isophthalonitrile CH2=C(CI)CH2CH(CN)CH2CH2CI (hybrid trimer) unidentified unidentified
[ Related Reference ] 1) Tanaka, M.; Nishimura, F.; Shono, T. Anal. Chim. Acta 1975, 74, 119.
Molecular Retention Weight Index 36 41 53 79 81 79 93 115 103 117 128 177 -
470 563 747 759 774 904 940 978 991 1100 1277 1289 1303 1457
Relative Intensity 100.0 6.8 17.3 8.7 13.5 10.2 3.0 4.7 6.5 6.0 2.6 4.5 7.7 6.0 26.5
125
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
057
EGA thermogram
Averaged mass spectrum 36
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
52
67
77
91
116
29 50
130
100
144
157 169
181
207
195
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
A : acrylonitrile 36
53
Cl
H
N
38
29
CB : cyanobutadiene
67
CB : cyanobutene 52
41
79
N
N
54
81
39 75
66
CB : cyanobutadiene
AV : 4-chloropent-4-enenitrile 52
75
N N
Cl 39
115
79
53
77
39
118
75
29
90
TN : m-tolunitrile
BN : cyanobenzene (+ unidentified) 103
117
N
41
N
76
39
50 104
75
118
29
122
PN : isophthalonitrile
90 89
63
51
VAV : 4-chloro-2-(2-chloroethyl)-4-pentenitrile 128
128
N Cl
Cl 75
N
N
39
44
50
64
81
76 49
101 116
135
153
29
106 102 142
177
126
Tsuge, Ohtani and Watanabe
058 Methyl acrylate-vinyl chloride copolymer; P(MA-VC) CH2CH(COOCH3)
CH2CHCl
n
MN’ MC
MMM LB P B MMA TIC
7
8
9
10
11
12
M T
0
10
Peak Notation
Assignment of Main Peaks
LB MC M B MMA T MM’ P MMM
hydrogen chloride + CO2 methyl chloride methyl acrylate benzene methyl methacrylate toluene CH2(COOCH3)CH2CH2COOCH3 diethyl phthalate CH2=C(COOCH3)CH2CH(COOCH3)CH2CH2COOCH3
30 [min]
20
[ Related Reference ] 1) Tanaka, M.; Nishimura, F.; Shono, T. Anal. Chim. Acta 1975, 74, 119.
Molecular Retention Weight Index 36; 44 50 86 78 100 92 160 222 258
150 327 607 653 711 767 1138 1610 1671
Relative Intensity 46.5 100.0 8.3 1.5 2.2 1.7 8.8 2.1 4.7
127
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
058
EGA thermogram
Averaged mass spectrum 50
44 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31
91
79
67 50
115
129 141 152
100
165
178 189
202
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : hydrogen chloride ( + carbon dioxide ) Cl
H
MC : methyl chloride
44
50
Cl
+ O
C
O
47
B : benzene
M : methyl acrylate 55
78
O
O
85
42
31
39
68
52 74
31
MMA : methyl methacrylate
T : toluene
41
91 O 69 O 100 59
31
85
29
MM' : dimethyl glutarate O
O
65
51
79
P : diethyl phthalate
59
O
149
O O
O
100 O
39
129
O
42 87 29
177
74
132
MMM : trimethyl hex-5-ene-1,3,5-tricarboxylate O
O
O
O
O
194
79
106
59
167
125
41 29
134
O
67
93
227 153
29
50 65 76
93 105 121
222
128
Tsuge, Ohtani and Watanabe
059 Methyl acrylate-vinyl chloride alternating copolymer CH2CH(COOCH3)
CH2CHCl
n
F MC I
LB
TIC
5
TM E M
6
7
8
9
12
11
10
T 0
10
Peak Notation
Assignment of Main Peaks
LB MC TM M E T F I
hydrogen chloride + CO2 methyl chloride trichloromethane methyl acrylate ethyl acrylate toluene furfuryl methyl ether indene
30 [min]
20
Molecular Retention Weight Index
O
CH2OCH3
[ Related Reference ] 1) Tanaka, M.; Nishimura, F.; Shono, T. Anal. Chim. Acta 1975, 74, 119.
36; 44 50 117 86 100 92 112 116
150 327 605 607 694 767 867 1057
Relative Intensity 44.5 100.0 2.8 1.1 1.2 2.2 0.7
129
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
059
EGA thermogram
Averaged mass spectrum 50
100
44
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
91
77
67
31
115
50
128
100
145152
165
178 189
202
150
226 250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : hydrogen chloride (+ carbon dioxide)
MC : methyl chloride 50
44
Cl
H
H
+ O
C
H
O
Cl H
47 29
29
TM : trichloromethane
M : methyl acrylate 83
55
Cl
O
Cl O
Cl 47 29
120
70
E : ethyl acrylate 43
42
85
68
T : toluene 91
O
55
O 29
71
85
100
39 31
F : furfuryl methyl ether
65
51
79
I : indene
53
O 81
116 O
112
97 31 39
69
39 32
57
63
89
124
130
Tsuge, Ohtani and Watanabe
2.2.7 Fluorine-containing vinyl polymers 060 Polytetrafluoroethylene; PTFE CF2CF2
n
M
TIC
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
M
tetrafluoroethylene
Molecular Retention Weight Index 100
Relative Intensity
-
100.0
[ Related References ] 1) Madorsky, S. L.; Hart, V. E.; Straus, S.; Sedlak, V. A. J. Res. Nat. Bur. Std. 1953, 51, 327. 2) Morisaki, S. Thermochim. Acta. 1978, 25, 171. 3) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 4) Lonfei, J.; Jingling, W.; Shuman, X. J. Anal. Appl. Pyrolysis 1986, 10, 99.
EGA thermogram
Averaged mass spectrum 81 31 100
200
300
400
100
50 69
43
500
600
700 ºC
programming rate: 20ºC/min
131
50
100
150
[m/z]
( m/z range : 29 - 600 amu )
M : tetrafluoroethylene 81
F
F
F
F
100 31 50 43
69
131
150
131
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
061 Tetrafluoroethylene-hexafluoropropylene copolymer; FEP CF2CF2
CF2CF(CF3)
n
M
TIC
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Index Weight
M
tetrafluoroethylene, hexafluoropropylene
100, 150
Relative Intensity
-
100.0
[ Related References ] 1) Morisaki, S. Thermochim. Acta. 1978, 25, 171. 2) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 3) Lonfei, J.; Jingling, W,; Shuman, X. J. Anal. Appl. Pyrolysis 1986, 10, 99. 4) Shadrina, N. E.; Dmitrenko, A. V.; Pavlova, V. F.; Ivanchev, S. S. J. Chromatogr. 1987, 404, 183.
EGA thermogram
Averaged mass spectrum 81
31
100
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
50
131
69
150
44 132 50
100
150
181 200
250 [m/z]
( m/z range : 29 - 600 amu )
M : tetrafluoroethylene (+ hexafluoropropylene) 131
F
F
100
F
150
31
F
F
F F F
50 44 112
F
+
69 81
132
181
200
F
132
Tsuge, Ohtani and Watanabe
062 Polychlorotrifluoroethylene; PCTFE CF2CFCl
n
B6 M TF M’
C4
A2
B3
B2 C2 D
A3
B5
C6 A6
B4 C5
C3 A4
B7 C7 A7
A5
B8
B9
C9 A9 B10 C8 A8
10
20
TIC
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Weight Index
M TF M’ A2 B2 C2
CF2=CFCI + C3CI F5 (monomer) CFCl3 C3CI2F4 CF2CI-CFCI2 C4CI2F6 (dimer) C5CI2F8
116; 166 136 182 186 232 282
D
C7CI2F10 ?
344
A3 B3
C4CI4F6 ? C6CI4F9 (trimer)
304 383
C3
C7CI3F11 ?
398
A4
C6CI5F12
475
B4
C8CI4F12 (tetramer)
464
C4 A5 B5
C9CI4F14 ? C8CI6F15 ? C10CI5F15 (pentamer)
514 591 580
C5
C11CI5F17 ?
630
C6 B6 B7
C12CI6F20 ? C12CI6F18 (hexamer) C14CI7F21 (heptamer)
734 696 812
[ Related References ] 1) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 2) Lonfei, J.; Jingling, W,; Shuman, X. J. Anal. Appl. Pyrolysis 1986, 10, 99.
280 400 440 461 693 696 742 746 764 819 863 865 1054 1086 1088 1114 1343 1359 1372 1373 1628 1635 1915
Relative Intensity 100.0 3.3 2.5 4.7 3.3 0.3 0.8 0.6 0.7 0.6 1.0 2.5 1.0 0.9 0.6 1.9 1.2 2.0 0.7 3.2 0.8 1.0 0.3 5.7 2.6
133
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
062
EGA thermogram
Averaged mass spectrum 131
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31
85
69
50 50
116
101
135
147
100
163
150
181
203 217
243
200
259 300 [m/z]
250
( m/z range : 29 - 600 amu )
M : chlorotrifluoroethylene
TF : trichlorofluoromethane
(+ 3-chloropentafluoropropene) F
F F Cl +
Cl
101
116
Cl
F Cl
F
Cl
F
F 31
F
85
66
F
118
97
47 50
31
M' : 1,2-dichlorotetrafluoro propane
66
47
105 119
82
147
A2 : 1,1,2-trichloro-1,2,2-trifluoroethane (+ unidentified)
147
162
F F
Cl
101
Cl
F
Cl 85
93
116
163
132
182 193
F
Cl
69
47
Cl
F
151
F
31
182
243 259
31 278
A3 : C4Cl4F6
F
85 47
116
66
143
259
193 209
243
278 293
B3 : C6CI4F9 (trimer) 101
131
85 116 31
47
69
118 147
197
217 230
275
309
344
B4 : C8CI4F12 (tetramer)
31 47
69 85 101 116
69 85 101 116
B6
147 163
197
263
297
131
69
225
263
348
131
: C12CI6F18 (hexamer)
31
181197
B5 : C10CI5F15 (pentamer)
131
31
147
85 101 147 116 135 163
201217
247
279
335
31
69 85 101
147
163
247
297
134
Tsuge, Ohtani and Watanabe
063 Poly(vinyl fluoride); PVF CH2CHF
n
N I
LB
MI S
MN
X
B
AN
E
FB T
TIC
F AC
6
5
7
8
9
10
11
12
13
CP
0
10
Peak Notation LB CP B FB T E S X I MI N MN AC F AN
Assignment of Main Peaks low boiling point components cyclopentadiene benzene fluorobenzene toluene ethylbenzene styrene o-xylene indene 1-methylindene 3-methylindene naphthalene 2-methylnaphthalene 1-methylnaphthalene acenaphthene fluorene anthracene
30 [min]
20
Molecular Retention Index Weight 66 78 96 92 106 104 106 116 130 130 128 142 142 154 166 178
[ Related References ] 1) Madorsky, S. L.; Hart, V. E.; Straus, S.; Sedlak, V. A. J. Res. Nat. Bur. Std. 1953, 51, 327. 2) Chatfied, D. A. J. Polym. Sci., Polym. Chem. Ed. 1983, 21, 1681. 3) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 71, 215. 4) Nguyen, T. J. Macromol. Sci., Rev. Macromol. Chem. Phys. 1985, C25, 227.
510 659 675 769 865 894 897 1054 1163 1179 1200 1315 1333 1402 1614 1823
Relative Intensity 100.0 4.1 20.8 3.1 13.5 2.1 5.9 3.0 8.2 5.0 5.0 9.9 4.5 3.5 1.1 3.2 3.4
135
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
063
EGA thermogram
Averaged mass spectrum 85
100
200
300
400
500
600
91 39 33
51
115 129 141
65
50
700 ºC
programming rate: 20ºC/min
100
153 165 178 191 150
216 230 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
CP : 1,3-cyclopentadiene
B : benzene
66
78
39 61
29
79
39
163
T : toluene
51 74
114
S : styrene 91
104
103
78 39
51
65
51
79
63
39
I : indene
MI : 1-methylindene 130
115 115
89 90
57 63
39
39
133
MI : 3-methylindene
51
64
77
132
102
N : naphthalene 128
130
115
39
51
64
102
77
39
MN : 2-methylnaphthalene
51
64
102
77
MN : 1-methylnaphthalene 142
142
115 39
57
71
89
146
115 129
159
196
39
57
71
89 98
126
159
176
136
Tsuge, Ohtani and Watanabe
064 Poly(vinylidene fluoride); PVDF CF2CH2
n
F5’ F6 FN
TS
F7 F8
T
F9 FA F10
F5
F11 F12
F13
F14
F15 F16 F17
FB VF 2
4
6
8
10
12
14
16
18
TIC
0
10
Peak Notation
Assignment of Main Peaks
VF FB T F5 F5’ F6 FN F7 F8 F9 FA F10 F11
vinylidene fluoride 1,3,5-trifluorobenzene CF2=CHCF2CH=CF2 C11H10F10 C11H9F11 C13H12F12 C10H4F4 (tetrafluoronaphthalene) C15H14F14 C17H16F16 C19H18F18 C14H5F5 (pentafluoroanthracene) C21H20F20 C23H22F22
30 [min]
20
Molecular Retention Weight Index 64 132 176 332 350 396 200 460 524 588 268 652 716
[ Related References ] 1) Madorsky, S. L.; Hart, V. E.; Straus, S.; Sedlak, V. A. J. Res. Nat. Bur. Std. 1953, 51, 327. 2) Hagiwara, M.; Ellinghorst, G.; Hummel, D. O. Makromol. Chem., 1977, 178, 2913. 3) Nguyen, T. J. Macromol. Sci., Rev. Macromol. Chem. Phys. 1985, C25, 227. 4) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 5) Lonfei, J.; Jingling, W,; Shuman, X. J. Anal. Appl. Pyrolysis 1986, 10, 99.
625 805 970 1062 1119 1147 1316 1488 1658 1681 1827 1994
Relative Intensity 100.0 5.9 5.0 2.5 3.8 3.2 3.1 3.0 2.6 2.6 1.3 2.1 2.5
137
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
064
EGA thermogram
Averaged mass spectrum 85
100
113 51 65
95
121
300
400
500
100
600
700 ºC
programming rate: 20ºC/min
159169177189
3139 50
200
133
150
213 223 241
200
261
287 305
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
TS : tetrafluorosilane
FB : 1,3,5-trifluorobenzene 85
F F
F
132
Si
F F
F 47 51
33
64
102
63 57
31 39
F
F
154
172
115
F
F
F
153
101 112
F5 : C11H10F10
T : 1,1,3,3,5,5-hexafluoropenta-1,4-diene 108
81
F
133
F
51
236 64
39
83
57
103 133
172
203217
46
290
64
95
113
223
243
269
121
115
51 51 69
197
F6 : C13H12F12
F5' : C11H9F11
39
159 179
77
65 101 77
133 157 179 197
95
223 238
39
285 311
165 133 159 185
215 235
279 299 325
364
F7 : C15H14F14
FN : tetrafluoronaphthalene 200
115
F
133
F F 51
F 61 75
31
169 180 100111 129 150
64 218
46
274
FA : pentafluoroanthracene F
268
F F F 31
86
134 151
237 217 248 198
F
414 439 477
95
159 179197 223 287 243 261
351
397
138
Tsuge, Ohtani and Watanabe
065 Vinylidene fluoride-hexafluoropropylene rubber CF2CF2
CF2CH2
CF2CF(CF3)
n
LB E A
D B
TIC
7
6
0
10
Peak Notation LB A B C D E
8
9
10
11
C
Assignment of Main Peaks (vinylidene fluoride + tetrafluoroethylene + hexafluoropropylene) CF2=CHCF2CF2CH=CF2 unidentified C8H5F9 unidentified C12H2F10 ?
30 [min]
20
Molecular Retention Weight Index 64; 100 150 226 222 272 336
[ Related References ] 1) Blackwell, J. T. Anal. Chem. 1976, 48, 1883. 2) Nguyen, T. J. Macromol. Sci., Rev. Macromol. Chem. Phys. 1985, C25, 227. 3) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 4) Lonfei, J.; Jingling, W,; Shuman, X. J. Anal. Appl. Pyrolysis 1986, 10, 99.
710 761 853 941
Relative Intensity 100.0 23.7 4.4 4.5 3.2 7.5
139
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
065
EGA thermogram
Averaged mass spectrum 113
163 69 51
100
200
300
400
500
77
600
700 ºC
programming rate: 20ºC/min
133 95
31 45
157
131
50
100
197 207
175
150
229 241
200
259
277
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
LB : vinylidene fluoride (+ tetrafluoroethylene + hexafluoropropylene) 44
F
85 64
F +
+
F
114
F
F
F
F
F
F F
95
131
163 F
150 164
182
B : unidentified
51 69
51 77
95
119 144
95
39
F
F 189
228
257
307
C : C8H5F9
113
113
133 163 179 213 229
39
F
F
F
51
F
113
F
F
31
A : 1,1,3,3,4,4,6,6-octafluorohexa-1,5-diene
F
269
319
357
409
D : unidentified
39
51 69 95 77
160
133
245
273
319
E : C12H2F10 163
113
163 133 113 51
77
95
197 229
263
307
371 391 423
51
133
77 95
177
224
285
317
367
140
Tsuge, Ohtani and Watanabe
066 Propylene-tetrafluoroethylene rubber CH2CH(CH3)
CF2CF2
n
TE H
P
H’
TE’ HP LB
FP’ FP T
TIC
O
P’
T’
P’’
T’’
0
10
Peak Notation LB FP FP’ T T’ T” TE TE’ P P’ P’’ H H’ HP O
Assignment of Main Peaks propylene, tetrafluoroethylene C5H6F4 (hybrid dimer) C6H6F6 C7H6F8 (FPF hybrid trimer) C8H12F6 ? C8H6F10 C8H8F8 C8H10F6 C10H12F8 (FPFP hybrid tetramer) C11H12F10 C12H12F12 (FFPFP hybrid pentamer) C12H12F12 (FPFPF hybrid pentamer) C13H12F14 C13H16F10 C15H18F12 (FPFPFP hybrid hexamer) C16H18F14 C17H18F16 (FPFPFPF hybrid heptamer) C20H24F16 (FPFPFPFP hybrid octamer) * F : unit of tetrafluoroethylene ; P : unit of propylene
30 [min]
20
Molecular Retention Index Weight 42, 100 142 192 242 222 292 256 220 284 334 384 384 434 362 426 476 526 568
295 648 675 724 738 760 920 979 1028 1034 1088 1153 1300 1349 1396 1671
Relative Intensity 25.7 100.0 47.0 67.5 34.9 11.9 7.9 14.5 75.1 55.2 22.3 35.1 18.8 11.3 60.2 34.4 36.6 35.3
141
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
066
EGA thermogram
Averaged mass spectrum 91
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
65 51 47
77
109
33 50
127 141
100
161
181 193
150
223
263
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
FP : C5H6F4
FP' : C6H6F6 91
65
91
41 51
142
77
65
41
192
51 33
110 123
151 160
178
77
33
T : C7H6F8 (FPF hybrid trimer)
109
127 141
156 171
TE : C10H12F8 (FPFP hybrid tetramer) 91
91
65 65 242
51
41
77
33
109 123 139
171 183
39 51
206
P : C12H12F12 (FFPFP hybrid pentamer)
77
156 173 193
216
284
245
91
65 109 133 159
77
133
P : C12H12F12 (FPFPF hybrid pentamer)
91
3951
215 109
315 209
273 293
345
51
384
H : C15H18F12 (FPFPFP hybrid hexamer)
65 77
109
159 141 173
223
255 274
384 315 345
H' : C16H18F14 91
91
65
47
77
109
173193 153
357 231
295
335
426
HP : C17H18F16 (FPFPFPF hybrid heptamer)
65 51
109 141 161
199
263 295 243
366
476 407 437
O : C20H24F16 (FPFPFPFP hybrid octamer)
91
91
65
65 77 109
51
141161183
223
273
345
395
416 457 487 526
47
77 109
173 193 141 213
499 231 263 295
347
437 457
142
Tsuge, Ohtani and Watanabe
2.2.8 The other vinyl polymers 067 Poly(vinyl alcohol); PVA CH2CH(OH)
A
n
C
C7 AC D H EA
TIC
B
MB
0
10
Peak Notation
Assignment of Main Peaks
A AC D C EA H C7 B MB
acetaldehyde acetone 2,5-dihydrofuran crotonaldehyde CH3CH=CHCHO ethylidene acetone CH3CH=CHCH=CHCHO C7H12 (methyl hexadiene ?) benzaldehyde methylbenzaldehyde [ Related Reference ] 1) Wang, F. C.-Y. J. Chromatogr. A 1996, 753, 101.
30 [min]
20
Molecular Retention Weight Index 44 58 70 70 70 96 96 106 120
404 463 573 640 740 901 912 965 1075
Relative Intensity 100.0 9.7 14.9 95.9 4.1 2.9 46.6 5.8 3.2
143
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
067
EGA thermogram
Averaged mass spectrum 39
100
200
300
400
500
81
700 ºC
91
70
53
600
programming rate: 20ºC/min
105
31 50
122 133
100
155 165
178
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
A : acetaldehyde
AC : acetone 43
29
O
44
O
58 29
D : 2,5-dihydrofuran
70
EA : ethylidene acetone 41
O
69
O 41
70 84 29 50
29
C : crotonaldehyde
50
H : 2,4-hexadienal 70
O
81
41
O
39 29
C7 : methylhexadiene
91
O
120
65 51
108
O
77
105
106
77
51
29
MB : methylbenzaldehyde
39
95
96
67
53
29
29
67
B : benzaldehyde 81
39
53
29
50
39
74
95
144
Tsuge, Ohtani and Watanabe
068 Poly(vinyl butyral); PVB CH2CHCH2CH
n
OCHO C3H7
B
BT
BA LB
C
F 3
TIC
A
4
5
6
7
AP
0
10
Peak Notation
Assignment of Main Peaks
LB A F BT C BA B AP
propylene acetaldehyde O 2,5-dihydrofuran n-butanal crotonaldehyde CH3CH=CHCHO butyric acid benzaldehyde acetophenone
30 [min]
20
Molecular Retention Weight Index 42 44 70 72 70 88 106 120
295 408 571 610 639 816 965 1072
Relative Intensity 11.2 10.0 9.4 100.0 24.8 1.5 4.1 1.2
145
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
068
EGA thermogram
Averaged mass spectrum 43
100
29
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
72 57 77
92
50
105
143
123
100
155
169
150
200
250
[m/z]
( m/z range : 29 - 600 amu )
A : acetaldehyde
LB : propylene
29
41 44
O
29 56
F : 2,5-dihydrofuran
BT : n-butanal 41
O
44
72
O 29 70
57
29 50
C : crotonaldehyde
BA : butyric acid 70
O
60
O
41
OH 41 29
73
29
55
88 94
B : benzaldehyde
AP : acetophenone 106
77
105
O 77 O
51
120 51
29
39
74 95
43
74
91
146
Tsuge, Ohtani and Watanabe
069 Poly(vinyl acetate); PVAc CH2CH(OCOCH3)
n
N
A I
EA
MI
X1 S
B E
LB
MN X2
5
T
AC
I’
6
7
8
9
11
10
TIC
0
10
Peak Notation LB EA A B T E X1 S X2 I’ I MI N MN AC
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
ketene, etc. ethyl acetate acetic acid benzene toluene ethylbenzene p-xylene styrene o-xylene indane indene 1-methylindene 3-methylindene naphthalene 2-methylnaphthalene 1-methylnaphthalene acenaphthene [ Related Reference ] 1) Sellier, N.; Jones, C. E. R.; Guichon, G. J. Chromatogr. Sci. 1975, 132, 383.
42 88 60 78 92 106 106 104 106 118 116 130 130 128 142 142 154
150 606 643 657 768 864 873 894 896 1048 1054 1162 1178 1200 1315 1333 1398
Relative Intensity 6.6 20.4 100.0 11.6 3.3 0.6 0.3 1.7 0.4 0.6 2.2 1.4 2.3 4.5 1.1 0.9 1.4
147
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
069
EGA thermogram
Averaged mass spectrum 43
100
60
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
29 67
77
91
50
115
128
100
141 152
165
178
191 202
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
EA : ethyl acetate
A : acetic acid O
43
43
O 60
OH
O
29
61
70
29
88
B : benzene
62
T : toluene 91
78
51
39
39
74
I' : indane
65
51
89
I : indene 115
117 118
91 31
39
51
63
78
58 63
39
MI : 1-methylindene
89 90
MI : 3-methylindene 129
130
115 115
51 39
64
77
102
132
N : naphthalene
39
64
51
77
102
AC : acenaphthene 128
39
146
51
64
77
102
154
39
51 63
76
102 115 128 139
148
Tsuge, Ohtani and Watanabe
070 Poly(vinyl pyrrolidone); PVP CH2 CH N
n
O
C
F B
E
H
D
A
TIC
G
0
10
Peak Notation A
Assignment of Main Peaks CH 3 N O
H N
B
O
CH=CH 2 N O
C
30 [min]
20
(monomer)
Molecular Retention Weight Index
Relative Intensity
99
1043
5.3
85
1088
14.5
111
1118
100.0
125
1181
3.7
222
2079
13.3
210
2101
9.6
234
2120
3.5
333
2974
20.1
CH2=C- CH3 N
D
O
CH2= C - CH 2 - CH2
E
N
O N
O
(dimer)
CH2 CH2 CH2
F
N
N
O
O
CH2=C - CH2 -C=CH2
G
H
N
O
N
O
CH2=C - CH2 - CH- CH2 - CH2 N O N O N O
(trimer)
[ Related Reference ] 1) Ericsson, I.; Ljunggren, L. J. Anal. Appl. Pyrolysis 1990, 17, 251.
149
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
070
EGA thermogram
Averaged mass spectrum 56
100
200
300
400
500
600
41 68
30
700 ºC
programming rate: 20ºC/min
111 98
85
124
50
137
100
150
163
210
150
222
200
250
[m/z]
( m/z range : 29 - 600 amu )
A : 1-methyl-2-pyrrolidinone
B : 2-pyrrolidinone 99
H N N
85
O
O
44
41 30 71
56
30
56 66
82
C : 1-vinyl-2-pyrrolidinone (monomer) 56
D : 1-(prop-1-en-2-yl)pyrrolidin-2-one 125
70
111
N
O
N
O 42 82
68
41
82
96
30 54
29
E : 1,1'-(but-3-ene-1,3-diyl)dipyrrolidine-2-one (dimer)
111
F : 1,1'-(propane-1,3-diyl)dipyrrolidin-2-one 112
98 137 N
O
N
N
O
99
70 41 82 30
109
O
N
O
70
124
204
55
151 166
179 194
41 222
84
56
210
125
30
139 154
182
H : 1,1',1''-(hex-5-ene-1,3,5-triyl)tripyrrolidin-2-one G : 1,1'-(penta-1,4-diene-2,4-diyl)dipyrrolidin-2-one)
(trimer)
126
124 N
O
N
N
O
178
N
O
O
N
O
98 234
41 56 30
82 96107 69
149 136
206 164
191
41 219
283
30
56
70
82
163 110 136150
193
209 221
248 262
305
333
150
Tsuge, Ohtani and Watanabe
2.2.9 Diene-type elastomers 071 High cis-butadiene rubber; BR CH2CH
CHCH2
n
T3
M D
T2
T4 TE
T1
C5 15
10
TIC
B
trimers
T
0
10
tetramers
pentamers
hexamers
heptamers
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Weight Index
M C5 B T D T1 T2 T3 T4
1,3-butadiene 1,3-pentadiene benzene toluene 4-vinylcyclohexene (dimer) C11H16 C12H18 (trimer) C12H18 C12H18
54 68 78 92 108 148 162 162 162
TE
C16H26 (tetramer)
218
[ Related References ] 1) Shono, T.; Shinra, K. Anal. Chim. Acta 1971, 56, 303. 2) Alexeeva, K. V.; Kharanova, L. P.; Solomatina, L. S. J. Chromatogr. 1973, 77, 61. 3) Braun, D.; Canji, E. Angew. Makromol. Chem. 1974, 35, 27. 4) Ericsson, I. J. Chromatogr. Sci. 1978, 16, 340. 5) Haeusler, K. G.; Schroeder, E.; Huster, B. J. Anal. Appl. Pyrolysis 1980, 2, 109. 6) Radhakrishnan, T. S.; M. R. J. Polym. Sci., Polym. Chem. Ed. 1981, 19, 3197. 7) Schrafft, R. Kautsch. Gummi Kunstst. 1983, 36, 851. 8) Choi, S.-S. J. Anal. Appl. Pyrolysis 2001, 57, 249.
395 490 650 766 834 1091 1139 1164 1237 1553 1567 1580 1604
Relative Intensity 100.0 4.6 8.2 6.3 77.9 7.1 6.7 6.3 6.4 1.5 2.2 1.8 1.9
151
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
071
EGA thermogram
Averaged mass spectrum 79 91
67 41
100
55
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
105 119
50
133
147
100
161 175
150
189 202
216 230
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
M : 1,3-butadiene
B : benzene 78
54
39
52
39
29
D : 4-vinylcyclohexene
74
T2 : C12H18 (trimer)
54
79
79
93
119 133 66
39
93
41
67 147
53
108
29
162
29
T3 : C12H18 (trimer)
T4 : C12H18 (trimer) 79
79 93
93 119 119
105
106
67
41
133
147
54
147
53
162
29
133
67
41 29
TE : C16H26 (tetramer)
162 176
TE : C16H26 (tetramer) 55
55
67
67 79
79
91
41
107
29
41 121
153 168
189
93 109
29 216
230
TE : C16H26 (tetramer)
147 161
189
159
187
228
TE : C16H26 (tetramer) 79 91
79 91 55 41
67
119 29
67
41
105 145
106 55
165 187
216
230
29
119
133
202 216
230
152
Tsuge, Ohtani and Watanabe
072 Poly(1,2-butadiene) CH2CH(CH CH2)
n
D
M
T2
X2 X1
C10
TE
T3
a
C9
b
EB S
10
TIC C3
C5
trimers
B C7 T
0
10
Peak Notation
Assignment of Main Peaks
C3 M C5 B C7 T D EB X1 S X2 C9 C10 T2 T3 TE a b
propylene etc. 1,3-butadiene pentadiene benzene cycloheptadiene toluene 4-vinylcyclohexene (dimer) ethylbenzene p-xylene styrene o-xylene C9H12 C10H14 C12H18 (trimer) C12H18 C15H24 (tetramer) unidentified unidentified
15
tetramers
pentamers
30 [min]
20
Molecular Retention Weight Index 42 54 68 78 94 92 108 106 106 104 106 120 134 162 162 204 320 ?
[ Related References ] 1) Shono, T.; Shinra, K. Anal. Chim. Acta 1971, 56, 303. 2) Braun, D.; Canji, E. Angew. Makromol. Chem. 1974, 35, 27. 3) Haeusler, K. G.; Schroeder, E.; Huster, B. J. Anal. Appl. Pyrolysis 1980, 2, 109. 4) Radhakrishnan, T. S.; Rao, M. R. J. Polym. Sci., Polym. Chem. Ed. 1981, 19, 3197.
295 395 492 650 703 765 836 865 874 895 896 926 1013 1183 1211 1481 1694 2789
Relative Intensity 11.3 100.0 4.5 1.7 3.8 5.9 8.1 1.8 1.6 0.6 0.9 2.3 2.9 3.8 1.6 5.7 2.0 1.1
153
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
072
EGA thermogram
Averaged mass spectrum 91 79 41 55
100
105
67
300
400
500
600
700 ºC
programming rate: 20ºC/min
119
50
200
133
147
100
165 178 189 202
150
216 230
256 270
200
250
300 [m/z]
( m/z range : 29 - 600 amu )
M : 1,3-butadiene
C5 : 1,4-pentadiene 39
67
54
53 39
31
29
B : benzene
C7 : cycloheptadiene 66
78
79
39 52
39 32
67
T : toluene
91
51
29
D : 4-vinylcyclohexene 91
54
79 39
66
79
39
55
32
93
65
108
29
C10 : C10H14
T2 : C12H18 (trimer) 79
41 79
93
67 91 39
105
66
53
55 133
29
T3 : C12H18 (trimer)
29
147
TE : C15H24 (tetramer) 79
41 94
107 67
41 29
119 93
55
67
133 162
79
55
105 119
119
29
105 119
133 147
133 147 173
162
201
154
Tsuge, Ohtani and Watanabe
073 Natural rubber; NR CH2C(CH3) CHCH2
n
M T1 D
MP
TE1
T2 T3
TE2
C10
D’’ D’ TIC LB
T
20
10
trimers
tetramers
pentamers
hexamers
X
0
10
Peak Notation
Assignment of Main Peaks
LB M T X D’ D’’ D MP
propylene etc. isoprene toluene m-xylene 2,4-dimethyl-4-vinylcyclohexene C10H16 dipentene methylisopropylbenzene ?
C10
C10H16
T1 T2 T3 TE1 TE2
C15H24 C15H24 C15H24 C20H32 C20H32
(trimer)
(tetramer)
30 [min]
20
Molecular Retention Weight Index
(dimer)
42 68 92 106 136 136 136 134 136 136 204 204 204 272 272
[ Related References ] 1) Alexeeva, K. V.; Khranova, L. P.; Solomatina, L. S. J. Chromatogr. 1973, 77, 61. 2) Braun, V. D.; Canji, E. Angew. Makromol. Chem. 1974, 36, 67. 3) Chien, J. C. W.; Kiang, J. K. Y. Eur. Polym. J. 1979, 15, 1059. 4) Naveau, J.; Dieu, H. J. Anal. Appl. Pyrolysis 1980, 2, 123. 5) Schrafft, R. Kautsch. Gummi Kunstst. 1983, 36, 851. 6) Groves, S. A.; Lehrle, R. S. J. Anal. Appl. Pyrolysis 1991, 19, 301. 7) Choi, S.-S. Bull. Korean Chem. Soc. 1999, 20, 445. 8) Chen, F.; Qian, J. Fuel 2002, 81, 2071.
295 470 766 874 965 1019 1038 1122 1135 1149 1452 1472 1484 1941 2002
Relative Intensity 3.6 100.0 3.4 3.6 7.9 4.0 68.3 1.0 0.5 0.4 0.9 1.1 1.0 1.5 1.0
155
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
073
EGA thermogram
Averaged mass spectrum 67
79
53
39
93
100
200
300
400
500
600
107
700 ºC
programming rate: 20ºC/min
121 136 147 50
100
150
161 175
189
204
272
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
X : m-xylene
M : isoprene
91
67 53
106
39
39
29
51
D' : 2,4-dimethyl-4-vinylcyclohexene
77
65
32
D'' : .2,5-dimethyl-3-methylene-1,5-heptadiene
68
107 91
93 79 41 107 41
53
121
79
121
53
29
136
67
136
29
D : dipentene
T1 : C15H24 (trimer) 68
121 93 93
41
107
81 79 53
39
55 107
121
136
67
133
29
147
204 175
T2 : C15H24 (trimer)
T3 : C15H24 (trimer) 107
119 41
41
93 55
93 55
119
79
133
67
29
147 161
147 161 175 189 204
TE1 : C20H32 (tetramer)
93 41 55
93 107
175
189 204
TE2 : C20H32 (tetramer)
121
29
107
79
134
67
41 55
189
161
29
81
107 119
134 67
81 29 149 161
203
229
272
132 161175 203
257
156
Tsuge, Ohtani and Watanabe
074 Chloroprene rubber; CR CH 2 CCl
CHCH 2
n
DC
HCL
T
D M C4
TIC
CB M’ a T CT CX S B b
0
15
10
D’
10
Peak Notation
Molecular Retention Weight Index 36 54 88 90 78 102 121 92 112 104 126 140 176
395 550 618 653 722 740 766 850 896 962 1101 1255
Relative Intensity 100.0 7.8 19.2 1.3 1.6 1.3 3.8 2.4 1.3 1.1 1.4 1.4 4.4
C8H9Cl3
176 210
unidentified
254 ?
1259 1444 1950 2031 2068 2104
19.8 5.5 1.7 2.9 2.5 4.4
Assignment of Main Peaks
HCL C4 M M’ B a b T CB S CT CX D’
hydrogen chloride 1,3-butadiene chloroprene chlorobutene (C-C(Cl)=C-C ?) benzene C5H7Cl (C=C(Cl)-C=C-C ?) C4H4Cl2 (Cl-C=C-C=C-Cl ?) toluene chlorobenzene styrene chlorotoluene ( or isomer ) chloroxylene (or isomer ) Cl Cl ) C8H10Cl2 (dimer
D DC
C8H10Cl2 (dimer
T
30 [min]
20
Cl
Cl
)
* bonding hydrogen is omitted
[ Related References ] 1) Gardner, D. L.; McNeill, I. C. Eur. Polym. J. 1971, 7, 593. 2) Fuh, M.-R. S.; Wang, G.-Y. Anal. Chim. Acta 1998, 371, 89. 3) Lehrle, R. S.; Dadvand, N.; Parsons, I. W.; Rollinson, M.; Horn, I. M.; Skinner, A. R. Polym. Degrad. Stab. 2000, 70, 395.
157
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
074
EGA thermogram
Averaged mass spectrum 91
36
105
77
53
100
128 141
200
300
400
500
600
155
178 189 202
31 50
100
700 ºC
programming rate: 20ºC/min
165
65
150
239 285 289 300
229 244 258
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
HCL : hydrogen chloride
M : chloroprene 36
Cl
H
53
Cl
88
90 62
39
30
b : 1,4-dichloro-1,3-butadiene
D' : 1-chloro-5-(1-chloroethenyl)-cyclohexene (dimer)
Cl 51
Cl
Cl
113 87
122
Cl 88 53 39
90
65
141
73
37
176
D : 1-chloro-4-(1-chlorovinyl)cyclohexene (dimer) 88
DC : C8H9Cl3 88
Cl Cl
147
51 53 39
90 105 65
141
139
90 176
127
T : unidentified
39
122
175
63
210
T : unidentified 239
239
254
41
91
67
141 112 131 155
225
183197
211
41 55
91
141
112
165
197
T : unidentified
T : unidentified 239
239
131 141
254 43
53
81 91
254
223
129 117 141 159
199 183
225
258
169
55
91
211 195
117
43
178
254
158
Tsuge, Ohtani and Watanabe
075 Hydrogenated natural rubber CH2CH(CH3)CH2CH2
C8
C12
n
C13
C4 C7
C9
LB
C10 C5
S
C14
C17
C16
T C9’
C6
C15
C18
C20 C19
C11
C21
C25 C24 C26 C23
C22
C31
C30 C36
TIC
0
10
Peak Notation LB C5 C6 C7 T C8 C 9’ C9 C10 C11 S C12 C13 C14 C15 C16 C17 C18
30 [min]
20
Assignment of Main Peaks propylene etc. 1-pentene methylbutane 4-methyl-1-hexene toluene 2-methyl-1-heptene 2,6-dimethyl-1-heptene 3-methyloctane 4-methyl-1-nonene 4-methylnonane 2,6-dimethyl-1,8-nonadiene 2,6-dimethyl-1-nonene 4-methyl benzenthiol 4,8-dimethyl-1-decene 2,6-dimethyl-1-undecene 2,6,10-trimethyl-1-undecene 3,7-dimethyldodecane 4,8-dimethyltridecane 4,8-dimethyl-1-tridecene 2,6,10-trimethyl-1,12-tridecadiene 2,6,10-trimethyl-1-tridecene 4,8,12-trimethyl-1-tetradecene 2,6,10-trimethyl-1-pentadecene
[ Related Reference ] 1) Tsuge, S.; Sugimura, Y.; Nagaya, T. J. Anal. Appl. Pyrolysis 1980, 1, 221.
Molecular Retention Weight Index 42 70 72 98 92 112 126 128 140 142 152 154 124 168 182 196 198 212 210 222 224 238 252
295 495 580 656 765 787 853 874 960 966 1040 1048 1082 1124 1239 1298 1321 1403 1407 1484 1489 1566 1677
Relative Intensity 88.1 76.1 10.6 81.2 42.2 100.0 30.7 38.7 21.9 7.2 10.5 14.7 10.0 52.8 54.2 23.8 21.8 47.6 7.1 22.0 12.7 33.0 28.8
159
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
075
EGA thermogram
Averaged mass spectrum 41 55 69
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
81
97
111
30 50
125 137
100
151
167
182
196
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C7 : 4-methyl-1-hexene
C4 : butane (+ butene) 43
41
57
+ 29 29 56
70
98
78
64
C8 : 2-methyl-1-heptene
C12 : 4,8-dimethyl-1-decene 43
56
57 71 85
41 29
29
69 84
97
97
112
111
139
C17 : 4,8,12-trimethyl-1-tetradecene
C13 : 2,6-dimethyl-1-undecene
57
56
43
41
125
71
69
29
85 97
83
111
29 126
97
182
154
C18 : 2,6,10-trimethyl-1-pentadecene
111 125
140 154
196
C26 : 2,6,10,14,18-pentamethyl-1-henicosene
57
55 69
43
43
69
97
83 83 97 111
29
126 140
123 137
252
182
C31 : 2,6,10,14,18,22-hexamethyl-1-pentacosene
151 165 179
C36 : 2,6,10,14,18,22,26-heptamethyl-1-nonacosene 57
57
43
111
29
69
69 43 83 97 111
83 97 111 125
137 179
208
29
123 137
179
209
160
Tsuge, Ohtani and Watanabe
076 Acrylonitrile-butadiene rubber; NBR CH2CH CHCH2 AB
M
CH2CH(CH CH2)
CH2CH(CN)
n
ABA1 ABA2 TQ AB’’
CB N7
ABA3 ABA5 ABA’
AB’ A N6
LB
D B
TIC
10
N6’
14
18
T
0
10
Peak Notation
Assignment of Main Peaks
LB M A B T D
propylene etc. butadiene acrylonitrile benzene toluene 4-vinylcyclohexene (B dimer)
N6
C6H9N (C-C=C-C-C-CN ?)
N 6’ N7 CB
C=C-C-C(CN)=C C7H11N cyanobenzene C7H9N (AB mixture of dimer; C=C-C=C-C-C-CN C=C-C-C-C-(CN)=C etc. ?) C8H11N C8H9N C9H11N (tetrahydroquinoline)
AB AB’ AB’’ TQ ABA1 ABA2 ABA3 ABA4 ABA5 ABA’
C10H12N2 (ABA mixture of trimer; C=C(CN)-C-C=C-C-C-C-CN etc.) C11H13N3 * bonding hydrogen is omitted
30 [min]
20
Molecular Retention Weight Index 42 54 53 78 92 108 95 95 93 109 103 107 107 121 119 133
160
187
Relative Intensity
295 395 568 654 767 838 863 880 925 977 991 1004 1023 1083 1125 1190 1301 1319 1340 1350 1376 1488
[ Related References ] 1) Shimono, T.; Tanaka, M.; Shono, T. Anal. Chim. Acta 1978, 96, 359. 2) Balyan, A. K.; Fedtke, M.; Hausler, K.-G. Plaste Kautschuk 1982, 29, 569. 3) Kondo, A.; Ohtani, H.; Kosugi, Y.; Kubo, Y.; Inaki, H.; Asada, N.; Yoshioka, A. Macromolecules 1988, 21, 2918. 4) Fuh, M.-R. S.; Wang, G.-Y. Anal. Chim. Acta 1998, 371, 89. 5) Hiltz, J. A. J. Anal. Appl. Pyrolysis 2000, 55, 135. 6) Shield, S. R.; Ghebremeskel, G. N.; Hendrix, C. Rubber Chem. Technol. 2001, 74, 803.
15.2 100.0 65.9 7.6 7.7 17.2 10.5 5.9 7.4 4.4 8.7 7.8 14.5 4.6 8.8 10.1 11.6 9.7 9.3 4.5 7.6 2.9
161
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
076
EGA thermogram
Averaged mass spectrum 41
79 67
91
53 100
133
108
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
118 147
161
30 50
100
150
184 193
214 225
240 251
200
266 279 300 [m/z]
250
( m/z range : 29 - 600 amu )
M : 1,3-butadiene
B : benzene 39
78
54
52
41
74
29
T : toluene
D : 4-vinylcyclohexene 91
54
79 39 39
66
79
93
65
55
108
29
N6 : (E )-hex-4-enenitrile
N6' : 2-methylenepent-4-enenitrile
55
66
N
41
39 29
67
79
93
108
79
29
AB : C7H9N (AB hybrid dimer)
108
122
ABA : C10H12N2 (ABA hybrid trimer) 67
54
41
41 107
80 67
54 79
92
29
120
ABA : C10H12N2 (ABA hybrid trimer) 67 41 54
93 79
133 104
30
93
54
119
146 160
29
93 105 119
133
146
160
162
Tsuge, Ohtani and Watanabe
077 Hydrogenated acrylonitrile-butadiene rubber CH2CH
CHCH2
CH2CH2CH2CH2
CH2CH(C2 H5 )
CH2 CH(CN)
n
N7
N11’’ N11 N7’ LB TIC
B A
C8
N7
C6
N10
N 8’
N6
N8
N9
0
N11’
X
DN
10
Peak Notation LB B A C6 C8 N6 N 7’ N7 N8’ N8 N9 N10 N11’’ N11’ N11 DN X
Assignment of Main Peaks low boiling point components 1-butene acrylonitrile 1-hexene 1-octene CH2=CH(CH2)3CN CH3(CH2)4CN CH3(CH2)3C(CN)=CH2 CH2=CH(CH2)4CN CH3(CH2)5CN CH3(CH2)4C(CN)=CH2 CH2=CH(CH2)5CN CH3(CH2)6CN CH2=CH(CH2)6CN CH3(CH2)7CN CH2=CH(CH2)7CN CH3(CH2)8CN CH3(CH2)3CH(CN)(CH2)3CH CH2 CH3(CH2)7C(CN)=CH2 CH2=CH(CH2)8CN CH3(CH2)9CN NC(CH2)7CN CH3(CH2)6C(CN)=CH2 unidentified
30 [min]
20
Molecular Retention Weight Index 56 53 84 112 95 97 109 109 111 123 123 125 137 139 151 153 165 165 165 167 150 151 -
[ Related Reference ] 1) Kondo, A.; Ohtani, H.; Kosugi, Y.; Kubo, Y.; Inaki, H.; Asada, N.; Yoshioka, A. Macromolecules 1988, 21, 2918.
384 565 597 791 864 881 892 976 982 992 1079 1085 1181 1188 1284 1290 1292 1296 1387 1392 1509 1514 1923
Relative Intensity 26.8 48.8 27.7 17.3 35.1 11.6 17.5 42.3 100.0 10.6 10.0 13.0 9.8 11.4 14.2 16.2 20.9 30.7 19.2 31.8 14.4 14.4 12.3 50.3
163
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
077
EGA thermogram
Averaged mass spectrum 41 55 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
67
94
82
108
122
136
30 50
100
150
164
180 190
203
150
220
234
248
200
250 [m/z]
( m/z range : 29 - 600 amu )
B : 1-butene
A : acrylonitrile 53
41
N
56
29
38
31
C8 : 1-octene
67
N7 : 6-heptenenitrile 43
41
55
N 70 29
55 80
83
68 94
29
112
N7 : heptanenitrile
108
94
N10 : decanenitrile
41
41
N
N 54
55
82
82
29
96 110
69
29
124
68 96
108
134 148 162
120
N11'' : 2-butylhep-6-tenenitrile
N11' : 2-methylenedecanenitrile 43
41 94 109
108 122
N 55 29
57
83
29 67
122
N
136 95
69 81
150 164
136 150 164
N11 : 1-undecenenitrile
N11 : undecanenitrile 41
55 41
N
122
N 55
136 69 29
82
94
29 108 150 164
94 69
82
109 122 134
148 162 176
164
Tsuge, Ohtani and Watanabe
078 Polynorbornene CHCH2 CHCH
n
CH2CH2
I
LB
CH
MI
C8
C5 C4
C6
TIC
T
C7
0
10
Peak Notation LB C4 C5
C6
T C7 C8 I MI
20
10
Assignment of Main Peaks propylene etc. butene 1,3-cyclopentadiene cyclopentene methylcyclopentane methylcyclopentadiene 3-methylcyclopentene benzene 1,3-cyclohexadiene toluene unidentified unidentified indene 1-methylindene
30 [min]
20
Molecular Retention Weight Index 42 56 66 68 84 80 82 78 80 92 84 108 116 130
295 382 626 580 642 642 606 654 626 765 763 809 1055 1163
Relative Intensity 100.0 20.9 14.2 7.3 2.2 9.9 6.0 3.1 10.7 3.7 9.8 17.3 8.0 7.9
165
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
078
EGA thermogram
Averaged mass spectrum 67 39
79 91
55
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
115
128 141
31 50
100
152 165 178 189 202 216 150
233
200
252 264 276 300 [m/z]
250
( m/z range : 29 - 600 amu )
C5 : 1,3-cyclopentadiene
C5 : cyclopentene 67
66
39
39 53 61
31
29
C6 : benzene
79
C6 : 1,3-cyclohexadiene 79
78
51
39
39
67
29
C7 : unidentified
82
39
84
53
41 29
29
91
69
I : indene
62
107
MI : 1-methylindene 116 55
39
65
C8 : unidentified 55
29
51
130 115
84
68
55 29 153
211
285
82 98
132 153
238
405
166
Tsuge, Ohtani and Watanabe
079 Styrene-butadiene rubber; SBR CH2CH
CHCH2
CH2CH(C6H5 )
n
SBB
S S T
SB
PB’
Y
PB
M
Z D LB TIC
C5 B
20
10
TO
0
10
Peak Notation
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
TO D S PB PB’ S
propylene etc. 1,3-butadiene pentadiene benzene cyclohexadiene toluene 4-vinylcyclohexene (B dimer) styrene propenylbenzene propylbenzene -methylstyrene
42 54 68 78 80 92 108 104 118 120 118
T
C12H18 (B trimer)
162
LB M C5 B
SB
C12H14 (mixture of dimer)
158
SBB
C16H12 (SBB mixture of trimer)
204
Y
unidentified
302 ?
Z
unidentified [ Related References ] 1) Alexeeva, K. V.; Khramova, L. P.; Solomatina, L. S. J. Chromatogr. 1973, 77, 61. 2) Trojer, L.; Ericsson, I. J. Chromatogr. Sci., 1978, 16, 345. 3) Schrafft, R. Kautsch. Gummi Kunstst. 1983, 36, 1983. 4) Choi, S.-S. J. Anal. Appl. Pyrolysis 2000, 55, 161. 5) Shield, S. R.; Ghebremeskel, G. N.; Hendrix, C. Rubber Chem. Technol. 2001, 74, 803. 6) Choi, S.-S. J. Anal. Appl. Pyrolysis 2002, 62, 319.
295 395 495 654 663 767 837 896 954 961 988 1164 1194 1354 1654 1671 2456 2470 2528 3083 3100
Relative Intensity 9.8 76.9 5.1 5.4 5.8 14.8 30.7 100.0 3.4 3.5 5.2 7.7 4.0 6.2 7.7 3.8 1.3 1.6 2.0 1.3 0.7
167
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
079
EGA thermogram
Averaged mass spectrum 91
100
79 41
55
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
104
67 129
50
143
100
157165 178 197 202 217
150
200
239 252
287285 302
250
300
350 [m/z]
( m/z range : 29 - 600 amu )
M : 1,3-butadiene
TO : toluene 39
91 54
39 29
D : 4-vinylcyclohexene
65
51
29
89
S : styrene 104
54
79 103
39
66
78
51
93 39
108
29
S : -methylstyrene
63
T : C12H18 (B trimer) 91
118 117
103 39
129 115
78
51
39
63
T : C12H18 (B trimer)
65
77
132
SB : C12H14 (SB hybrid dimer)
79
93
104
119 133
41 106
67 29
55
32
147
53
158 162
SBB : C16H12 (SBB hybrid trimer)
29 39
51
65
78
91
128
143
172
SBB : C16H12 (SBB hybrid trimer) 104
104
91
41 53 65 79
91
129 143 169
183
212
41 53 65
79
143
169
198
146
168
Tsuge, Ohtani and Watanabe
080 Styrene-butadiene-styrene block copolymer; SBS(TPS) CH2CH(C6H5)
p
CH2CH
CHCH2
q
CH2CH(C6H5)
r
SSS
S
S T2 T1 B
SS’ SS
20
10
V
TIC
EB
T
0
10
Peak Notation
Assignment of Main Peaks
B T V EB S S T1 T2 SS’ SS SSS
butadiene toluene 4-vinylcyclohexene (B dimer) ethylbenzene styrene -methylstyrene C12H18 (B trimer) C12H18 (B trimer) CH2(C6H5)CH2CH2C6H5 CH2=C(C6H5)CH2CH2C6H5 (S dimer) CH2=C(C6H5)CH2CH(C6H5)CH2CH2C6H5 (S trimer)
30 [min]
20
Molecular Retention Weight Index 54 92 108 106 104 118 162 162 196 208 312
[ Related Reference ] 1) Hacaloglu, J.; Ersen, T.; Ertugrul, N.; Fares, M. M.; Suzer, S. Eur. Polym. J. 1997, 33, 199.
395 767 837 867 897 989 1170 1194 1678 1738 2490
Relative Intensity 25.4 7.2 13.6 1.6 100.0 4.6 1.0 1.4 2.4 2.2 11.8
169
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
080
EGA thermogram
Averaged mass spectrum 104 91
78
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
39
118
63
133 147 161 50
100
187194 207216
150
312
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
B : 1,3-butadiene
T : toluene 39
91
54
39 29
V : 4-vinylcyclohexene
65
51
29
89
S : styrene 104
54
79 103 39
78
66 51
93 108
29
39
S : -methylstyrene
63
T1 : C12H18 (B trimer) 118
79
117
103
91
105 119 133
41 53
78
67
51
39
147 63
162
T2 : C12H18 (B trimer)
SS' : propane-1,2-diyldibenzene
79
92 93
41
106
119
133 105
67
196
53
147
29
162
SS : but-3-ene-1,3-diyldibenzene (styrene dimer)
29
39
51
145
165
187
91
104 65 77
118
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
91
39 51
65 77
117 130 152 165
193
208 39
65 77
118143
194 207 221
312
170
Tsuge, Ohtani and Watanabe
081 Styrene-ethylene-butadiene-styrene block copolymer; hydrogenated SBS (SEBS) CH2CH(C6H5)
CH2CH2
p
CH2CH
q
CHCH2
r
CH2CH(C6H5)
s
SSS
S
S C10
SS
C11 C12 C13 C14
E
C4 TIC
C15 C16
20
10
T C8
LB
0
10
Peak Notation LB C4 T C8 E S S C10 C11 C12 C13 C14 C15 C16 SS SSS
Assignment of Main Peaks propylene etc. butadiene etc. toluene 1-octene ethylbenzene styrene -methylstyrene 1-decene 1-undecene n-undecane 1,11-dodecadiene 1-dodecene 1-tridecene 1-tetradecene 1,14-pentadecadiene 1-pentadecene n-pentadecane 1,15-hexadecadiene 1-hexadecene CH2=C(C6H5)CH2CH2C6H5 (S dimer) CH2=C(C6H5)CH2CH(C6H5)CH2CH2C6H5 (S trimer)
30 [min]
20
Molecular Retention Weight Index 42 54 92 112 106 104 118 140 154 156 166 168 182 196 208 210 212 222 224 208 312
295 395 767 791 867 896 988 994 1094 1100 1189 1195 1294 1394 1494 1496 1500 1591 1594 1737 2491
[ Related References ] 1) Lamb, G. D.; Lehrle, R. S. J. Anal. Appl. Pyrolysis 1989, 15, 261. 2) Dean, L.; Groves, S.; Hancox, R.; Lamb, G.; Lehrle, R. S. Polym. Degrad. Stab. 1989, 25, 1
Relative Intensity 3.7 6.2 5.2 4.1 1.4 100.0 3.0 1.4 1.1 1.3 1.2 1.4 0.7 0.7 0.3 0.8 0.6 0.8 0.8 2.7 9.7
171
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
081
EGA thermogram
Averaged mass spectrum 104
78 100
91
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51 39
118
63
165 178 194 207
143 50
100
150
200
312 250
300
350 [m/z]
( m/z range : 29 - 600 amu )
T : toluene
C8 : 1-octene 91
55
41
70
29 83 39
65
51
32
89
112
97
S : styrene
S : -methylstyrene 104
118 117
103
103 78
78
51 39
51
39
63
63
C12 : 1-dodecene
C10 : 1-decene
43
56
41
55
70 70 29 83
83 97
29 97 111118
111
140
SS : but-3-ene-1,3-diyldibenzene (styrene dimer)
125
168
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
91
91
117 104 39 51
65
77
130 165 179 193
208 51 6577
118 143
194 207 221
312
172
Tsuge, Ohtani and Watanabe
2.2.10 Polyamides 082 Polycaproamide; Nylon-6 NH(CH2)5CO
n
M
NA5 LB TIC
N6
N5
AN
0
NA4 NA3 NA1
NAA3 NAA1
10
Peak Notation LB N5 N6 AN M NA1 NA3 NA4 NA5 NAA1 NAA3 NAA5
Assignment of Main Peaks propylene etc. CH2=CH(CH2)2CN CH2=CH(CH2)3CN CH3(CH2)4CN NC(CH2)5NH2 (CH2)5CONH CH3CONH(CH2)5CN CH3(CH2)2CONH(CH2)5CN CH2=CH(CH2)2CONH(CH2)5CN CH2=CH(CH2)3CONH(CH2)5CN CH3(CH2)4CONH(CH2)5CN CH3CONH(CH2)5CONH(CH2)5CN CH3(CH2)2CONH(CH2)5CONH(CH2)5CN CH3(CH2)4CONH(CH2)5CONH(CH2)5CN
NAA5
30 [min]
20
Molecular Retention Weight Index 42 81 95 97 112 113 154 182 194 208 210 267 295 323
[ Related References ] 1) Ohtani, H.; Nagaya, T.; Sugimura, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis 1982, 4, 117. 2) Levchik, S. V.; Weil, E. D.; Lewin, M. Polym. Int. 1999, 48, 532.
295 737 838 855 1110 1265 1530 1689 1780 1883 1892 2603 2758 2958
Relative Intensity 2.6 0.4 1.5 1.1 1.4 100.0 2.0 2.1 3.9 5.4 2.6 6.4 4.8 7.1
173
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
082
EGA thermogram
Averaged mass spectrum 55 113
30
41 100
200
300
400
500
600
85
700 ºC
programming rate: 20ºC/min
68 96 50
124
139
100
151
164
179
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
N6 : 1-pentenenitrile
N6 : pentanenitrile
55
N
41
N 54
41 68
82
29 29
96
67
80
95
110
143
143
M : ε -caprolactam
AN : 6-aminohexanenitrile N
30
O
113
55
NH 2
NH 85
30
41
42
67
54
67
84
94
111
98
124
NA3 : N-(5-cyanopentyl)butyramide
NA5 : N-(5-cyanopentyl)hex-5-enamide O
114
O
71
41
43
N H
30
55
N
N H
69
114 128
55
100
30
154
83
168
87 142 167
126 140
188
NA5 : N-(5-cyanopentyl)hexanamide 154
O
114 N H
43
179 193 208
NAA1 : 6-acetamido-N-(5-cyanopentyl)hexanamide
O
114
N
154
100
N
H N N H
N
O
99 55 30
71
167 83 128 139
167 181
30 43 55 72 86 96
190 210 229
114
128 140
273
NAA3 : 6-butyramido-N-(5-cyanopentyl)hexanamide H N
N H
267
NAA5 : N-(5-cyanopentyl)-6-hexanamide O
114
O
224 181195 213 238
154
N H
N
H N
N O
O
43 30 55 71 96 86
167 142 154
128
224 41 55 69 30
181 206
295
419
96 86
168 154 126 140
224 195 181 209
292
321
174
Tsuge, Ohtani and Watanabe
083 Polyundecanoamide; Nylon-11 (CH2)10 CONH
N11
C6 LB
C10 C7
C9 C8
TIC
N7
N10 N9
NA10 NA5 HA19 HA20 NA6 HA18 HA17 NA7 HA16 NA8 NA1 NA9
HA15 HA14 HA13 N11’ M
10
LB C6 C7 C8 C9 C10 N9 N10 N11 N11’ M NA1 HA17
HA18
NA5 HA20 NA8 NA9 NA10 D
D
N8
0
Peak Notation
n
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
42 propylene etc. 84 1-hexene 98 1-heptene 112 1-octene 124 1,8-nonadiene 126 1-nonene 140 1-decene 137 CH2=CH(CH2)6CN 139 CH3(CH2)7CN 151 CH2=CH(CH2)7CN 165 CH2=CH(CH2)8CN 167 CH3(CH2)9CN 165 C11H19N 183 (CH2)10CONH 224 CH3CONH(CH2)10CN 279 CH2=CH(CH2)m -2CONH(CH2)n-2CH=CH2 281 CH2=CH(CH2)m-2CONH(CH2)n-1CH3 (m+n=17, m<10, n<9) 283 CH3(CH2)m-1CONH(CH2)n-1CH3 293 CH2=CH(CH2)m-2CONH(CH2)n-2CH=CH2 295 CH2=CH(CH2)m-2CONH(CH2)n-1CH3 297 CH3(CH2)m-1CONH(CH2)n-1CH3 (m+n=18, m<10, n<10) 278 CH2=CH(CH2)3CONH(CH2)10CN 280 CH3(CH2)4CONH(CH2)10CN 321 CH2=CH(CH2)8CONH(CH2)8CH=CH2 CH2=CH(CH2)8CONH(CH2)9CH3 + CH3(CH2)9CONH(CH2)9CH3 323, 325 CH2=CH(CH2)6CONH(CH2)10CN + CH3(CH2)7CONH(CH2)11CN 320, 322 334 CH2=CH(CH2)7CONH(CH2)10CN 348 CH2=CH(CH2)7CONH(CH2)11CN 366 (CH2)10CONH(CH2)10CONH
[ Related References ] 1) Ohtani, H.; Nagaya, T.; Sugimura, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117. 2) Levchik, S. V.; Weil, E. D.; Lewin, M. Polym. Int. 1999, 48, 532.
295 595 691 790 882 891 992 1175 1181 1279 1383 1388 1512 1710 2098 2226 2231 2242 2327 2333 2339 2453 2462 2531 2537 2774 2875 2981 3384
Relative Intensity 27.5 28.3 18.4 9.3 6.0 10.9 13.2 3.8 7.7 13.4 35.4 20.3 12.2 15.2 12.5 7.2 11.5 1.9 9.7 13.2 1.2 5.7 10.5 7.4 12.3 25.2 32.3 82.9 100.0
175
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
083
EGA thermogram
Averaged mass spectrum 30 41 55 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
69
86 98
50
114 122
142
100
156
170 182 193
150
200
250 [m/z]
( m/z range : 29 - 600 amu )
N11 : 10-undecenenitrile
C6 : 1-hexene 41
56
55 41
N
122 136 94
69
84
69
82
108
29
29
150 164
NA1 : N-(10-cyanodecyl)acetamide
M : azacyclododecan-2-one 83
O
41 55
O
30
H N
72
12
96
69
97 86
55
30 110 138
114 142 128
183 277
238
357
55
N H
237 240 224
73
252 321
NA9 : N-(10-cyanodecyl) -9-decenamide 97
O
184
83
110 141 128 171
N
+
O
O
196
340
H N
97
184
73 86100 114 140 128 156168
274
N-(10- cyanodecyl) -8-nonenamide (+ N-(11- cyanoundecyl)nonanamide)
NA8 :
H N
41
184 166
476
HA17 : N-(non-8-enyl) -8-nonenamide
30
N N H
43
N
198 224
282 265
322
362
NA10 : N-(11-cyanoundecyl)-9-decenamide H N
97
O
N
N N H
55 83 41
55
237
184
110 142 166
30
294 334
266
521
D : 1,13-diazacyclotetracosane-2,14-dione O
184
55
41 30
184 237
41
69 30
O
83
HN
69 100 86
140 156 168
196
366
NH
238
294 323 280 309 337
O
351
429
69 110
224 209
308 356
176
Tsuge, Ohtani and Watanabe
084 Polylauroamide; Nylon-12 (C H 2 ) 1 1 C O N H
n
N12
N12’ C10
TIC
LB C6 C7
C8
N7 C9 N6
N11
C11 N8 N9 N10
0
HA20 HA19 HA18 HA17 NA1 HA16 HA15 HA14 M
LB C6 C7 C8 C9
C10 C11 N10 N11 N12 N12’ M’ M NA1 HA19
HA20
NA5 HA22 NA9 NA10 NA11 D
NA7 NA11 NA8 NA9 NA10
M’
10
Peak Notation
NA5 HA21 HA22
D 30 [min]
20
Assignment of Main Peaks propylene etc. 1-hexene 1-heptene 1-octene 1,8-nonadiene 1-nonene n-nonane 1,9-decadiene 1-decene 1-undecene CH2=CH(CH2)7CN CH3(CH2)8CN CH2=CH(CH2)8CN CH2=CH(CH2)9CN CH3(CH2)10CN C12H21N unidentified (CH2)11CONH CH3CONH(CH2)11CN CH2=CH(CH2)m -2CONH(CH2)n-2CH=CH2 CH2=CH(CH2)m-2CONH(CH2)n-1CH3 (m+n=19, m<11, n<10) CH3(CH2)m-1CONH(CH2)n-1CH3 CH2=CH(CH2)m-2CONH(CH2)n-2CH=CH2 CH2=CH(CH2)m-2CONH(CH2)n-1CH3 CH3(CH2)m-1CONH(CH2)n-1CH3 (m+n=20, m<11, n<11) CH2=CH(CH2)3CONH(CH2)11CN CH3(CH2)4CONH(CH2)11CN CH2=CH(CH2)9CONH(CH2)9CH=CH2 + CH2=CH(CH2)9CONH(CH2)10CH3+CH3(CH2)10CONH(CH2)10CH3 CH2=CH(CH2)7CONH(CH2)11CN +CH3(CH2)8CONH(CH2)11CN CH2=CH(CH2)8CONH(CH2)11CN +CH3(CH2)9CONH(CH2)11CN CH2=CH(CH2)9CONH(CH2)11CN +CH3(CH2)10CONH(CH2)11CN (CH2)11CONH(CH2)11CONH
Molecular Retention Weight Index 42 84 98 112 124 126 128 138 140 154 151 153 165 179 181 179 196 197 238 307 309 311 321 323 325 292 294 349 351, 353 348, 350 362, 364 376, 378 394
[Related References ] 1) Ohtani, H.; Nagaya, T.; Sugimura, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117. 2) Levchik, S. V.; Weil, E. D.; Lewin, M. Polym. Int. 1999, 48, 532.
295 593 692 792 886 894 900 986 994 1094 1284 1290 1387 1490 1496 1615 1764 1825 2210 2438 2443 2471 2540 2545 2549 2565 2574
Relative Intensity 59.4 44.5 17.5 15.6 4.4 16.0 2.5 9.1 26.9 12.2 8.8 10.9 26.9 77.5 29.9 27.5 15.0 23.3 25.8 9.0 17.0 9.0 13.6 3.3 8.7 11.8
2747
18.6
2991 3095 3200 3590
31.8 33.8 100.0 17.7
177
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
084
EGA thermogram
Averaged mass spectrum 41 30
55 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
86
69
96 50
112 122
136
100
156 166
197 207
180
150
224
200
250 [m/z]
( m/z range : 29 - 600 amu )
N11 : 10-undecenenitrile
C10 : 1-decene 56
41
55 N
41 122 70
136
29
83
94
69
97
82
29
111
108 150 164
140
N12 : dodecanenitrile
N12 : 11-dodecenenitrile N
55
N
41
41 122 136
97
55
110 82
69 82
29
94
108
150
124
69
29
138 152
164 178
166 180
NA1 : N-(11-cyanoundecyl)acetamide
M : Azacyclotridecan-2-one 30 41
55
73
86
NH 112 126
140
43
168
156
O N H
N
+
55
N H 110
N
198 251 212 185 238
128 142 156 198 170 181
(+ N-(11-cyanoundecyl)undecanamide) 97
O
73
114
NA10 : N-(11-cyanoundecyl)undec-10-enamide
N H
55
86
55
O
83
97
182
(+ N-(11-cyanoundecyl)decanamide ) 97
N
72
197
154
NA9 : N-(11-cyanoundecyl)dec-9-enamide
30
N H
O
100
43
O
30
13
O
83
41 30 69
110 128 156
310 321
198 180
N
+
N H 251 238
N 362
NA11 : N-(11-cyanoundecyl)dodec-11-enamide
( + N-(11-cyanoundecyl)dodecanamide ) 97
55 N H
O
N
+
30 41
N H
83
55 41 30
D : 1,14-diazacyclohexacosane-2,15-dione
O
198
N 69
69
110
198
251
336
376
83
100 114
156
210 184
O HN
252
26 280 309
NH O
351 365
394
178
Tsuge, Ohtani and Watanabe
085 Poly(tetramethylene adipamide); Nylon-4,6 NH(CH2 )4NHCO(CH2 )4 CO
n
CP c
b e Pr B TIC LB
BA
0
BD
d
a CC
10
Peak Notation
Assignment of Main Peaks
LB B BA Pr CP BD CC a b c d e
CO2 1,3-butadiene 1-butanamine pyrrolidine cyclopentanone 1,4-butanediamine 2-cyanocyclopentanone unidentified CH2=CH(CH2)2NHCO(CH2)4CN unidentified (CH2)4NHCO(CH2)4CONH unidentified
30 [min]
20
Molecular Retention Weight Index 44 54 73 71 84 88 109 133 180 180 198 263
150 395 637 686 790 882 1150 1366 1612 2006 2059 2499
Relative Intensity 3.1 3.7 13.3 33.6 100.0 31.6 5.4 35.5 19.7 39.3 9.9 24.5
179
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
085
EGA thermogram
Averaged mass spectrum 30
100
55
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
44 70
84
96
110
136
124 50
100
158 173180 150
198 202 216 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
BA : 1-butanamine
Pr : pyrrolidine H N
43
30
NH2
70 41
30
73
56
54
79
BD : 1,4-butanediamine
CP : cyclopentanone 55
O
30
NH2
H2N 84
41 29
43 59
67
CC : 2-cyanocyclopentanone
71
87
a : unidentified O
54
30
N
39
109
114
41
80 66
30
56
120
93
b : N-(but-3-enyl)-5-cyanopentanamide
69
86
99
151
c : unidentified
O
55 N H
41
180 125
123
30
N
72
96 67
29
82
110
137
152 41 53
80 95 109
180 165
156 98 114
141
82
170
185
96
30
N H
128
84
224
55
H N 70
196
110
O
55
41
163
e : unidentified
d : 1,6-diazacyclododecane-7,12-dion
30
137 151
41 O 225
70 124 136 154
181
196
263
286
180
Tsuge, Ohtani and Watanabe
086 Poly(hexamethylene adipamide); Nylon-6,6 NH(CH 2 )6 NHCO(CH2 ) 4 CO
n
CP
DA
AA4 AA3 NA6
A6 TIC LB
CA
A5
0
AA2 AA1
DN
M HD
L6 10
Peak Notation LB A5 CP A6 CA DA DN L6 AA1 AA2 AA3 AA4 NA6 M HD
Assignment of Main Peaks CO2 etc. CH2=CH(CH2)3NH2 (CH2)4CO CH2=CH(CH2)4NH2 CH3(CH2)5NH2 NC(CH2)4NH2 ? H2N(CH2)6NH2 NC(CH2)4CN (CH2)5CONH CH3CONH(CH2)6NH2 CH2=CHCONH(CH2)6NH2 CH2=CHCH2CONH(CH2)6NH2 CH2=CH(CH2)2CONH(CH2)6NH2 CH2=CH(CH2)4NHCO(CH2)4CN CH3(CH2)5NHCO(CH2)4CN (CH2)6NHCO(CH2)4CONH CH2=CH(CH2)4NHCO(CH2)4CONH(CH2)5CH3 ?
30 [min]
20
Molecular Retention Weight Index 44 85 84 99 101 98 ? 116 108 113 158 170 184 198 208 210 226 310 ?
150 729 788 832 841 907 1087 1183 1257 1532 1608 1704 1799 1905 1912 2295 2733
[ Related References ] 1) Ohtani, H. ; Nagaya, T. ; Sugimura, Y. ; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117. 2) Mac Kerron, D. H. ; Gordon, R. P. Polym. Degrad. Stab. 1985, 12, 277. 3) Ballistreri, A.; Garozzo, D.; Giuffrida, M.; Montaudo, G. Macromolecules 1987, 20, 2991. 4) Levchik, S. V.; Weil, E. D.; Lewin, M. Polym. Int. 1999, 48, 532. 5) Schaffer, M. A.; Marchildon, E. K.; McAuley, K. B.; Cunningham, M. F. J. Macromol. Sci., Rev. Macromol. Chem. Phys. 2000, C40, 233.
Relative Intensity 27.3 7.4 100.0 20.0 10.2 7.0 21.1 2.5 4.0 9.2 3.3 3.2 6.8 12.3 4.3 31.5 18.0
181
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
086
EGA thermogram
Averaged mass spectrum 30
44
55
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
84 96
68 50
110
124
152
138
100
166
176 200 [m/z]
150
( m/z range : 29 - 600 amu )
A6 : hex-5-en-1-amine
CP : cyclopentanone O
55
30
NH2 39 84 39 56
29
67
67
A6 : hexan-1-amine
82
DA : hexane-1,6-diamine 30
30
41
42
56
56 87
70
O
41
H N
30
NH2
N H
43
100
AA4 : N-(6-aminohexyl)pent-4-enamide
AA1 : N-(6-aminohexyl)acetamide 30
NH2
H2 N
NH2
NH 2
55
O 82
73
56
86 100
82
O
41 30
N H
55
N H
55
N
N
82 110
110 100
67
55
O
41
NH O 168 181
198
181
226
30
152 O
82 96 110
55
112 128 141 154
167
H N
N H
HN
41
86 98
128 140
HD : N1-(hex-5-enyl)-N6-hexyladipamide
O
30
100
73
167
127 139
M : 1,8-diazacyclotetradecane-2,7-dione
69
152
NA6 : 5-cyano-N-hexylpentanamide
O
41
139
129
114
NA6 : 5-cyano-N-(hex-5-enyl)pentanamide
30
100 110
73
67 124138
166
209
251
291
182
Tsuge, Ohtani and Watanabe
087 Poly(hexamethylene sebacamide); Nylon-6,10 NH(CH 2 )6 NHCO(CH 2 )8 CO
n
M HA14 NA1 HA13 HA12 A DN
N8
NA5 NA4 HD
L6
LB TIC
NA6
N7
C6
N9
N6
C7
0
10
Peak Notation LB C6 C7 N6 N7 N8 N9 L6 DN A HA12
HA13 NA1 HA14
NA4 NA5 NA6 M HD
Assignment of Main Peaks
1-butene 1-hexen 1-heptene CH2=CH(CH2)3CN CH3(CH2)4CN CH2=CH(CH2)4CN CH3(CH2)5CN CH2=CH(CH2)5CN CH2=CH(CH2)6CN CH3(CH2)7CN (CH2)5CONH NC(CH2)8CN NC(CH2)8COOH CH2=CH(CH2)m-2CONH(CH2)n-2CH=CH2 (m+n=12, m<8, n<6) CH2=CH(CH2)m-2CONH(CH2)n-1CH3 (m+n=12, m<8, n<6) + CH2(CH2)n-2CONH(CH2)m-1CH3 CH2=CH(CH2)m-2CONH(CH2)n-2CH=CH2 (m+n=13,m<8, n<7) CH2=CH(CH2)m-2CONH(CH2)n-1CH3 (m+n=13, m<8, n<7) + CH2=CH(CH2)n-2CONH(CH2)m-1CH3 CH3NHCO(CH2)8CN CH2=CH(CH2)6CONH(CH2)4CH=CH2 CH2=CH(CH2)6CONH(CH2)5CH3 + CH2=CH(CH2)4NHCO(CH2)7CH3 CH3(CH2)3NHCO(CH2)8CN CH2=CH(CH2)3NHCO(CH2)8CN CH2=CH(CH2)4NHCO(CH2)8CN CH3(CH2)5NHCO(CH2)8CN (CH2)6NHCO(CH2)8CONH CH2=CH(CH2)4NHCO(CH2)8CONH(CH2)5CH3 ?
30 [min]
20
Molecular Retention Weight Index 56 84 98 95 97 109 111 123 137 139 113 164 183 209 211 211 223 225 225 196 237 239 239 238 250 264 266 282 366 ?
[ Related References ] 1) Ohtani, H. ; Nagaya, T. ; Sugimura, Y. ; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117. 2) Levchik, S. V.; Weil, E. D.; Lewin, M. Polym. Int. 1999, 48, 532.
Relative Intensity
385 595 694 863 880 975 982 1079 1079 1187 1263 1617 1670 1717
31.1 31.0 7.7 6.7 4.1 8.8 10.4 37.4 8.4 5.0 14.9 33.5 48.6 10.9
1726
17.2
1820
15.3
1828
15.5
1909 1923
18.6 6.5
1931
9.0
2152 2246 2353 2359 2776 3097
18.6 21.3 68.3 13.4 100.0 47.4
183
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
087
EGA thermogram
Averaged mass spectrum 55
41 30
100
200
300
400
500
82
67
600
700 ºC
programming rate: 20ºC/min
96 114 50
124
142
100
156 165
184
198 207
150
223
200
250 [m/z]
( m/z range : 29 - 600 amu )
DN : decanedinitrile
N8 : 7-octenenitrile 55
82
N
41
N
41
N 55
94
96 29
82
67
73
58
137 30
154 166
NA4 : N-butyl-9-cyanononanamide
30
N
55
30
O 166
N 30
166
55 N H 41
N
73 138 126 154 113
86
223 183196 210
156 100
114
128 143
O
30
O
55
100
86
86
41
NH
72 282 253267
H N
N H
128
69
237
HD : N5-(hex-5-enyl)-N10-hexyldecanediamide H N
128 O 140 156 114 210 168 184196 225 239
223 182 196 209
264
235
97
41
195 208
NA6 : 9-cyano-N-hexylnonanamide
M : 1,8-diazacyclooctadecane-9,18-dione 55
85
138 156 112 127
98 73 82
N 166
198 209 223
O N H
156166
99
128 138 156
NA6 : 9-cyano-N-(hex-5-enyl)nonanamide 55
114 128 138
O 73
100
100
H N
73
86
30
86
41
N H 166
41
41
NA5 : 9-cyano-N-(pent-4-enyl)nonanamide
O
115
55
N O
97 108
41
H N
124
84
30
163
OH
N
29
135
NA1 : 9-cyano-N-methylnonanamide O
55
69
124 110
A : 9-cyanononanoic acid 41
69
29
122 108
O
140 114
166 157
196 210
251 241
323
184
Tsuge, Ohtani and Watanabe
088 Poly(dodecamethylene adipamide); Nylon-12,6 NH(CH 2 )12 NHCO(CH 2 ) 4 CO
n
CP M DA
LB
C11
C6
A12 NA10
A11 A10
C9 C10
C7
TIC
A7 A8 A9
0
10
Peak Notation LB C6 C7 CP C9 C10 C11 A9 C12 A10 A11 A12 DA NA10 NA11 NA12 M
NA12 NA11
C12
Assignment of Main Peaks propylene etc. CH2=CH(CH2)3CH3 CH2=CH(CH2)4CH3 (CH2)4CO CH2=CH(CH2)6CH3 CH2=CH(CH2)7CH3 CH2=CH(CH2)7CH=CH2 CH2=CH(CH2)8CH3 CH2=CH(CH2)7NH2 CH3(CH2)8NH2 CH2=CH(CH2)9CH3 CH2=CH(CH2)8NH2 CH3(CH2)9NH2 CH2=CH(CH2)9NH2 CH3(CH2)10NH2 CH2=CH(CH2)10NH2 CH3(CH2)11NH2 H2N(CH2)12NH2 CH3(CH2)9NHCO(CH2)4CN CH2=CH(CH2)10NHCO(CH2)4NH2 CH2=CH(CH2)9NHCO(CH2)4CN + CH3(CH2)11NHCO(CH2)4CN (CH2)12NHCO(CH2)4CONH
30 [min]
20
Molecular Retention Weight Index 42 84 98 84 126 140 152 154 141 143 168 155 157 169 171 183 185 200 266 282 278 294 310
[ Related References ] 1) Ohtani, H.; Nagaya, T.; Sugimura, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117. 2) Tsuge, S.; Ohtani, H.; Matsubara, H.; Ohsawa, M. J. Anal. Appl. Pyrolysis 1987, 11, 181.
Relative Intensity
295 596 690 790 891 991 1093 1093 1151 1158 1193 1241 1250 1343 1352 1446 1454 1717 2335 2438
10.2 15.1 6.3 95.8 18.8 7.2 2.9 6.3 4.8 3.4 3.1 3.9 10.2 14.7 6.2 24.5 20.8 54.7 12.0 17.0
2548
42.1
2982
100.0
185
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
088
EGA thermogram
Averaged mass spectrum 30
100
200
300
400
500
55
600
700 ºC
programming rate: 20ºC/min
44 84
97
69
152 128 142
110
50
100
171 184
150
194 208 222 236 250 200
266
250
300 [m/z]
( m/z range : 29 - 600 amu )
CP : cyclopentanone
C6 : 1-hexene 56
55
O
41
84 41
69
29
84 29
C10 : 1-decene
67
A10 : 1-decanamine 30
41
NH2 55 70 29 83
97
41
111
140
A11 : undec-10-en-1-amine
55
69
86
100 114
132
157
A12 : dodec-11-en-1-amine
30
30
NH2
41
55
NH2
41 67
86 95
114 128 140 154
55
169
67
86
100 112
128 142 154 168
183
DA : 1,12-dodecanediamine
A12 : 1-dodecanamine
30
30
NH2
41
55
44 86
69
100 114 128 142 156
184
NA12 : 5-cyano-N-(undec-10-enyl)pentanamide H N
55
+
82 41 73
100
127
86 100 114 128 142 156 171 184 201
O N H
O O
30 41 N
139 153 167181195 212
69
55
N
N H
110
56
M : 1,8-diazacycloicosane-2,7-dione
(+ 5-cyano-N-dodecylpentanamide ) 30
NH2
H2N
294
20 HN
112 84100 69 128
O
156 182 212 238 265
310 364
186
Tsuge, Ohtani and Watanabe
089 Caproamide-hexamethylene adipamide copolymer; Nylon-6/66 NH(CH2)5CO
NH(CH2)6NHCO(CH 2)4CO
n
L6
CP
CA N6 LB A5
TIC
A6
NA5 AN
0
10
Peak Notation LB A5 CP A6 N6 CA AN L6 NA5
Assignment of Main Peaks propylene etc. CH2=CH(CH2)3NH2 (CH2)4CO CH2=CH(CH2)4NH2 CH3(CH2)5NH2 CH2=CH(CH2)3CN CH3(CH2)4CN NC(CH2)4NH2 ? NC(CH2)5NH2 (CH2)5CONH CH2=CH(CH2)3NHCO(CH2)4CN ?
30 [min]
20
Molecular Retention Weight Index 42 85 84 99 101 95 97 98 ? 112 113 194 ?
[ Related References ] 1) Senoo, H.; Tsuge, S.; Takeuchi, T. J. Chromatogr. Sci., 1971, 9, 315. 2) Ohtani, H.; Nagaya, T.; Sugimura, Y.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1982, 4, 117.
295 732 788 839 850 861 878 912 1159 1268 1821
Relative Intensity 5.3 1.6 28.0 2.1 0.8 1.3 1.3 2.9 0.8 100.0 11.8
187
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
089
EGA thermogram
Averaged mass spectrum 55
30 41
100
200
300
400
500
84
600
700 ºC
programming rate: 20ºC/min
113 68
96 122
50
136
100
150
179
164
200 [m/z]
150
( m/z range : 29 - 600 amu )
CP : cyclopentanone
A5 : pent-4-enylamine 30
55
O
NH2
84 41 39
56 68
29
A6 : hex-5-en-1-amine
63
A6 : hexan-1-amine
30
30
NH2
NH2
56 39
39 70 56
82
N6 : hexanenitrile
N6 : hex-5-enenitrile 55
54
41
N
N
41 68 82 29 67
29
93
80
L6 : ε -caprolactam
AN : 6-aminohexanenitrile 43
30
N
O
55
113
NH2 30 72
60
NH
41
85
85 67 98
NA5 : 5-cyano-N-(pent-4-enyl)pentanamide H N O 95 108 41 29
55
179
N
67
80
123
136 150 164
188
Tsuge, Ohtani and Watanabe
090 Poly(m-xylene adipamide); Nylon-MXD6 NHCH2
CH2NHCO(CH2)4CO
n
G
X
CP LB TIC
H
TA TN AL MS CB
0
J
NO DN A
C B
F D
E
10
Peak Notation
Assignment of Main Peaks
LB CP X CB MS AL TN TA NO DN A B C D E F G H I J
CO2 (CH2)4CO m-xylene cyanobenzene m-methylstyrene m-tolualdehyde ? m-tolunitrile CH3C6H4CH2NH2 C6H7NO adiponitrile C10H11N ? C10H9N ? unidentified unidentified unidentified unidentified CH3C6H4CH2NHCO(CH2)4CN unidentified unidentified CH3C6H4CH2NHCO(CH2)4CONHCH2C6H4CH3
* C6H4 represents m-phenylene group
I
30 [min]
20
Molecular Retention Weight Index 44 84 106 103 118 120 ? 117 121 109 108 145 ? 143 ? 126 210 212 231 230 352
150 786 871 988 998 1074 1098 1122 1131 1187 1340 1407 1434 1718 1933 2000 2208 2517 3021 3314
Relative Intensity 42.5 59.6 100.0 1.4 4.2 1.3 15.5 7.5 9.4 8.1 10.7 4.6 30.2 23.3 19.2 23.6 124.1 108.3 30.0 80.8
189
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
090
EGA thermogram
Averaged mass spectrum 91 55
39
106 100
77
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
120
65
132
30
147 170 50
100
187188
208
150
223 250 [m/z]
200
( m/z range : 29 - 600 amu )
X : m-xylene
CP : cyclopentanone 55
O
91
84
106
41 29
51
39
66
C : unidentified
77
65
D : unidentified 59
105
44 210 82 29
72
98
110
77
39 51 65
E : unidentified
103
118
139 152 165 178189
F : unidentified 105
119 231
55 77
39 51 65
212 103
29
128 144 158170 185
G : 5-cyano-N-(3-methylbenzyl)pentanamide
77
41
98105 132 146 160
65
188
229
H : unidentified
O
105 120
203
174
120
N H
N 230
105 77 91
55
162
65
29 41
132 148
176 190
44 55 65 77 91 29
215
132 146 160 174 190 203 220 231 248
J : N1,N6-bis(3-methylbenzyl)adipamide
I : unidentified
120
105
O N H
105
120 334
163
30
77 91 5565
H N O
158
176191
212
355
30
657791
132
229
324
352
190
Tsuge, Ohtani and Watanabe
2.2.11 Polyacetals and polyethers 091 Polyoxymethylene; POM CH 2O
n
M
MO TIC
a
0
10
Peak Notation
Assignment of Main Peaks
M MO a
formaldehyde methanol unidentified
30 [min]
20
Molecular Retention Weight Index 30 32 -
245 320 615
[ Related References ] 1) Grassie, N.; Roche, R. S. Makromol. Chem. 1968, 112, 16. 2) Ishida, Y.; Ohtani, H.; Abe, K.; Tsuge, S.; Yamamoto, K.; Katoh, K. Macromolecules 1995, 28, 6528.
Relative Intensity 100.0 7.7 5.6
191
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
091
EGA thermogram
Averaged mass spectrum 29
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
50
100
[m/z]
( m/z range : 29 - 600 amu )
MO : methanol
M : formaldehyde 29
H
H
H
31
H
O H
O 44
a : unidentified 45
31 61 75
89
44
56
H
192
Tsuge, Ohtani and Watanabe
092 Polyoxymethylene(copolymer) CH2CH2O
CH2O
n
M MO
TIC
DO PG
EA
A
0
10
Peak Notation
Assignment of Main Peaks
M MO DO PG EA A
formaldehyde + ethylene oxide methanol O O 1,3-dioxolane propylene glycol CH3O(CH2CH2O)2CH3 unidentified
30 [min]
20
Molecular Retention Weight Index 30; 44 32 74 76 134 -
245 260 603 616 807 988
[ Related References ] 1) Burg, K. H.; Fischer, F.; Weissermel, K. Makromol. Chem. 1967, 103, 268. 2) Ishida, Y.; Ohtani, H.; Abe, K.; Tsuge, S.; Yamamoto, K.; Katoh, K. Macromolecules 1995, 28, 528.
Relative Intensity 100.0 64.0 2.5 5.3 8.6 4.2
193
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
092
EGA thermogram
Averaged mass spectrum 30
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
44 75
55
87 98
50
135
100
150
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
DO : 1,3-dioxolane
MO : methanol 29
H H
O
O H
73
29
O
44
H
45
PG : propylene glycol
EA : 1-methoxy-2-(2-methoxyethoxy)ethane 45
45
OH HO
O
O O
31
31 61
61 75
A : unidentified 45
31 61
75
89
105
119
89
74 90
119
194
Tsuge, Ohtani and Watanabe
093 Poly(ethylene oxide) CH 2 CH 2 O
n
M
HP3 HP2 HP1 H4 P4
D2 EE D3
D4
T4 T2 T3
TIC
TE4
T1
TE3 TE2 TE1
0
P2 P1
P3
H3 H2 H1
10
Peak Notation M EE D2 D3 D4 T1 T2 T3
T4 TE1 TE2 TE3
TE4 P4 HP4 O4 N4 DE4 DO4
HP4 O4 O3 O2 O1
N4 DE4
N1
U4 DO4
30 [min]
20
Assignment of Main Peaks ethylene oxide CH3CH2OOCH2CH3 + CH2=CHOCH2CH3 CH3CH2OCH2CH=O CH2=CHOCH2CH2OH CH2=CHOCH2CH2OCH3 CH2=CHOCH2CH2OCH2CH3 CH3OCH2CH2OCH2CH=O CH2=CHOCH2CH2OCH2CH=O CH3CH2OCH2CH2OCH2CH=O CH2=CHO(CH2CH2O)2H CH2=CHO(CH2CH2O)2CH3 CH3CH2O(CH2CH2O)2CH3 CH2=CHO(CH2CH2O)2CH2CH3 CH3CH2O(CH2CH2O)2CH2CH3 CH3O(CH2CH2O)2CH2CH=O CH2=CHO(CH2CH2O)2CH2CH=O CH3CH2O(CH2CH2O)2CH2CH=O CH2=CHO(CH2CH2O)3H CH2=CHO(CH2CH2O)3CH3 CH3CH2O(CH2CH2O)3CH3 CH2=CHO(CH2CH2O)3CH2CH3 CH3CH2O(CH2CH2O)3CH2CH3 CH2=CHO(CH2CH2O)4CH=CH2 + CH2=CHO(CH2CH2O)4CH2CH3 CH3CH2O(CH2CH2O)4CH2CH3 CH3CH2O(CH2CH2O)6CH2CH3 CH3CH2O(CH2CH2O)7CH2CH3 CH3CH2O(CH2CH2O)8CH2CH3 CH3CH2O(CH2CH2O)9CH2CH3 CH2=CHO(CH2CH2O)11CH=CH2 CH2=CHO(CH2CH2O)11CH2CH3 CH3CH2O(CH2CH2O)11CH2CH3
Molecular Retention Weight Index 44 74, 72 88 88 102 116 118 130 132 132 146 148 160 162 162 174 176 176 190 192 204 206 246, 248 250 336 380 424 468 554 556 558
[ Related References ] 1) Madorsky, S. L.; Straus, S. J. Polym. Sci. 1959, 36, 183. 2) Voorhees, K. J.; Baugh, S. F.; Stevenson, D. N. J. Anal. Appl. Pyrolysis 1994, 30, 47. 3) Fares, M. M.; Hacaloglu, J.; Suzer, S. Eur. Polym. J. 1994, 30, 845.
360 490 657 719 726 802 862 961 971 1004 1015 1019 1084 1090 1173 1238 1251 1284 1296 1308 1358 1363 1629 1634 2169 2439 2703 2975 3506 3511 3518
Relative Intensity 100.0 22.9 23.3 16.1 9.3 20.7 2.6 4.4 3.5 2.0 5.2 4.2 13.6 5.9 1.6 4.5 5.2 2.4 11.4 0.9 15.4 7.8 18.7 8.7 31.6 32.3 31.8 31.5 3.6 13.3 6.5
195
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
093
EGA thermogram
Averaged mass spectrum 45
100
29
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
59 73 87
103
50
117
131133
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
M : ethylene oxide
EE : diethyl ether + ethoxyethene 43
29
O
O
+
29
O 72
44 59
D2 : 2-ethoxyacetaldehyde
D3 : 2-(vinyloxy)ethanol
31
45
O
OH
O
O 59 31 45 57
D3 : (2-methoxyethoxy)ethene
D4 : (2-ethoxyethoxy)ethene
45
45
O
O
58
29
88
69
O
O 31 72 59
87
72
102
86
HP4 : 3,6,9,12,15,18,21-heptaoxatricos-1-ene O
O
O
O
45
O
O
O
89
117 101
133
147 161
O
177
89
59
29
N4 :3,6,9,12,15,18,21,24,27-nonaoxanonacos-1-ene
O
O
O
O
O
117 133
101
161 177
201
DE4 : 3,6,9,12,15,18,21,24,27,30-decaoxadotriacont-1-ene
45
45
O
O
O
O
O
O
O
O
O
O
73 59 29
O
73
73 59
29
116
O4 : 3,6,9,12,15,18,21,24-octaoxahexacos-1-ene
45
O
101
O
O
O
O
O
O
O
O O
73 117
89 101
133
147 161 177
203 221
29
59
117
89 101
133
147 161 177
221
196
Tsuge, Ohtani and Watanabe
094 Epichlorohydrin rubber; CHR CH 2 CH(CH 2 Cl)O
n
D2 LB
D1
T3 T1
P2
P1
T2
TE3
AC
TE1
CP
15
10
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB AC CP D1 D2 T1 T2 T3 TE1 TE3 P1 P2
hydrogen chloride, propylene acrolein CH2=CHCHO 3-chloropropylene CH2=CHCH2Cl C6H9ClO2 C6H11ClO2 C9H13ClO3 C9H14Cl2O3 C9H16Cl2O3 C12H18Cl2O4 C12H21Cl3O4 C15H23Cl3O5 C15H26Cl4O4 [ Related References ] 1) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 2) Mcguire, J. M.; Bryden, C. C. J. Appl. Polym. Sci., 1988, 35, 537.
30 [min]
20
Molecular Retention Weight Index 36, 42 56 76 148 150 204 240 242 296 334 388 410
295 490 530 1023 1090 1258 1392 1531 1721 1910 2134 2675
Relative Intensity 100.0 8.0 13.7 6.7 8.2 3.4 2.9 4.6 1.0 2.4 2.8 4.1
197
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
094
EGA thermogram
Averaged mass spectrum 43
57
29
100
200
300
400
500
93
600
700 ºC
programming rate: 20ºC/min
75 77
121 107
50
135
100
149
171175
188
150
205
229 250 [m/z]
200
( m/z range : 29 - 600 amu )
AC : acrolein
LB : hydrogen chloride (+ propylene) 36
Cl
H
O
56
+
29
37 67
32
CP : 3-chloropropylene
76
D2 : C6H11ClO2 41
39
Cl
76 49
32
31
119
77 101
63
T3 : C9H16Cl2O3
115
TE3 : C12H21Cl3O4
41
41
55
121 29
57
75
5763
91 77
29 149
106
77 75
169
P1 : C15H23Cl3O5
93
111 121
137 149
175 169
P2 :C15H26Cl4O4
41
41 93 75 93
29
57
77
29
111121 141 149
169
203
259
121
57 77 75
107
149 137
169 185 189
241
198
Tsuge, Ohtani and Watanabe
095 Epichlorohydrin-ethylene oxide rubber; CHC CH2CH2O
CH2CH(CH2Cl)O CE3
LB
D2
CE2
A
b c AC
D1
CEE
CEE1 T3
a
CP EP TIC
n
10
5
CE1
0
10
Peak Notation
Assignment of Main Peaks
LB A AC CP EP CE1 CE2 CE3 a b c D1 D2 CEE CEE1 T3
hydrogen chloride + propylene acetaldehyde acrolein CH2=CHCHO 3-chloropropylene CH2=CHCH2Cl epichlorohydrin ? C5H8O2 C5H9ClO (mixture of dimer) C6H11ClO unidentified unidentified unidentified C6H9ClO2 C6H11ClO2 C6H13ClO3 C8H15ClO3 C9H16Cl2O3
[ Related References ] 1) Pidduck, A. J. J. Anal. Appl. Pyrolysis 1985, 7, 215. 2) McGuire, J. M.; Bryden, C. C. J. Appl. Polym. Sci., 1988, 35, 537.
30 [min]
20
Molecular Retention Weight Index 36; 42 44 56 76 92 ? 100 120 134 132 150 148 148 150 168 194 242
295 408 490 530 637 679 754 774 802 837 883 910 986 1090 1371 1648
Relative Intensity 100.0 42.2 10.5 8.9 15.2 2.6 4.8 9.6 2.3 3.5 2.5 1.6 9.3 2.7 1.4 2.1
199
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
095
EGA thermogram
Averaged mass spectrum 45
100
29
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
57
87
63
93 107
50
121
137
100
151
165 175
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : hydrogen chloride
A : acetaldehyde 36
H
29
Cl O
44
32
56
AC : acrolein
62
CP : 3-chloropropylene 56
O
39
Cl
29
76 37 49
67
75
CE3 : C6H11ClO
CE2 : C5H9ClO (mixed dimer)
43
99 73 45 29
55 100 29 55
D1 : C6H9ClO2
72
85
D2 : C6H11ClO2 87
79
29 107
29
43
41 49
55
CEE : C6H13ClO3
136 121
T3 : C9H16Cl2O3
41
31
92
63
94
66
41
57
119
77 63
29
93
57 63
101
84
121
200
Tsuge, Ohtani and Watanabe
2.2.12 Thermosetting polymers 096 Phenol formaldehyde resin (novolak); PF OH CH2 n
P D1 D2 PC OC
D3 X2 HQ
BQ
TIC
A
HA
X1
0
PP XT MX
10
Assignment of Main Peaks
BQ P OC PC X1 X2
benzoquinone phenol o-cresol p-cresol 2,6-xylenol 2,4-xylenol
HA PP XT MX A
T2 T1
30 [min]
20
Peak Notation
HQ
D4
Molecular Retention Weight Index
O H HO
p-hydroxybenzaldehyde o-phenylphenol O xanthene 2-methylxanthene unidentified OH
D1
OH
O
Relative Intensity
108 94 108 108 122 122
920 986 1060 1081 1115 1155
0.8 100.0 32.0 43.7 2.2 11.3
110
1275
9.5
122 170 182 196 -
1369 1540 1687 1808 1998
9.5 2.4 2.3 3.3 8.3
200
2034
60.7
200
2101
73.5
214
2119
10.2
214
2164
10.1
306
3099
7.0
320
3178
12.3
OH C H2
OH CH 2
D2
OH OH
OH
C H3
C H2
D3 OH
C H2
D4
OH OH
OH CH 2
T1 OH
T2
C H3
OH CH 2
OH CH 2
OH CH 2
CH 3
[ Related References ] 1) Jones, S. T. Analyst. 1984, 109, 823. 2) Morterra, C.; Low, M. J. D. Carbon 1985, 23, 525. 3) Blazso, M.; Toth, T. J. Anal. Appl. Pyrolysis 1991, 19, 251. 4) Cohen, Y.; Aizenshtat, Z. J. Anal. Appl. Pyrolysis 1992, 22, 153. 5) Lytle, C. A.; Bertsch, W.; McKinley, M. J. Anal. Appl. Pyrolysis 1998, 45, 121. 6) Sobera, M.; Hetper, J. J. Chromatogr. A 2003, 993, 131.
201
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
096
EGA thermogram
Averaged mass spectrum 94
107
100
66
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
39
200
77 51 121
141
31 50
100
152
181
165
214
150
228
200
250 [m/z]
( m/z range : 29 - 600 amu )
OC : o-cresol
P : phenol OH
94
108
OH
66
39
77
55
29
79
PC : p-cresol
90
63
X2 : 2,4-xylenol 107
OH
122
OH
107
77 29
51
39
29
51
39
77
39
90
63
51
29
91
65
HA : p-hydroxybenzaldehyde
HQ : hydroquinone 110
OH
121
O
HO
29
OH
81
53
39
63
D1 : 2,2'-methylenebisphenol OH
OH
93
65
39 53
29
95
77
D2 : 2,4'-methylenediphenol
107
107
OH
200
200
OH 94
29
77
39 51 63
152 181 128 141 165
202
29
T1 : 2,2'-(2-hydroxy-1,3-phenylene) OH
55 63
183 152 128 141 165
94
202
T2 : 2-(2-hydroxy-3-(2-hydroxybenzyl)benzyl)
bis(methylene)diphenol 107
39
77
-6-methylphenol OH
OH
OH
OH
OH 306 199
107 306 199 213 39 5565
77 94
213
181 255
287
320
3139
55 65
77
94
128
152
181 334
202
Tsuge, Ohtani and Watanabe
097 Phenol formaldehyde resin (resol); PF OH CH2 n
D1
P PC
OC
D2
XT
D3 MX
D4
X2 15
TIC
20
X1
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
P OC PC X1 X2 XT
phenol o-cresol p-cresol 2,6-xylenol 2,4-xylenol xanthene
MX
2-methylxanthene
O
Molecular Retention Weight Index
Relative Intensity
94 108 108 122 122 182
986 1061 1081 1116 1155 1687
100.0 38.6 43.9 3.6 14.2 3.1
196
1807
2.2
200
2029
11.4
200
2093
10.0
214
2116
1.6
214
2163
1.7
O
OH
D1
OH C H2
OH CH 2
D2
OH OH
D3
OH C H2
C H3
C H2
C H3
OH
D4
OH
[ Related References ] 1) Martinez, J.; Guiochon, G. J. Gas Chromatogr. 1967, 51, 146. 2) Jones, S. T. Analyst. 1984, 109, 823. 3) Morterra, C.; Low, M. J. D. Carbon 1985, 23, 525. 4) Prokai, L. J. Anal. Appl. Pyrolysis 1987, 12, 265. 5) Sobera, M.; Hetper, J. J. Chromatogr. A 2003, 993, 131.
203
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
097
EGA thermogram
Averaged mass spectrum 94
66
107
100
200
300
400
500
600
39
700 ºC
programming rate: 20ºC/min
77 51 122
31 50
152
100
181
165
195
150
200
250 [m/z]
( m/z range : 29 - 600 amu )
OC : o-cresol
P : phenol OH
94
108
OH
77
66
39 55
29
79
PC : p-cresol
51
39
29
90
63
X1 : 2,6-xylenol
OH
122
OH
107
107
77
77 29
51
39
39
90
63
X2 : 2,4-xylenol
91
65
132
XT : xanthene
OH
107
77 29
51
31
39
51
122
181
O
91
65
39
MX : 2-methylxanthene
76
51 63
152 90
115 127 139
D1 : 2,2'-methylenediphenol 195
O
107
OH
OH
200 94
181 97 39
69
51
152 165 115 126 139
82
202
D4 : 4-(2-hydroxybenzyl)-2-methylphenol
D2 : 2,4'-methylenediphenol 107
OH
152 181 128 141 165
77 29 39 51 63
214
OH 200
39
55 63 77
107 121
HO
OH 94
183 152 128 141 165
214
39
55 65
77
91
199
181 141152 165
216
204
Tsuge, Ohtani and Watanabe
098 Cresol formaldehyde resin (novolak) CH3 OH CH2 OC
n
D1 D3
X2
D4
X1 TP
D5 D2 T1
PC TIC
T2
P
0
10
Peak Notation
Assignment of Main Peaks
P OC PC X1 X2 TP
phenol o-cresol p-cresol 2,6-xylenol 2,4-xylenol 2,4,6-trimethylphenol C
D1
HO
D2
HO
C C C
HO
HO C
HO
C
2140
99.7
242
2191
14.8
242
2233
100.0
C
256
2269
18.9
242
2286
26.2
348
3211
30.8
376
3308
43.6
OH C
C C HO
C HO
C HO
C C
T2
228
C
HO
T1
6.6 88.9 6.6 44.8 64.6 32.0
C
C
D5
985 1060 1079 1116 1155 1215
C HO
C
94 108 108 122 122 136
C
C
D4
Relative Intensity
C HO
C
D3
Molecular Retention Weight Index
C HO
C
30 [min]
20
C C
C
HO
HO
HO
C
C
C
C
* bonding hydrogen is omitted [ Related References ] 1) Blazso, M.; Toth, T. J. Anal. Appl. Pyrolysis 1991, 19, 251. 2) Cohen, Y.; Aizenshtat, Z. J. Anal. Appl. Pyrolysis 1992, 22, 153.
205
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
098
EGA thermogram
Averaged mass spectrum 121 107 77
100
200
300
400
500
91 39
51
65
700 ºC
228
135
152 165
31 50
600
programming rate: 20ºC/min
100
150
213
181 195
242 256
200
250
300 [m/z]
( m/z range : 29 - 600 amu )
OC : o-cresol
X1 : 2,6-xylenol OH
108
OH
122 107
77 29
51
39
90
77
63
29
X2 : 2,4-xylenol
51
OH
77 39
51
122
121 136
91
91
65
29
39
51
122
HO
108
HO
228
77 91
165 141152 181 195 213
242 77 29 39 51 65
230
D3 : 2-(4-hydroxy-3-methylbenzyl)-4,6-dimethylphenol
91 107
135 152 165 181 197 211 227
121
227 242
HO
213
OH
121 108 77 91
135 152
165 181 197
242
T1 : 4,6'-(4-hydroxy-5-methylene)
244
D5 : 4-(4-hydroxy-3-methylbenzyl)-2,6-dimethylphenol
228
HO
51 65 29 39
117
D2 : 4-(2-hydroxy-3-methylbenzyl)-2,6-dimethylphenol
HO
HO
77
65
121
29 39 51 65
132
OH
D1 : 4,6-methylenebis(2-methylphenol) HO
91
65
TP : 2,4,6-trimethylphenol 107
29
39
29 39 51 65
77 91
135
115
152
165 181 197 211
244
T2 : 4-(2-hydroxy-3,5-dimethylbenzyl)-2-(4-hydroxy-3,5 -dimethylbenzyl)-6-methylphenol
bis(methylene)bis(2-methylphenol)
121
121
HO
HO
HO
348 HO
HO
HO
225 240 348
29 53
108 77 91
228 240
197 7791 108 135 165 152 181 211 43 65
376
206
Tsuge, Ohtani and Watanabe
099 Diallyl phthalate resin; DAP CH2CHCH2OCO
COOCH2CHCH2
n
PA
AB
C6 LB TIC
BA B
M
T
0
10
Peak Notation
Assignment of Main Peaks
LB C6 B T BA AB PA M
propylene etc. C6H12 benzene toluene benzoic acid C6H5COOH allyl benzoate C6H5COOCH2CH=CH2 phthalic anhydride C6H4COOCO CH2=CHCH2OCOC6H4COOCH2CH=CH2 (monomer)
30 [min]
20
Molecular Retention Weight Index 42 84 78 92 122 162 148 246
* C6H5 represents phenyl group ; C6H4 represents o-phenylene group
295 598 658 767 1183 1264 1343 1755
Relative Intensity 11.73 0.27 5.25 2.66 22.87 1.26 100.00 1.47
207
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
099
EGA thermogram
Averaged mass spectrum 104 76
100
200
300
400
500
600
50
700 ºC
programming rate: 20ºC/min
74 31
37
91 50
122
141
100
148
165
178
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C6 : 1-hexene
B : benzene 44
55
78
84
69
29
39
T : toluene
51 74
BA : benzoic acid 91
O
105
OH
122 77
51 39
65
51
79 29
AB : allyl benzoate
104
O
76
77 29 39
50
74
131
91
162
147
29
M : diallyl phthalate O O
41
O
O 149
76
146
104 98
189 132 121
180
203
226 246
38
O O 148 O
74
51
50 65
94
PA : phthalic anhydride 105
O
29
74
39
208
Tsuge, Ohtani and Watanabe
100 Poly(ethylene glycol bisallyl carbonate); CR-39 CH2CHCH2OCOOCH2CH2OCH2OCOOCH2 CHCH2
n
LB
EV
A
CD DG
TIC
AA
DO
0
BD VD VE
AB
M B
C
10
Peak Notation
Assignment of Main Peaks
LB AA DO EV DG VE AB CD VD BD M A B C
CO2 + propylene etc. allyl alcohol 1,4-dioxane ethylene glycol monovinyl ether C=C-O-C-C-OH diethylene glycol HO-C-C-O-C-C-OH C=C-O-CO-O-C-C-OH allyl benzoate C6H5COO2CH=CH2 C=C-C-O-CO-O-C-C-O-C-C-OH C=C-O-CO-O-C-C-O-C-C-OH C6H5COO-C-C-O-C-C-OH C=C-C-O-CO-O-C-C-O-C-C-O-CO-O-C-C=C (monomer) unidentified unidentified unidentified (initiator)
30 [min]
20
Molecular Retention Weight Index
* bonding hydrogen is omitted ; C6H5 represents phenyl group
44; 42 58 88 88 106 132 162 190 176 210 274 238 264 -
150 562 705 720 983 1152 1268 1369 1569 1711 1776 1799 1930 2395
Relative Intensity 100.0 2.9 2.9 24.3 55.9 6.5 0.5 16.9 8.8 4.0 1.4 13.3 2.1 1.0
209
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
100
EGA thermogram
Averaged mass spectrum 45
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31 89 91
75
55
105 119
50
133
149
100
165
178 200 [m/z]
150
( m/z range : 29 - 600 amu )
EV : ethylene glycol monovinyl ether
DG : diethylene glycol
O
O
45
OH
45
HO
OH
31 57
OH
O
O 29
105
O
102
O
58
AB : allyl benzoate
VE : 2-hydroxyethyl vinyl carbonate O
75 76
31
88
73
43 77
58 73
132
104
89
146
CD : 2-(2-hydroxyethoxy)ethyl vinyl carbonate 45
O
O
29
67
91
131
O
75
105
119
141
29
160
105
O
O
102 116
41
O
O
O
91
O
O
89
149
180
135
45
89 75
177
O
O
122 75
133 147
129
51
58
71
OH
A : pentaethylene glycol
31
58
77
45 31
OH
M : diallyl 2,2'-oxybis(ethane-2,1-diyl) dicarbonate (monomer)
BD : 2-(2-hydroxyethoxy)ethyl benzoate O
O
O
89
89 54
162
O
45
O
31
146
VD : allyl 2-(2-hydroxyethoxy)ethyl carbonate OH
O
51
39
102 116120133 148 164 178
208
29
57
73
90
117
133
159 173
210
Tsuge, Ohtani and Watanabe
101 Urea formaldehyde resin; UF CH2NCONCH2
MI
e
LB TIC
n
b TA EN
0
a
c
d f
g
10
Peak Notation
Assignment of Main Peaks
LB MI TA EN a b c d e f g
CO2 N N-methylethyleneimine ? N 1,3,5-triazine N N N,N-dimethylaminoethanenitrile ? (CH3)2NCH2CN 1,3,5-trimethyl-1,3,5-triazinane N hexamethylenetetramine N N N unidentified unidentified unidentified unidentified unidentified
30 [min]
20
Molecular Retention Weight Index 44 57 ? 81 84 ? 129 140 -
150 460 666 746 982 1236 1259 1276 1369 1443 1612
Relative Intensity 24.8 100.0 7.0 2.4 5.9 15.3 9.3 2.0 55.2 11.1 16.8
211
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
101
EGA thermogram
Averaged mass spectrum 43
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
57
30
70
81
112
94
50
128
143 149
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
MI : N-methylethylenimine
TA : 1,3,5-triazine
43
81
N N
57
N
54
N
29 29
EN : 2-dimethylaminoacetonitrile
38
a : 1,3,5-trimethyl-1,3,5-triazinane 44
83
N
N 58
42
N
N
86
N
128
57 67
30
30
b : hexamethylenetetramine
71
c : unidentified N
42
N
112
N
140
42
N
30
71
56
58
85 96
112
29
e : unidentified
71
98 85
128
f : unidentified 114
128 44 44
58
30
71
30 85
99
112
g : unidentified 128
42 29
58
70
83
101
160
56
71
85 99
128 140
157
140
212
Tsuge, Ohtani and Watanabe
102 Melamine formaldehyde resin; MF N
H 2CN N DM
NCH 2
n
N N
MI M
TM
TIC
DT
0
10
Peak Notation
Assignment of Main Peaks
MI DT TM DM
formaldehyde 2,4-diamino-1,3,5-triazine N,N,N-trimethylmelamine ? N,N-dimethylmelamine ?
M
melamine
H2 N
NH 2
N N
30 [min]
20
N NH2
Molecular Retention Weight Index
Relative Intensity
30 111 ? 168 ? 154 ?
261 1287 1554 1598
8.9 3.7 9.2 68.3
126
1677
100.0
213
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
102
EGA thermogram
Averaged mass spectrum 43
69 100
111
57
300
500
600
700 ºC
154
98 50
400
programming rate: 20ºC/min
125
83
30
200
140
168
182
150
100
200 [m/z]
( m/z range : 29 - 600 amu )
MI : formaldehyde H
H
DT : 2,4-diamino-1,3,5-triazine
29
N
111
N N
H2N
NH2
O
43 70 53
29
DM : N,N-dimethylmelamine H N N
H N
140
126
N NH
111
69
43
126 85
55
30
85 154
97
68 29
M : melamine 126
N
H 2N N
NH 2 N
43 NH 2 85 68 29
53
99 111
120
H N
N N
N NH 2 43
94
TM : N,N,N-trimethylmelamine
H N
N
84
140 154 168
56
99
110
214
Tsuge, Ohtani and Watanabe
103 Xylene resin CH3 (CH2 O)mCH2 CH3 n
D1 D2
D3
D4
A B D 1’ C DA
TM
TA
DO TE
TIC
X 0
10
Peak Notation
Assignment of Main Peaks
X TM TE DA DO TA
m-xylene 1,2,4-trimethyl benzene 1,2,4,5-tetramethyl benzene 2,4-dimethyl benzaldehyde 2,4-dimethyl benzyl alcohol 2,4,5-trimethyl benzaldehyde C H3
D 1’
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
106 120 134 134 136 148
873 999 1127 1198 1250 1339
0.6 7.0 3.6 6.8 2.6 4.9
224
1838
19.0
224
1866
100.0
238
1961
36.0
268
2129
23.0
CH3
252
2195
32.6
( C H 3) 2 C H3 C H3
266
2222
42.8
254
2282
31.6
-
3152
21.8
C H3 C H2
CH3
CH3 CH3
D1
C H3 C H2
CH3
CH3 C H3
D2
C H3 C H2
C H3 C H3
C H3
A
unidentified C H3
C H3 C H2
D3
C H3 C H3
D4
( C H 3) 2 CH
C H2
H3 C C H3 C H3
3
C H2 O C H 2
B C
C H3
unidentified
C H3
215
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
103
EGA thermogram
Averaged mass spectrum 118
91 100
77
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
117
39
51
65
132
31 50
100
146
165
179
209
193
150
224
236 250 [m/z]
200
( m/z range : 29 - 600 amu )
TM : 1,2,4-trimethylbenzene
TE : 1,2,4,5-tetramethylbenzene 119
105
134
120
39
51
77
65
91 29
39
91
77
65
51
117
TA : 2,4,5-trimethylbenzaldehyde
DA : 2,4-dimethylbenzaldehyde O
133
147
O 105 119 77 29
51
39
91
63
29 39
119
51
65
91
77
105 133
D1 : bis(2,4-dimethylphenyl)methane
D1' : C17H20
118
118
209 224
224 209 77 91 29 39 51 65
165 141152
117
179 194
179 194 29 39 51 65
D2 : C18H22
77 91
117
141152
165
D3 : C19H24 223
252 238
118
237
146 132 118
179 194 209
193 208 77 29 41 51 65
91
117
178 152 165
29 39 51 65
D4 : C20H26
77 91 117
145
223
165 282
B : 4,4'-oxybis(methylene)bis(1,3-dimethylbenzene) 254
236
O
119
223 118 221 91 31
65
77
148 117
135
193 208 178 165
236 45 266
298
29
77
91 117
146
178
207
266
298 300
216
Tsuge, Ohtani and Watanabe
104 Unsaturated polyester; UP CH2 CH(C6H5)
CHCHCOOCH2CH2 OCO
COOCH2CH2 OCO
n
S
PA
SS PO
BA
T TIC
MS
S
a
b
SSS c
B
0
10
Peak Notation PO B T S S BA PA a MS SS b SSS c
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
propylene oxide benzene toluene styrene -methylstyrene benzoic acid C6H5COOH phthalic anhydride C6H4COOCO 2-hydroxyethyl benzoate styrene-maleic anhydride (hybrid dimer) CH2=C(C6H5)CH2CH2C6H5 (styrene dimer) unidentified CH2=C(C6H5)CH2CH(C6H5)CH2CH2C6H5 (styrene trimer) unidentified * C6H5 represents phenyl group
[ Related References ] 1) Ravey, M. J. Polym. Sci., Polym. Chem. Ed. 1983, 21, 1. 2) Vijayakumar, C. T.; Fink, J. K.; Lederer, K. Eur. Polym. J. 1987, 23, 861. 3) Hiltz, J. A. J. Anal. Appl. Pyrolysis 1991, 22, 113. 4) Evans, S. J.; Haines, P. J.; Skinner, G. A. J. Anal. Appl. Pyrolysis 2000, 55, 13.
58 78 92 104 118 122 148 166 202 208 312 -
410 652 765 895 983 1180 1334 1396 1637 1738 1871 2445 2516
Relative Intensity 10.3 2.3 7.5 71.9 6.5 3.9 100.0 3.5 5.6 7.4 4.8 6.4 4.2
217
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
104
EGA thermogram
Averaged mass spectrum 104
100
76
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
50 103
74
31 39
131 132
50
100
149 162
179
193 202
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
T : toluene
B : benzene 78
52
39
29
91
39
74
S : styrene
51
65
89
S : -methylstyrene 118
104
117 78
103
103 78
51 39
63
39
BA : benzoic acid O
51
63
PA : phthalic anhydride 105
OH
104
O
122 76 77
O 50
148 O
51 74 74
38
94
29
MS : styrene-maleic anhydride (hybrid dimer)
38
SS : but-3-ene-1,3-diyldibenzene (dimer)
202
91
129 115 39
51
64 77 91
174 145
104
156 173
39 51
196
SSS : 5-hexene-1,3,5-triyltribenzene (trimer) 91
117 77 39 51 65
118 143
194 179
207 221 242
297
312
65 77
208 130 165 180
193
218
Tsuge, Ohtani and Watanabe
105 Epoxy resin; EP CH2CH(OH)CH2O
C(CH3)2
OCH2CH(OH)CH2N
CH2
N
n
BA d f e IP’ P
g
h
c
a
AC TIC
IP
LB AA
b
OC
0
10
Peak Notation
Assignment of Main Peaks
LB AC AA P OC IP IP’
ethylene oxide etc. acetaldehyde allyl alcohol phenol + aniline o-cresol p-isopropylphenol p-isopropenylphenol C
HO
C
C C C
OH
C
O
44 58 94, 93 108 136 134
349 408 564 981 1055 1200 1305
2.7 7.3 0.4 12.9 3.9 6.0 16.3
212
1844
11.2
226
1944
5.5
242
2107
15.4
228
2192
100.0
242
2214
24.4
212
2219
19.2
226
2236
19.8
C C
C
BA
Relative Intensity
OH
C C
b c
Molecular Retention Weight Index
C
a
30 [min]
20
bisphenol A
C
HO
OH
C C
C
d
HO
C
OH
C
e
C N
C
f
C C
C
g
C N C
C
N
C
240
2325
18.1
h
C C
C
N
C C
254
2342
20.9
N
N
NH2
NH2
* bonding hydrogen is omitted
[ Related References ] 1) Nakagawa, H.; Tsuge, S.; Koyama, T. J. Anal. Appl. Pyrolysis 1987, 12, 97. 2) Nakagawa, H.; Wakatsuka, S.; Tsuge, S.; Koyama,T. Polym. J. 1988, 20, 9. 3) Plage, B.; Schulten, H.-R. Macromolecules 1988, 21, 2018. 4) Bradna, P.; Zima, J. J. Anal. Appl. Pyrolysis 1992, 24, 75. 5) Nakagawa, H. ; Wakatsuka, S. ; Ohtani, H. ; Tsuge, S. ; Koyama, T. Polymer 1992, 33, 3556. 6) Fuchslueger, U.; Grether, H.-J.; Grassercauer, M. Fresenius J. Anal. Chem. 1994, 349, 283.
219
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
105
EGA thermogram
Averaged mass spectrum 213 119
91
100
134
65 77
39
200
300
400
500
600
51 152 100
228237
165
254
181 197
31 50
700 ºC
programming rate: 20ºC/min
107
150
269 279290
200
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
AC : acetaldehyde
P : phenol (+ aniline)
29
94
NH2
OH
44
O
+ 66 39 55
29
56
IP' : p-isopropenylphenol
79
a : p-hydroxy-2,2-diphenylpropane 134
OH
197
OH
119
212
91 39
29
65
51
77
105
39 51 65
146
c : 2-(4'-hydroxyphenyl)-2-(4'-methoxyphenyl)propane
103 119 135 152 165 182 115
77
BA : bisphenol A
227
HO
213
HO
O
OH
228 242 119 133 152165 183 197 212 39 51 65 77 91 106
119 29 39
244
d : 4-(2-(4-hydroxyphenyl)propan-2-yl)-2-methylphenol
55 65 77
91
107
135 152 165 181 197
e : 4-(4-aminobenzyl)-N-methylaniline 212
227
HO
230
OH
NH2
N H 242 106
29
55
77 91 107 119 133
244
210
g : N,N-dimethyl-4-(4-(methylamino)benzyl)aniline
30 42 52
7078
120 168 140 154
98
182 196
h : 4,4'-methylenebis(N,N-dimethylaniline) 254
240
120 134 42
65
91 112
N
N
N H
N
196 152
180
223 268
42
65
91 104
134 126
210 165 152
194
237 223
266
220
Tsuge, Ohtani and Watanabe
106 Brominated epoxy resin Br CH2 CHCH2 O O
Br C(CH3)2
Br
Br
Br OCH2CHCH2 O
Br
OH
n
C(CH3)2 Br
OCH2CH CH2 O
Br
H
J I G BM A
P BP
E
D
B
TIC
TP
T
C
0
10
F
30 [min]
20
Peak Notation
Assignment of Main Peaks
BM A
bromomethane CH3Br acetone
B
BrCH2CCH3
T P BP C D TP
toluene phenol 2-bromophenol 2,4-dibromophenol 2,6-dibromophenol 2,4,6-tribromophenol
O
Molecular Retention Weight Index
Relative Intensity
94 58
465
7.5 7.0
136
760
4.9
92 94 172 250 250 328
767 983 1077 1397 1397 1668
1.5 14.9 13.9 3.0 11.8 5.0
290
1715
16.1
384
2344
6.6
446
2479
22.8
462
2798
100.0
524
2869
32.9
540
3109
97.7
Br O
E
C H3 Br Br
F
HO
Br
G
HO
Br C(C H3 )2
Br Br
H
OH
C(CH 3) 2 Br
HO
Br C(C H3)2
OH
Br Br
I
HO
Br C (C H3 )2
Br
Br
Br
J
HO
Br OH
C (C H 3 ) 2 Br
Br
221
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
106
EGA thermogram
Averaged mass spectrum 43 82
100
200
300
400
500
600
529 63 53
29
0
152 181 91105 118133 165 196
50
100
150
277 293 212217 252 265
200
250
300
449 464 505 468489 513
371 369 386 409 350
400
450
700 ºC
programming rate: 20ºC/min
544 550 [m/z]
500
( m/z range : 29 - 600 amu )
B : 1-bromo-2-propanone
A : acetone 43
43
O
O Br
58 29
29
80
P : phenol
79
53
136
93
121
D : 2,6-dibromophenol OH
94
OH
Br
63
66 39 55
29
252
Br
79
E : 5,7-dibromo-2-methyl-2,3-dihydrobenzofuran O
197
223
F : 4,4'-(propane-2,2-diyl)bis(2-bromophenol)
292
Br
143 146
92
29
Br
291
Br
HO
OH
132
Br
277 29
39
51 66 77
103 104
131
196
252 265
211
29
G : 2-(3-bromophenyl)-
propan-2-yl)phenol Br
371
Br
Br
449
OH
HO
HO 369
Br 29
Br 386
63
89
118
152 181
152 181 213
29
J : 4,4'-(propane-2,2'-diyl)bis(2,6-dibromophenol)
propan-2-yl)phenol Br
468 105
211
I : 2,6-dibromo-4-(2-(3,5-dibromophenyl)
Br
513
Br
Br
HO
Br
Br
Br 163
293 272
528 353
432
529
OH
HO
41
308 277
H : 2,6-dibromo-4-(2-(3-bromo-4-hydroxyphenyl)
2-(3,5-dibromo-4-hydroxyphenyl)propane Br
197 212
119
51
152 53 76 112144 29
Br 217
293 277
544 448
222
Tsuge, Ohtani and Watanabe
2.2.13 Polyimide and polyamide-type engineering plastics 107 Bismaleimide triazine resin; BT resin O
C(CH3)2
N
O
CO N
N
CO
CH2
N
CO CO
N N
O n
O
BA
IP’
P
IP TIC
LB AL
PC
a
0
d
b
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
LB AL P PC IP IP’
propylene etc. acrolein ? phenol + aniline p-cresol p-isopropylphenol p-isopropenylphenol
Molecular Weight
Retention Index
Relative Intensity
56 94; 93 108 136 134
295 498 985 1077 1231 1308
8.4 5.4 44.0 3.5 10.2 27.9
212
1758
2.4
226
1882
4.7
228
2212
100.0
242
2252
7.0
C C
a
OH
C C
C
b
C
OH
C
BA
C
bisphenol A C
d
HO
C
HO
C
OH
C
C OH
C
* bonding hydrogen is omitted
223
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
107
EGA thermogram
Averaged mass spectrum 94
66
100
44
200
300
600
700 ºC
134 152
30 50
500
213
107
77
51
400
programming rate: 20ºC/min
119
100
165
183
228
197
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
PC : p-cresol
P : phenol (+ aniline) NH2
OH
94
107
OH
+ 66 77
39 55
29
79
29
39
51
133 90
63
IP' : p-isopropenylphenol
IP : p-isopropylphenol OH
121
134
OH 119
136 77 29
39
51
91
91
65
39
107
29
a : p-hydroxy-2,2-diphenylpropane
51
65
77
105
b : 2-methyl-4-(2-phenylpropan-2-yl)phenol 197
210
OH
OH
195 77 91 39 51 65
115 119
212 77 39 51 65
165 181 141152
103 119 135 152 165 182 115
d : 4-(2-(4-hydroxyphenyl)propan-2-yl)-2-methylphenol
BA : bisphenol A 213
HO
227
OH
HO
OH
228 242
119 29 39
55 65 77
91
107
135 152 165 181 197
230
119 91 106 133 149 165 181 197 213 29 39 5565 77
252
224
Tsuge, Ohtani and Watanabe
108 Polyetherimide; PEI CO O
C(CH3)2
CO N
O
CO
N CO
n
ID
P AI
c
PC
d DA
CB TIC
DE IP’ MD EP CP VP b
0
PA
10
Peak Notation
Assignment of Main Peaks
P CB PC EP VP DA IP’ CP b DE
phenol + aniline cyanobenzene + phenol p-cresol p-ethylphenol p-vinylphenol m-phenylenediamine p-isopropenylphenol m-cyanophenol p-cyanophenol diphenyl ether
MD
4-methyl(diphenyl ether)
30 [min]
20
Molecular Weight
O
C
Retention Index
Relative Intensity
94; 93 103; 94 108 122 120 108 134 119 119 170
985 1007 1078 1170 1220 1304 1306 1364 1406 1419
100.0 3.9 28.7 5.3 3.6 9.4 4.0 4.4 2.6 1.8
184
1532
7.0
210
1759
52.5
212
1882
5.4
238
2488
30.2
-
2935 3498
67.2 38.4
C
ID
4-isopropenyl(diphenyl ether) C
PA
O
C C
C OH
C H2 N
AI c d
N
CO CO
unidentified unidentified * bonding hydrogen is omitted [ Related References ] 1) Huang, F.; Wang, X.; Li, S. Polym. Degrad. Stab. 1987, 18, 247. 2) Carroccio, S.; Puglisi, C.; Montaudo, G. Macromol. Chem. Phys. 1999, 200, 2345. 3) Perng, L.-H. J. Polym. Res. 2000, 7, 185. 4) Perng, L.-H. J. Appl. Polym. Sci. 2001, 79, 1151.
225
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
108
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
94 66
51
77
107
50
119
141
100
152
165
210
195
183
150
238 250 [m/z]
200
( m/z range : 29 - 600 amu )
CB : cyanobenzene (+ phenol)
P : phenol (+ aniline) 94
NH2
OH
N
94
OH
+
+
117
44
39
76
51
55
29
118
66
66 29
79
EP : p-ethylphenol
PC : p-cresol 107
OH
107
OH
122
77 29
39
51
77
90
63
120
OH
65
91
108
NH2
91
29
51
DA : m-phenylenediamine
VP : p-vinylphenol
39
39
29
80
NH2
65
51
89
105
53
39
30
134
119
91
65
CP : m-cyanophenol
IP' : p-isopropenylphenol 108
OH
134
119
N
119 80 91 39
53
OH
91
64
65 39
29
29
MD : 4-methyl(diphenyl ether)
76
108
AI : 2-(3-aminophenyl)isoindoline-1,3-dione 184
O
52
H2N
238
O N
91 O 39
51
65
77
141 155 115 128 169
76 39 50 65
91 104 119 134
154 167 181
194
210
226
Tsuge, Ohtani and Watanabe
109 Polypyromellitimide; PI CO
CO
CO
CO
N
O
N n
OI
AP
EA
a
PI
c AN b
I P CB
TIC
DE BF
0
d
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
I P CB AP DE
phenyl isocyanate phenol + aniline cyanobenzene p-aminophenol diphenyl ether
PI
phthalimide
Molecular Weight
Retention Relative Index Intensity
119 94; 93 103 109 170
977 991 1014 1263 1419
1.5 50.8 2.4 100.0 3.9
147
1469
33.6
168
1545
5.0
185
1774
35.5
223
2081
16.6
CO NH CO O
BF EA
dibenzofuran O
NH2 CO
AN
N
phthalanil
CO
CO N
OH
OI
CO
239
2439
77.6
a b
unidentified unidentified
-
2687 2977
27.5 10.9
CO N
O
NH2
c
CO
330
3409
40.5
d
unidentified
-
3623
6.1
227
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
109
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
94 66
51
77
107
50
119
141
100
152
165
210
195
183
150
238
20 0
[m/z]
250
( m/z range : 29 - 600 amu )
P : phenol (+ aniline)
CB : cyanobenzene 94
NH2
OH
93
N
66 39
67
+
39
79
51 107
50 76
32
121
136
119
AP : p-aminophenol
DE : diphenyl ether 109
OH
170
O
141
80 51
NH2 30
77
39
53 39
63
91
115
65
119
131
BF : dibenzofuran
PI : phthalimide 76
O
147
NH
168
O
104
139
103 50 74
O
39
38
EA : p-phenoxyaniline
113
84
159
129
AN : phthalanil 185
108
O
55 62
179
O
NH 2
223
N 76 80
O
51 32
50
156
65
39
129
92
39
169
139
N
52 39
195
92 75
330
O 108
OH
N
O
NH 2
O
O 104
139 152 167 130
102
239
O
104
c : 2-(4-(4-aminophenoxy)phenyl)isoindoline -1,3-dione
OI : 2-(4-hydroxyphenyl)isoindoline-1,3-dione
76
64
76 167
130140 154
182
210
39 50
65 90
130 154 183 210 238 266
301
356
228
Tsuge, Ohtani and Watanabe
110 Polyaminobismaleimide; PABM CH2
CO
CH
CO
N
CH2
N
CO
CH2
CO
CH NH
CH2
NH n
DA MI
AN TL b
MA,TI TIC
a
LB
I
0
10
Peak Notation
Assignment of Main Peaks
LB I AN
CO2 phenyl isocyanate aniline
TL
p-toluidine
MA
NH2
CH2
TI
CH3
N
DA
diaminodiphenylmethane
a b
unidentified unidentified
MI
CH2 CO CH2 CO
N
Molecular Weight
NH2
CH3
Retention Index
Relative Intensity
44 119 93
150 963 984
10.2 1.3 24.9
107
1081
15.5
183
1799
189
1795
198
2169
53.3
-
2185 2613
4.2 8.6
280
2982
100.0
7.3
CO CH2 CO CH2
CH2
30 [min]
20
NH2
CH2
NH2
NH2
[ Related Reference ] 1) Crossland, B.; Knight, G. J.; Wright, W. W. Br. Polym. J. 1987, 19, 291.
229
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
110
EGA thermogram
Averaged mass spectrum 93
106 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
66 77
51
119
30 50
133
100
152
198
182
167
208
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
LB : carbon dioxide O
C
I : phenyl isocyanate O
44
O
119
C N 91 64 29
31
38
51
76
TL : p-toluidine
AN : aniline
106
93
NH2
NH2
66 77
39
52
30
O
91
189
183
106
N
183
O
189
106
H2N
133
55 39
63
MA : 4-benzylaniline
TI : 1-p-tolylpyrrolidine-2,5-dione
30
52
30 39
78
77
91
146
65
118
165
30 39
DA : diaminodiphenylmethane
55 65
133
77 91 118
146
165 203
a : unidentified 208
198
NH 2
H 2N
106 106
30 39 52 65
77
99
182 77 90 30 39 51 63
130 143152 168
b : unidentified
190 127 140 152 165 180
232
MI : 1-(4-(4-aminobenzyl)phenyl)pyrrolidine-2,5-dione 280
240
O 197
43
77 51 65
93
NH2 O
106
30
N
182 120
143152 168
212 224
3039
55 77 90 65
106
182 130
165
197
223
251 264
306
230
Tsuge, Ohtani and Watanabe
111 Polyamideimide; PAI CO
CO
N
O
NH
CO
CO
CO N
NH n
CO
b AI
AA
TIC
P CB I
LB
DA PI DN DE BF
0
EA
AN
10
OI
a
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Weight
Retention Index
Relative Intensity
LB I P CB DN DA DE
CO2 phenyl isocyanate phenol + aniline cyanobenzene p-aminophenol + dicyanobenzene m-phenylenediamine diphenyl ether
44 119 94; 93 103 109; 128 108 170
150 967 983 991 1271 1304 1419
18.4 0.3 9.4 10.9 6.6 7.7 1.9
PI
phthalimide
147
1474
4.4
BF
dibenzofuran
168
1547
0.5
EA
O
185
1776
4.6
223
2081
3.8
200
2140
14.3
CO NH CO O
NH2 CO
AN AA
phthalanil
N CO
H2 N
O
NH2
CO
OI AI a
N
OH
239
2443
17.6
N
NH2
238
2490
35.1
-
2971
5.9
330
3414
100.0
CO CO CO
unidentified CO
b
N CO
O
NH2
231
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
111
EGA thermogram
Averaged mass spectrum 94 66 44 100
200
300
400
500
48
600
700 ºC
programming rate: 20ºC/min
80 108
128 147 141
30 50
100
185
170
223
200
150
238 250 [m/z]
200
( m/z range : 29 - 600 amu )
DN : p-aminophenol (+dicyanobenzene)
P : phenol (+ aniline) 94
NH2
OH
109 H2 N
OH
+
+
66
80
N
39
53
55
29
N
77
29
119
DA : m-phenylenediamine
39
63
128
101
PI : phthalimide O
147
108
NH2
76
NH
104
80
NH2
91
65
74
29 38
EA : p-phenoxyaniline
218
AN : phthalanil 185
O
O
103
50 53
30 39
223
O
NH 2 179
N
108
O 51
39
80
65
129139
92
156 39
169
AA : p,p'-diamino(diphenyl ether) O
75
104 91
130 139
239
O
NH2 N
65
80 93
195 76
171 202 130 144156
39 50
182
AI : 2-(3-aminophenyl)isoindoline-1,3-dione H 2N
OH
O
108 39 53
152 166
OI : 2-(4-hydroxyphenyl)isoindoline-1,3-dione 200
H2N
76
50
75
167 182
210
330
O H2 N
N
130 140 154
b : 2-(4-(4-aminophenoxy)phenyl)isoindoline-1,3-dione 238
O
92 104
N O O
O 76 39 50 65
108
91 104 119 134
154 167 181
194
210
39
6576 92
130
165 183
210
238
273
301
232
Tsuge, Ohtani and Watanabe
112 Poly(p-phenylene terephthalamide); Kevlar CO
CONH
NH n
AB
CA
DA
NA
BN
AN CB
TIC
TN
DP
0
10
Peak Notation
Assignment of Main Peaks
AN
aniline + cyanobenzene
TN
p-tolunitrile
CH3
CN NC
DA
H2 N
DP
diphenyl
NA
p-cyanoaniline
BN
benzanilide
AB
4'-aminobenzanilide
CA
4-cyano-4'-aminobenzanilide
CONH
NC
Retention Index
Relative Intensity
93; 103
989
89.2
117
1117
2.7
128; 108
1269
58.3
154
1397
1.2
118
1457
19.6
197
1985
14.8
212
2390
100.0
237
2724
63.0
NH2
NH2
CONH
Molecular Weight
CN
+
p-dicyanobenzene + p-phenylenediamin
NC
30 [min]
20
NH2
CONH
NH2
[ Related References ] 1) Brown, J. R.; Power, A. J. Polym. Degrad. Stab. 1982, 4, 379. 2) Schulten, H. -R.; Plage, B.; Ohtani, H.; Tsuge, S. Angew. Makromol. Chem. 1987, 155, 1.
233
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
112
EGA thermogram
Averaged mass spectrum 103 108 44
100
200
300
400
500
80 50
600
700 ºC
programming rate: 20ºC/min
66
118 134
30 50
100
154
166
178
191
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
AN : aniline (+ cyanobenzene)
TN : p-tolunitrile 117
93
N
N
NH 2
+
66 39
76
50
39
104
30
DA : p-dicyanobenzene (+ p-phenylendiamin)
90 89
63
50
32
118
DP : diphenyl
108
H2N
154
NH2 128
+ N
N
80
53 29
101
75
39
3239 51 63
NA : p-cyanoaniline
76
108 102
128 139
199
BN : benzanilide 118
105
O
N
NH 2
220
N H 77
197
91 64
52
41
76
117
39
65
92
139 152 167 184
105
107
212
NH2
NH 2
O
237
N H
N H
218
CA : 4-cyano-4'-aminobenzanilide
AB : 4'-aminobenzanilide O
51
77 N 80 102
51 39
65
90
128134
154 167 182
222
39
53
75
130 134 153
179
207
263
234
Tsuge, Ohtani and Watanabe
113 Poly(m-phenylene isophthalamide); Nomex CO
CONH
NH n
AB
DA
CA CB AN
TIC LB
B
TN
BN
BA DN DP
0
PD
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
LB B AN CB
CO2 benzene aniline cyanobenzene
TN
m-tolunitrile
BA
benzoic acid
COOH
DN
m-dicyanobenzene
NC
Molecular Weight
Retention Index
Relative Intensity
44 78 93 103
150 661 983 990
30.2 7.4 8.7 21.9
117
1099
1.4
122
1181
17.9
128
1273
2.3
108
1307
46.5
154
1398
1.6
197
1986
6.1
212
2377
100.0
237
2695
18.3
CN CH3
DA
m-phenylenediamine
DP
diphenyl
BN
benzanilide
AB
3'-aminobenzanilide
CA
CN
H2 N
NH2
CONH
CONH
NH2
NC
CONH
3-cyano-3'-aminobenzanilide
NH2
[ Related References ] 1) Brown, J. R.; Power, A. J. Polym. Degrad. Stab. 1982, 4, 379. 2) Schulten, H. -R.; Plage, B.; Ohtani, H.; Tsuge, S. Angew. Makromol. Chem. 1987, 155, 1.
235
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
113
EGA thermogram
Averaged mass spectrum 108 80
44
100
103
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
122 66
139 147
30 50
100
169 179
194
150
212 250 [m/z]
200
( m/z range : 29 - 600 amu )
AN : aniline
CB : cyanobenzene 93
NH 2
103
N
66 39
76
52
30
39
78
50
104
75
DN : m-dicyanobenzene
BA : benzoic acid
128
105
O
OH
N
N
122 77
51 29
101 74
39
32
94
DA : m-phenylenediamine
37
50
76 75
108
DP : diphenyl 108
NH2
154
80
NH2 53
30 39
32
91
65
44 51 63
76
102 108
128 139
AB : 3'-aminobenzanilide
BN : benzanilide 105
105
O
O
212 N H
N H 77
39
51
77
197
65
92
139 152
167
39
184
51
92
134 128
237 N H
H N
NH 2 O
102
39 53
80 75
109
154 167 184 193
105
130
O
65
PD : N,N'-dibenzoyl-p-phenylenediamine
CA : 3-cyano-3'-aminobenzanilide N
NH2
77
134
208 164 182192
220
39
51
75
133
167 195 211
316 N H
O
287
236
Tsuge, Ohtani and Watanabe
114 Poly(p-phenylene/3,4-diphenylene ether terephthalamide) OC
CONH
NH
CONH
OC
O
NH n
C
G
PD AN
A
CB
E B
PC
D
F H
AP
TIC
0
10
Peak Notation
Assignment of Main Peaks
AN CB PC PD AP
aniline cyanobenzene benzoic acid p-phenylenediamine 3-aminophenol
A
O
B
CONH
30 [min]
20
NH 2
Molecular Weight
Retention Index
Relative Intensity
93 103 122 108 109
983 990 1182 1277 1291
20.6 43.4 50.3 58.9 11.6
185
1777
21.8
197
1987
13.2
200
2152
80.8
212
2394
100.0
237
2721
28.2
304
3230
54.0
304
3300
63.7
316
3551
50.9
NH2
C
H2N
D E F G H
O
CONH
CN
CONH
H2N
H2N
NH2
O
O
CONH
NH2 NHCO
NHCO
NHCO
237
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
114
EGA thermogram
Averaged mass spectrum 105
44
77
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
200
122
103
65
154 171 185
134
29 50
100
150
212 228 239 252 269
200
289 304 317 332
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
PD : p-phenylenediamine
PC : benzoic acid O
105
OH
108 122
H2N
NH2
77 80 51 74
39
29
53 94
A : p-phenoxyaniline
91
63
128 136
B : benzanilide 185
O
41
30
105
O
N H2 N H 197
77 156
108 65
51
39
80
169
92
130 141
51
39
C : m,p'-diaminodiphenyl ether
65
167
139
D : 4'-aminobenzanilide 200
NH2
105
212
N H2
O
H2 N
92
O N H 108 80
65 30
39 53
93
202
130 144156
51
183
30 39
80 102 75
304
O H 2N
77 130 145
225
260
310 295
39 51 65
91
127
154
199
226
298
H : N,N'-dibenzoyl-p-phenylenediamine 105
H 2N
304
O
H N
O
316
N H
O
127 154
202
N H
77
77 92
H N
O
105
65
154 167 182
105
G : N-(4-(3-aminophenoxy)phenyl)benzamide
3951
128134
237
N
53
90
NH 2
O N H
2941
65
F : N-(3-(4-aminophenoxy)phenyl)benzamide
E : 4-cyano-4'-aminobenzanilide 107
77
171
276
328
361
51 39 75 102
130
225
O
301
356
403
238
Tsuge, Ohtani and Watanabe
2.2.14 Polyesters 115 Poly(ethylene terephthalate); PET COOCH2CH2OCO n
F G
D C
LB
A PE2
BA
AC TIC
DP
B 0
PA
PB
E
PE1
10
Peak Notation
Assignment of Main Peaks
LB AC B A BA DP C D PA PB E F PE1 PE2 G H I
CO2 acetaldehyde benzene vinyl benzoate benzoic acid diphenyl divinyl terephthalate CH2=CHOCOC6H4COOCH=CH2 CH2=CHOCOC6H4COOH C6H5-C6H4COOCH=CH2 C6H5-C6H4COOH C6H5COOCH2CH2OCOC6H5 C6H5COOCH2CH2OCOC6H4COOCH=CH2 C6H5-C6H4COOCH2CH2OCOC6H5 HOCOC6H4COOCH2CH2OCOC6H4COOCH=CH2 CH2=CHOCOC6H4COOCH2CH2OCOC6H4COOCH=CH2 C6H5COOCH2CH2OCOC6H4COOCH2CH2OCOC6H5 C6H5(COOCH2CH2OCOC6H4)2COOCH=CH2
H
I 30 [min]
20
Molecular Weight 44 44 78 148 122 154 218 192 224 198 270 340 346 384 410 462 532
Retention Index 150 408 654 1143 1186 1398 1577 1622 1889 1914 2178 2636 3050 3052 3089 3753 4180
* C6H5 represents phenyl group ; C6H4 represents p-phenylene group [ Related References ] 1) Sugimura, Y.; Tsuge, S. J. Chromatogr. Sci. 1979, 17, 269. 2) Bednas, M. E.; Day, M.; Ho, K.; Sander, R.; Wiles, D. M. J. Appl. Polym. Sci. 1981, 26, 277. 3) Adams, E. R. J. Polym. Sci., Polym. Chem. Ed. 1982, 20, 119. 4) Vijayakumar, C. T.; Fink, J. K. Thermochim. Acta 1982, 59, 51. 5) Ohtani, H.; Kimura, T.; Tsuge, S. Anal. Sci. 1986, 2, 179. 6) Montaudo, G.; Puglisi, C.; Samperi, F. Polym. Degrad. Stab. 1993, 42, 13.
Relative Intensity 25.2 8.8 3.0 14.0 44.7 1.8 25.7 100.0 3.9 6.0 7.1 39.9 1.5 3.3 42.8 11.9 17.9
239
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
115
EGA thermogram
Averaged mass spectrum 149
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
65 44
105
77
50
121
103 50
166175
135
100
150
193 200
300 [m/z]
250
( m/z range : 29 - 600 amu )
AC : acetaldehyde
B : benzene 29
78
44
O
51
44
A : vinyl benzoate O
74
C : divinyl terephthalate 105
O
175
77
O
O
O
O 104 76
51 74
39
148
91
42
50
66
91
149
OH
O
O
105
93 104
O
77 175
132
192
O
297
51
75
O
O
O
39
118
148
227
178
G : ethan-1,2-diyl divinyl diterephthalate
F : 2-(benzoyloxy)ethyl vinyl terephthalate
367
O
O
O
O
O
O
121 76
218
O
65 39 50
132 147
E : ethan-1,2-diyldibenzoate
D : 4-(vinyloxycarbonyl) benzoic acid O
119
O
O
O
O
O
O 105 77 103 132 39 51 75 121
325
149 175 191
267
300
297
268
296 337
370
O
O O
77 51 75 103
105
O
O
191 219
vinyl terephthalate
O
105
162
I : 2-(4-((2-(benzoyloxy)ethoxy)carbonyl)benzoyloxy)ethyl
H : bis(2-(benzoyloxy)ethyl) terephthalate O
104 76 132 50 75 103 39
O
O
O
O
O
O O
O
O
O
O
149 132
207
300 342
419
462
77103 5175
149
489 240 269 297
367
459
240
Tsuge, Ohtani and Watanabe
116 Poly(butylene terephthalate); PBT COOCH2CH2CH2CH2OCO
n
C
D
C4
A
F
H
BA
TIC
DP 0
E
10
Peak Notation C4 BA A DP D C E F G H
G 30 [min]
20
Assignment of Main Peaks 1,3-butadiene benzoic acid C6H5COOH C6H5COOCH2CH2CH=CH2 diphenyl C6H5-C6H5 CH2=CHCH2CH2OCOC6H4COOH CH2=CHCH2CH2OCOC6H4COOCH2CH2CH=CH2 C6H5COO(CH2)4OCOC6H5 C6H5COO(CH2)4OCOC6H4COOCH2CH2CH=CH2 CH2=CHCH2CH2OCOC6H4COO(CH2)4OCOC6H4COOH CH2=CHCH2CH2OCOC6H4COO(CH2)4OCOC6H4COOCH2CH2CH=CH2
Molecular Weight 54 122 176 154 220 274 298 396 440 494
* C6H5 represents phenyl group ; C6H4 represents p-phenylene group [ Related References ] 1) Sugimura, Y.; Tsuge, S. J. Chromatogr. Sci. 1979, 17, 269. 2) Lum, B. M. J. Polym. Sci., Polym. Chem. Ed. 1979, 17, 203 3) Adams, E. R. J. Polym. Sci., Polym. Chem. Ed. 1982, 20, 119. 4) Vijayakumar, C. T.; Fink, J. K. Thermochim. Acta 1982, 59, 51. 5) Ohtani, H.; Kimura, T.; Tsuge, S. Anal. Sci. 1986, 2, 179. 6) Montaudo, G.; Puglisi, C.; Samperi, F. Polym. Degrad. Stab. 1993, 42, 13. 7) Sato, H. ; Kondo, K. ; Tsuge, S. ; Ohtani. H. ; Sato, N. Polym. Degrad. Stab. 1998, 62, 41. 8) Koshiduka, T.; Ohkawa, T.; Takeda, K. Polym. Degrad. Stab. 2003, 79, 1.
Retention Index 395 1185 1362 1396 1848 2045 2441 3154 3649 3838
Relative Intensity 21.0 21.0 9.3 0.6 100.0 41.1 1.2 12.0 3.0 33.3
241
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
116
EGA thermogram
Averaged mass spectrum 149
100
54
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
65 39
203
121
76
104
93 50
132
167174
100
150
200
250
300
[m/z]
( m/z range : 29 - 600 amu )
BA : benzoic acid
C4 : 1,3-butadiene 54
O
39
105
OH
122 77
51 29
A : but-3-enyl benzoate
74
39
29
94
DP : diphenyl 105
O
154
O 77
54 29 39
122 135
74
105 102
128139
220
C : dibut-3-enyl terephthalate
D : 4-((but-3-enyloxy)carbonyl)benzoic acid O
76
39 51 63
176
203
O
149 O
O
O
OH
149 54
O 65
29
39
54 121
76
93 104
166 179
O
O
274
O O
325 O
O
O
O 105
O
54 149 203 77 71 103 121 176 132 162 193 220
54 71
176 193 149 122 135 166 203 223
93
256
298
G : 4-((4-(4-((but-3-enyloxy)carbonyl)benzoyloxy)butoxy) O
39 29
369 O
7176 121 180 103 162
O
O
O
O
149 O
O
OH
54
324 370
149
O
203
440 238
O
O
O
104
396
369
O
O
O
342
H : dibut-3-enyl'-butane-1,4-diyl diterephthalate
carbonyl)benzoic acid
29 41
220
F : 4-(benzoyloxy)butyl but-3-enyl terephthalate
77
132
167175
O
105
54
104 121 93 132
65 76
29 39
203 220
E : butane-1,4-diyl dibenzoate
29 41
O
542
29
108 176 132 162 201 39 65 93
370 353
423 494
242
Tsuge, Ohtani and Watanabe
117 Poly(ethylene naphthalate); PEN CH2CH2OCO COO n
BN
A
CN N
B LB AC
C
D E
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB AC N
CO2 acetaldehyde naphthalene
BN CN A B C D E
30 [min]
20
Molecular Weight
Retention Index
Relative Intensity
44 44 128
150 408 1200
24.0 15.1 21.2
COOCH CH2
198
1708
30.4
COOH
172
1741
100.0
268
2178
32.4
254 254
2542 2702
10.1 9.3
370
3468
16.7
440
3926
21.3
H2C CHOCO COOCH CH2
1,1‘-binaphthalene 2,2‘-binaphthalene COOCH2CH2OCO
COOCH2CH2OCO COOCH CH2
243
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
117
EGA thermogram
Averaged mass spectrum
44
100
127
155
29 63
51
77
101
50
115
142
100
300
400
500
600
700 ºC
programming rate: 20ºC/min
242 254
225
185 150
200
199
172
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
N : naphthalene
AC : acetaldehyde 29
128
O 44
51
39
BN : vinyl-2-naphthoate
64
102
77
CN : 2-naphthalenecarboxylic acid 155
O
172
O
127
O
OH
77 75
42 51
198
101 115
63 4551
141
A : divinyl naphthalene-2,6-dicarboxylate
127
77
101 115
155
144
174
B : 1,1'-binaphthalene
225
254
O O O 154
O 126 63 42 50
126
77 91 115
140
169182 197
268
39 51
C : 2,2'-binaphthalene
113 75 87 101
139
163
187
239
213
D : ethan-1,2-diyl di-2-naphthoate 254
155
O O
127
O O
199
51
113 75 88 101
126 139150 163
51 7577 101115
187 200 213 226 239
E : 2-(2-(2-naphthoyloxy)ethyl) 6-vinylnaphthalene -2,6-dicarboxylate 397
O O
O O
O O
127 155 199 225 252 281 51 77 91 115 140 171
325
367
398
440
172 185
370
252 281
351
244
Tsuge, Ohtani and Watanabe
118 Poly(p-hydroxybenzoic acid); type A O
O
CO
CO
O
CO n
BP
DB
PP BF PB
P TIC
BA
B
XO
DP
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
B P
benzene phenol
BA
benzoic acid
DP
diphenyl
Molecular Weight
COOH
Retention Index
Relative Intensity
78 94
655 984
6.2 34.0
122
1172
6.8
154
1398
1.8
168
1546
0.7
198
1678
1.8
170
1731
11.9
196
1901
1.8
186
2061
100.0
290
2891
46.8
O
BF
dibenzofuran
PB
phenyl benzoate
PP
p-phenylphenol
COO
OH CO
XO
xanthone O
BP DB
diphenol COO
HO
OH
OH
[ Related References ] 1) Crossland, B.; Knight, G. J.; Wright, W. W. Br. Polym. J. 1986, 18, 371. 2) Sueoka, K.; Nagata, M.; Ohtani, H.; Nagai, N.; Tsuge, S. J. Polym. Sci. Part A 1991, 29, 1903. 3) Ohtani, H.; Fujii, R.; Tsuge, S. J. High Res. Chromatogr. 1991, 14, 388. 4) Ishida, Y.; Ohtani, H.; Tsuge, S. J. Anal. Appl. Pyrolysis. 1995, 33, 167.
245
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
118
EGA thermogram
Averaged mass spectrum 186 94
44
100
200
300
400
500
121
51
700 ºC
157 139
31 50
600
programming rate: 20ºC/min
105
66 77
170
100
196 212 225
150
200
290
246 262 250
350 [m/z]
300
( m/z range : 29 - 600 amu )
P : phenol
BA : benzoic acid
OH
94
O
OH
105 122 77
66
51
39 55
29
74
39
77
DP : diphenyl
94
BF : dibenzofuran 154
168
O
139 39
51 63
76
102 115 128 139
39
51
69
84
113 121
93
159
PP : p-phenylphenol
PB : phenyl benzoate 105
170
OH
O O
77
39
51
65
94
121
198
139
XO : xanthone
39
127
152
186
196 HO
OH
168
O
139
44 50
63
84 92
114 121
121 184
DB : 4'-hydroxybiphenyl-4-yl benzoate 105
O O
OH 290
77
39
102
BP : diphenol
O
51
141
115
85
51 63
75 102
128 157 185 139
65 77 29 39 51
157
93 115
139
169
188
214
246
Tsuge, Ohtani and Watanabe
119 Poly(p-hydroxybenzoic acid); type B O CO
O
CO n
P
HP
NO
HP’
a
A NP XO
HA DE
TIC
0
10
Peak Notation
Assignment of Main Peaks
P HA DE
phenol p-hydroxybenzaldehyde diphenyl ether
A
p-hydroxybenzoic acid
NO
30 [min]
20
HO
Molecular Weight
COOH
(monomer)
Relative Intensity
94 122 170
983 1364 1419
100.0 6.8 4.1
138
1518
44.8
144
1537
50.6
196
1901
4.7
220
2011
3.5
214
2061
63.4
214 ? 264 264
2155 2703 2718
26.3 22.8 19.4
OH
β -naphthol CO
XO
Retention Index
xanthone O
NP
2-naphthyl phenyl ether
HP
(p-hydroxyphenyl)benzoic acid
HP’
unidentified (C13H10O3?) Phenyl-1-hydroxy-2-naphthoate Phenyl-1-hydroxy-4-naphthoate
a
O
HO
COO
[ Related Reference ] 1) Ohtani, H.; Fujii, R.; Tsuge, S. J. High Res. Chromatogr. 1991, 14, 388.
247
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
119
EGA thermogram
Averaged mass spectrum 94
66
121
44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
144
115 50
77
31
157 170
50
100
186 197
150
220
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
HA : p-hydroxybenzaldehyde
P : phenol OH
94
121
O
39
OH 55
29
93
65
66 39
50
79
76
A : p-hydroxybenzoic acid
DE : diphenyl ether 170
O
121
O HO
138
OH
141 77
51 39
65
94
115
53
31
NO : β-naphthol
93
65
39 155
128
81
110
149
XO : xanthone 144
OH
O
196
115 168
O 39
89 90
63 57
126
84 92
63
39 50
170
146
139 114
184
129
HP : (p-hydroxyphenyl)benzoic acid
NP : 2-naphthyl phenyl ether 220
121
O HO
O
O 191
77 39 51 63
101
115 127 144152
165
204
39
178
121
157
186
214
65
171
O
214
53
93 77
a : phenyl-1-hydroxy-2-naphthoate
HP' : unidentified
39
65 51
O HO 143
93 77
107
197 139 157168 185
216
39 51 65
89 94
115 126
264 245
248
Tsuge, Ohtani and Watanabe
120 Polyarylate; PAR O
C(CH3)2
OCO
BA
TP
CO n
IP’
P ID
PC
VP EP IP BP DP A
TIC
PB
IB
MB TE
PA
B 0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
B P PC EP A VP IP BP IP’
benzene phenol p-cresol p-ethylphenol benzoic acid p-vinylphenol p-isopropylphenol p-tert-butylphenol p-isopropenylphenol
DP
diphenyl
PB
phenyl benzoate
Molecular Weight
Retention Index
Relative Intensity
78 94 108 122 122 120 136 150 134
664 985 1078 1169 1176 1220 1231 1298 1307
10.2 49.3 21.1 16.8 9.9 14.3 11.5 7.0 57.1
154
1398
6.5
198
1678
15.1
210
1759
26.1
212
1799
6.6
212
1881
6.4
238
2030
18.5
228
2202
71.8
C
332 ?
3043
100.0
OCO
436
3891
24.7
COOH
COO C
ID
4-isopropenyl(diphenyl ether)
O
C C
MB
p-tolyl benzoate
COO
C
C
PA IB
C
OH
C
C
COO
C C
C
BA
C
HO
bisphenol A
OH
C
TP
OCO
COO C
TE
COO
C C
* bonding hydrogen is omitted
249
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
120
EGA thermogram
Averaged mass spectrum 77
105 119
94
213
65
39
100
134
51
300
400
500
600
700 ºC
programming rate: 20ºC/min
152165 183195
31 0
200
50
100
150
200
228 238
332 250
300
350
[m/z]
400
( m/z range : 29 - 600 amu )
PC : p-cresol
P : phenol OH
94
OH
107
66
77
39 55
29
51
39
79
90
63
VP : p-vinylphenol
EP : p-ethylphenol 107
OH
OH
120
91
122 77 39
51
39
91
65
IP : p-isopropylphenol
65
51
89
105
PB : phenyl benzoate 121
OH
105
O 77
136 91
77 39
51
65
O
51
39
107
65
93
198
141
IB : 4-(prop-1-en-2-yl)phenyl benzoate
ID : 4-isopropenyl(diphenyl ether) 210
105
O
O
O 195 77 91 39 51 65
115 119
77
165 181 141152
39
51
238 63
103
119 133
165 181
TP : phenyl p-tolyl terephthalate
BA : bisphenol A
105
213
HO
O
OH
O
O 228 55 65 77
91 107
135 152 165 181 198
230
39
51 65 91 119
O 317 332
77
119 39
210
213 228
436
250
Tsuge, Ohtani and Watanabe
121 Poly(1,4-cyclohexanedimethylene terephthalate) H2C
CH2 OOC
COO
n
f
DM b a e c X BA LB TIC
B
d
T
0
10
Peak Notation
Assignment of Main Peaks
LB B T
CO2 benzene toluene
30 [min]
20
Molecular Weight
a CH 2
Retention Index
Relative Intensity
44 78 92
150 662 768
30.1 13.4 5.3
108
813
47.6
108
855
58.3
DM
H2C
X
p-xylene
106
873
33.2
BA
HOOC
122
1199
100.0
b c d e f
unidentified unidentified unidentified unidentified unidentified
-
1851 1877 2290 3138 3165
42.5 25.4 3.3 45.6 87.8
( including the form of
CH2
CH2
)
251
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
121
EGA thermogram
Averaged mass spectrum 93 108 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
149
79
65 29 39
121
51 50
166
100
257
150
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
DM : 1,4-dimethylenecyclohexane
a : bicyclo[2.2.2]octane
93
93 108
79
108 77
39 39
67
53
65
51
29
29
X : p-xylene
BA : benzoic acid 91
O
105
OH
122 77
106 51 39
51
65
77 29
b : unidentified
74
39
94
c : unidentified 105
93
93
108
77 77
29
41
51
67
51 29 41
123
67
123
f : unidentified
e : unidentified 108
108 93
93 149
79
257 149
79 29 41 55
67
230
121 132
167 189
229
258
67 29 41 55
121 132
257 189
229
258
252
Tsuge, Ohtani and Watanabe
122 Poly(lactic acid); PLA CH3 OCHCO
n
AA
TIC
PD
L2 L1
Acr
0
10
Peak Notation
Assignment of Main Peaks
AA PD Acr
acetaldehyde 2,3-pentadione acrylic acid
30 [min]
20
Molecular Weight
Retention Index
Relative Intensity
44 100 72
411 689 714
100.0 1.3 1.8
(meso-form)
144
1133
1.2
(DL-form)
144
1172
6.1
O
L1
* O
O
* O O
L2
* O
O
* O
[ Related References ] 1) Kopinke, F.-D.; Remmler, M.; Mackenzie, K. Moeder, M.; Wachsen, O. Polym. Degrad. Stab. 1996, 53, 329. 2) Kopinke, F.-D.; Mackenzie, K. J. Anal. Appl. Pyrolysis 1997, 40-41, 43. 3) Khabbaz, F.; Karlsson, S.; Albertsson, A.-C. J. Appl. Polym. Sic. 2000, 78, 2369. 4) Aoyagi, Y.; Yamashita, K.; Doi, Y. Polym. Degrad. Stab. 2002, 76, 53. 5) Fan, Y.; Nishida, H.; Hoshihara, S.; Shirai, Y.; Tokiwa, Y.; Endo, T. Polym. Degrad. Stab. 2003, 79, 547. 6) Fan, Y.; Nishida, H.; Shirai, Y.; Endo, T. Polym. Degrad. Stab. 2003, 80, 503. 7) Nishida, H.; Mori, T.; Hoshihara, S.; Fan, Y.; Shirai, Y.; Endo, T. Polym. Degrad. Stab. 2003, 81, 515. 8) Fan, Y.; Nishida, H.; Shirai, Y.; Tokiwa, Y.; Endo, T. Polym. Degrad. Stab. 2004, 86, 197. 9) Abe, H.; Takahashi, N.; Kim, K. J.; Mochizuki, M.; Doi, Y. Biomacromolecules 2004, 5, 1606. 10) Fan, Y.; Nishida, H.; Mori, T.; Shirai, Y.; Endo, T. Polymer 2004, 45, 1197. 11) Abe, H. Macromol. Biosci. 2006, 6, 469.
253
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
122
EGA thermogram
Averaged mass spectrum 56
100
200
300
400
500
45
600
700 ºC
programming rate: 20ºC/min
29 128 73 83 100 111 144 154 0
50
100
200
150
272
200
250
344 300
350
450 [m/z]
400
( m/z range : 29 - 600 amu )
AA : acetaldehyde
PD : 2,3-pentadione 29
44
29
43
O
O 57
O 100
74
L1 : 3,6-dimethyl-1,4-dioxane-2,5-dion (meso form)
Acr : acrylic acid 72
OH
O
55
56
O
*
O
45
*
O 45
29 29
L2 : 3,6-dimethyl-1,4-dioxane-2,5-dion (DL form) 56
O O
*
*
O
45
O
29 70
1 44
O
254
Tsuge, Ohtani and Watanabe
123 Poly( -caprolactone); PCL (CH2)5COO
n
CL1
F CL2 TIC
A
B
C
D
E0
CL3 E1
E2 CL4
0
10
Peak Notation
Assignment of Main Peaks
A B C D
pentene unidentified cyclopentanone CH2=CH(CH2)3COOH
CL1
ε-caprolactone
E0 F CL2 E1 CL3 E2 CL4
30 [min]
20
Retention Index
Relative Intensity
70 96 84 114
493 699 788 998
1.8 3.5 4.6 16.7
(CH2)5COO
114
1160
100.0
CH2=CH(CH2)2COO(CH2)4CH3 CH2=CH(CH2)3COO(CH2)5COOH
170 228
1278 1742
3.8 23.0
228
1788
7.2
270
2053
5.1
342
2602
8.2
370
2825
5.9
456
3401
5.8
(CH2)5COO
2
CH2=CH(CH2)2COO(CH2)4COO(CH2)4CH3
(CH2)5COO
3
CH2=CH(CH2)2COO[(CH2)4COO]2(CH2)4CH3
(CH2)5COO
4
Molecular Weight
[ Related References ] 1) Aoyagi, Y.; Yamashita, K.; Doi, Y. Polym. Degrad. Stab. 2002, 76, 53. 2) Abe, H.; Takahashi, N.; Kim, K. J.; Mochizuki, M.; Doi, Y. Biomacromolecules 2004, 5, 1480. 3) Abe, H. Macromol. Biosci. 2006, 6, 469.
255
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
123
EGA thermogram
Averaged mass spectrum 55
42
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
84
29
115
70
97
50
229
100
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
C : cyclopentanone
D : 5-hexenoic acid 60
55
O
O OH
41 84
41
68 29
29
69
96
95
CL1 : ε -caprolactone
114
81
E0 : pentyl pent-4-enoate
55
43
O
42
O 55
O
O
84 29
114
97
68 29 114
70
81
97
CL2 : 1,8-dioxacyclotetradecane-2,9-dione (ε -caprolactone dimer)
F : 6-(5-hexenoyloxy)hexanoic acid 69
115 97
41 55
O
OH
O
55
O 41 29
128 133
81
O
O
115
O 97
69
29 156 174
O
84
210
128 141 156 169
210
CL3 : trimer of ε -caprolactone
E1 : 5-oxo-5-(pentyloxy)pentyl pent-4-enoate 115
115 O
O O
O O
O
41 55 69 41 29
81
128 142 156 169
185
O
O
97 55
E2 : 5-oxo-5-(5-oxo-5-(pentyloxy)pentyloxy)
97
69
29
203
O O
84
128
156
185 210 230
324
CL4 : tetramer of ε-caprolactone
pentyl pent-4-enoate
115
115
O O O
O
O
O
O O
O
O
O
97 41 55 69 29
84
128
169
185
55 69 41 211
244
283
324
29
O O
97 84
O
128
169
229
283
324
438
256
Tsuge, Ohtani and Watanabe
124 Poly(butylene succinate / adipate); PBSA O(CH2 )4OCO(CH2 )2 CO
O(CH2)4OCO(CH2 )4CO
n
S4
THF S3 SS2 B
CP BD
TIC
SA2 SS1 SA1
A4 H
San
P1
S1 S2 P2
0
A3
S5
A1 V2 A2
PS
A5
10
Peak Notation
Assignment of Main Peaks
B THF CP P1 BD
1,3-butadiene tetrahydrofuran cyclopentanone CH3CH2COO(CH2)2CH=CH2 1,4-butanediol O
O
S2 V2 H S3 A1 A2
Molecular Weight
Retention Index
Relative Intensity
54 72 84 128 90
395 621 788 890 947
64.9 97.9 45.9 6.6 35.1
100
1034
33.7
146 172
1174 1340
10.0 24.9
172
1354
12.5
174 168 226 200
1360 1370 1526 1531
4.5 19.6 46.4 12.7
200
1566
4.6
254 244 272 262 318 290
1733 1817 2026 2114 2320 2330
20.4 100.0 42.3 28.5 9.7 8.2
344
2580
26.8
O
San P2 S1
30 [min]
20
CH3CH2COO(CH2)4OH HOOC(CH2)2COO(CH2)2CH=CH2 OCO(CH2)2COO(CH2)4 CH3(CH2)3COO(CH2)4OH OCN(CH2)6NCO CH2=CH(CH2)2OOC(CH2)2COO(CH2)2CH=CH2 HOOC(CH2)4COO(CH2)2CH=CH2 OCO(CH2)4COO(CH2)4
SS1
CH2=CH(CH2)2OCO(CH2)4COO(CH2)2CH=CH2 CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OH CH2=CH(CH2)2OCO(CH2)4COO(CH2)4OH HO(CH2)4OCO(CH2)2COO(CH2)4OH CH3CH2COO(CH2)4OCO(CH2)2COO(CH2)4OH HO(CH2)4OCO(CH2)4COO(CH2)4OH OCO(CH2)2COO(CH2)4OCO(CH2)2COO(CH2)4
SS2
CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OCO(CH2)2COO(CH2)2CH=CH2
398
OCO(CH2)2COO(CH2)4OCO(CH2)4COO(CH2)4
372
2656 2862
26.0
CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OCO(CH2)4COO(CH2)2CH=CH2
426
2966
42.8
A3 S4 A4 S5 PS A5
SA1 SA2
[ Related References ] 1) Plage, B.; Schulten, H.-R. J. Anal. Appl. Pyrolysis 1989, 15, 197 2) Plage, B.; Schulten, H.-R. Macromolecules 1990, 23, 2642. 3) Sato, H.; Furuhashi, M.; Yang, D.; Ohtani, H.; Tsuge, S.; Okada, M.; Tsunoda, K.; Aoi, K. Polym. Degrad. Stab. 2001, 73, 327.
42.6
257
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
124
EGA thermogram
Averaged mass spectrum 55
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
42
101
73
29
129
111
84 50
142
100
155 150
173 183
201
227
255
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
B : 1,3-butadiene
THF : tetrahydrofuran 42
54
39
O 72
29 29
53
CP : cyclopentanone
S3 : 3-dibutenyl succinate 55
55
O
O O
O
84
O 41
101
29
29 39
69
S4 : 3-butenyl 4-hydroxybutyl succinate
101
125
O
55
O
O
O
OH
O
73
155
108
A4 : 3-butenyl 4-hydroxybutyl adipate
O
55
73 80
OH
129 O
O 111
183 71
155
29 43
89
119
173 174
142
213
S5 : bis(4-hydroxybuthyl) succinate 73
55 O
O
71
20 173
119 31 43 87
42
55
O
O O
101 29 39
73 80
108 119
55
O
O
288
326
O
O O
O
73
227
101 155173 227
173 174
254
O
O O
O
155
226
butyl adipate
O
O
214
SA2 : 3-butenyl 4-(4-(3-butenyloxy)-4-oxobutanoyloxy)
O
O
O
O
154 114 142
87
214 231
SS2 : dibut-3-enyl '-butane-1,4-diyl disuccinate
O
128
29
142 160 146
116
O
O
O
55
241
O
101
OH
O 101
201 202
141 154 170
SS1 : 1,6,11,16-tetraoxacycloicosane-2,5,12,15-tetraone
O HO
101
83
29 43
213
327
29 42
80
119 108 142
174 214
273
327 345
385
258
Tsuge, Ohtani and Watanabe
125 Poly(3-hydroxybutylic acid); PHB H
OCHCH2C CH3
O
OH n
LB
D F C B
TIC
A 0
10
Peak Notation
Assignment of Main Peaks
LB F A B C D
CO2, propylene etc. furan acetic acid CH2=C(CH3)COOH CH3CH=CHCOOH (cis) CH3CH=CHCOOH (trans)
30 [min]
20
Molecular Weight
Retention Index
44, 42 68 60 86 86 86
295 555 605 792 853 927
Relative Intensity 23.0 8.6 0.6 16.5 18.1 100.0
[ Related References ] 1) Watt, B. E.; Morgen, S. L. J. Anal. Appl. Pyrolysis 1991, 19, 237. 2) Lehrle, R. S.; Williams, R. J. Macromolecules 1994, 27, 3782. 3) Lehrle, R.; Williams, R.; French, C.; Hammond, T. Macromolecules 1995, 28, 4408. 4) Kopinke, F.-D.; Remmler, M.; Mackenzie, K. Polym. Degrad. Stab. 1996, 52, 25 5) Kopinke, F.-D.; Mackenzie, K. J. Anal. Appl. Pyrolysis 1997, 40-41, 43. 6) Aoyagi, Y.; Yamashita, K.; Doi, Y. Polym. Degrad. Stab. 2002, 76, 53. 7) Li, S.-D.; He, J.-D.; Yu, P. H.; Cheung, M. K. J. Appl. Polym. Sci. 2003, 89, 1530. 8) Gonzalez, A.; Irusta, L.; Fernandez-Berridi, M. J.; Iriarte, M.; Iruin, J. J. Polym. Degrad. Stab. 2005, 87, 347. 9) Abe, H. Macromol. Biosci. 2006, 6, 469.
259
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
125
EGA thermogram
Averaged mass spectrum 69
100
41
200
300
400
500
103
29
600
700 ºC
programming rate: 20ºC/min
86
57
154
113
50
100
171
150
200
[m/z]
( m/z range : 29 - 600 amu )
LB : propylene
F : furan 41
39
O
50
29
29
68
B : methacrylic acid
A : acetic acid 43
O
41
OH
60
86
OH
58
O 29 67
69
29
82
C : 2-butenoic acid (cis)
95
D : 2-butenoic acid (trans) 86
OH 39
O
68
86
O OH
39 68
29
57
29
57
260
Tsuge, Ohtani and Watanabe
126 Poly(butylene succinate / carbonate); PEC O(CH2)4OCO(CH2)2CO
O(CH2)4
OCO
n
S4 SS2 S3
B LB
SA2 S5
THF BO BD San
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB B THF BO BD
CO2 1,3-butadiene tetrahydrofuran CH2=CH(CH2)2OH 1,4-butanediol O
O
Molecular Weight
Retention Index
Relative Intensity
44 54 72 72 90
150 395 617 625 947
36.6 39.2 55.3 39.1 30.2
100
1021
39.6
226 244 262 398 426
1516 1818 2116 2657 2969
50.2 100.0 41.0 62.6 75.3
O
San S3 S4 S5 SS2 SA2
30 [min]
20
CH2=CH(CH2)2OOC(CH2)2COO(CH2)2CH=CH2 CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OH HO(CH2)4OCO(CH2)2COO(CH2)4OH CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OCO(CH2)2COO(CH2)2CH=CH2 CH2=CH(CH2)2OCO(CH2)2COO(CH2)4OCO(CH2)4COO(CH2)2CH=CH2
261
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
126
EGA thermogram
Averaged mass spectrum 55
100
73
42
200
300
400
500
101
29 108 119
89 50
600
700 ºC
programming rate: 20ºC/min
142
100
155
174
227
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
THF : tetrahydrofuran
B : 1,3-butadiene
42
54
39
O 72
29 29
53
BO : 3-buten-1-ol
BD : 1,4-butanediol 42
42
OH
OH
HO
31 31
71
57 57
72
S3 : 3-dibutenyl succinate
San : succinic anhydride 56
O
55
O
O
O
O
O O 101 29
42
29 39
100
S4 : 3-butenyl 4-hydroxybutyl succinate
73 80
73 O
73
89
119
119 31 43 87
213
SS2 : dibut-3-enyl '-butane-1,4-diyl disuccinate 55
O O
101
29 39
73 80
108 119
55
O
73
O
O O
O
227
101 155
173 227
173 174
214 231
191
O
O O
O
155
142 160 146
-4-oxobutanoyloxy)butyl adipate
O
O
116
SA2 : 3-butenyl 4-(4-(3-butenyloxy)
O
O O
OH
O
55
173 174
142
O
O
101
O
155 29 43
O HO
OH
O
101
125
S5 : bis(4-hydroxybutyl) succinate
O
55
155
108
213
243
273
327
29 42
80
119 108 142
174
214
245 273
345
385
262
Tsuge, Ohtani and Watanabe
2.2.15 The other engineering plastics with phenylene skeletons 127 Polycarbonate(melt method); MM-PC H
O
C(CH3)2
OCO
n
BA
PC
TIC
P
VP EP IP
PA ID
IP’
0
MA
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Weight
P PC EP VP IP IP’
phenol p-cresol p-ethylphenol p-vinylphenol p-isopropylphenol p-isopropenylphenol
ID
4-isopropenyl(diphenyl ether)
Retention Index
Relative Intensity
94 108 122 120 136 134
982 1077 1169 1220 1230 1305
6.3 14.0 7.0 5.8 1.5 5.7
210
1758
0.3
212
1881
4.0
226
1981
3.3
228
2200
100.0
C O
C
PA MA
C
C C C C
OH C OH C
C
BA
bisphenol A
C
HO
C
OH
C
* bonding hydrogen is omitted [ Related References ] 1) Lee, L. –H. J. Polym. Sci., Part A 1961, 2, 2859. 2) Tsuge, S.; Okumoto, T.; Sugimura, Y.; Takeuchi, T. J. Chromatogr. Sci. 1969, 7, 253. 3) Foti, S.; Giuffrida, M.; Maravigna, P.; Montaudo, G. J. Polym. Sci., Polym. Chem. Ed. 1983, 21, 1567. 4) Ito, Y.; Ogasawara, H.; Ishida, Y.; Tsuge, S.; Ohtani, H.; Polym. J. 1996, 28, 1090.
263
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
127
EGA thermogram
Averaged mass spectrum
100
200
300
400
500
213 65
39
91
77
51
31
700 ºC
119
107
134
50
600
programming rate: 20ºC/min
100
152
169
228
197
183
15 0
200
250 [m/z]
( m/z range : 29 - 600 amu )
PC : p-cresol
P : phenol 94
OH
107
OH
66
77
39 55
39
76
EP : p-ethylphenol
51
90
63
VP : p-vinylphenol 107
OH
120
OH
91
122 77 39
51
39
91
65
IP : p-isopropylphenol
51
65 89
105
IP' : p-isopropenylphenol 121
OH
134
OH 119
136 39
51
65
77
91
91 39
107
51
65
77
107
PA : p-hydroxy-2,2-diphenylpropane
ID : 4-isopropenyl(diphenyl ether) 210
197
O
OH
212
195 77 91 39 51 65
115
77 39 51 65
128 141152 165 182
MA : p-hydroxy-3-methyl-2,2-diphenylpropane
103 107119 135 152 165 182
BA : bisphenol A
211
213
OH
HO OH
228
226 91 39 51 65 77
119 135 152 165 181 196
39
119 91 107 135 152 165 181 197 55 65 77
264
Tsuge, Ohtani and Watanabe
128 Polycarbonate(solvent method); SM-PC (CH3)3C
OCO
O
C(CH3)2
OCO
O
n
C(CH3)3
BA
PC TIC
P
EP IP’ VP
BP IP
0
ID
PA MA
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
P PC EP VP IP BP IP’
phenol p-cresol p-ethylphenol p-vinylphenol p-isopropylphenol p-tert-butylphenol p-isopropenylphenol
ID
4-isopropenyl(diphenyl ether)
Molecular Weight
Retention Index
Relative Intensity
94 108 122 120 136 150 134
985 1079 1169 1219 1229 1299 1307
7.6 19.7 10.7 7.9 2.4 6.8 8.6
210
1761
0.4
212
1885
5.2
226
1985
3.7
228
2207
100.0
C O
C
PA MA
C
C C C C
OH C OH C
C
BA
bisphenol A
C
HO
C
OH
C
* bonding hydrogen is omitted [ Related References ] 1) Lee, L. –H. J. Polym. Sci., Part A 1961, 2, 2859. 2) Tsuge, S.; Okumoto, T.; Sugimura, Y.; Takeuchi, T. J. Chromatogr. Sci. 1969, 7, 253. 3) Foti, S.; Giuffrida, M.; Maravigna, P.; Montaudo, G. J. Polym. Sci., Polym. Chem. Ed. 1983, 21, 1567. 4) Ito, Y.; Ogasawara, H.; Ishida, Y.; Tsuge, S.; Ohtani, H.; Polym. J. 1996, 28, 1090.
265
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
128
EGA thermogram
Averaged mass spectrum 213
100
91 65 77
39
300
400
500
600
700 ºC
programming rate: 20ºC/min
228
51
134
50
200
107 119
100
152 169183197 150
200
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
PC : p-cresol
P : phenol 94
OH
107
OH
66
77
39 55
29
29
79
EP : p-ethylphenol
51
39
90
63
VP : p-vinylphenol 107
OH
120
OH
91 122 77 29
39
51
OH
51
89
105
BP : p-tert-butylphenol 121
29
51
29
IP : p-isopropylphenol
39
65
39
91
65
65
77
135
OH
107
136
91
150 41 51 29
107
65 77
95
119
PA : p-hydroxy-2,2-diphenylpropane
IP' : p-isopropenylphenol 134
OH
197
OH
119
91 29
39
51
65
77
212 105
77 39 51 65
MA : p-hydroxy-3-methyl-2,2-diphenylpropane
103 119 135 152 165 182 115
BA : bisphenol A 213
211
HO
OH
OH
226 29 39 51 65 77
91
119 135 152 165 181 196
29 39
119 91 107 135 152 165 181 197 55 65 77
228 230
266
Tsuge, Ohtani and Watanabe
129 Bisphenol Z polycarbonate O
OCO n
E
MP B EP A
VP PP CP CP’
Ph
C D
TIC
X 0
10
Peak Notation
Assignment of Main Peaks
X Ph MP EP VP CP PP CP’
p-xylene phenol p-cresol p-ethylphenol p-vinylphenol p-cyclohexylphenol p-phenylphenol p-cyclohexenylphenol
A
HO
B
HO
30 [min]
20
Molecular Weight
Retention Index
Relative Intensity
106 94 108 122 120 176 170 174
879 984 1079 1170 1221 1650 1730 1736
1.3 35.4 100.0 67.6 40.6 12.9 33.9 14.3
CH2
OH
200
2085
48.9
CH
OH
214
2143
80.7
OH
212
2191
24.8
OH
228
2207
19.1
OH
268
2654
95.7
CH 3
C
HO
C CH 2 CH 3
D
HO
C CH 3
E
HO
267
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
129
EGA thermogram
Averaged mass spectrum 107
100
200
300
400
500
77 51
91
133
65
170 183
148
29 0
600
700 ºC
programming rate: 20ºC/min
44
50
100
150
199 262 209 225 236 246 274 289 303 200
250
333 348 350 [m/z]
300
( m/z range : 29 - 600 amu )
X : p-xylene
Ph : phenol 91
94
OH
106 44
66 51
32
65
39
77
55
29
79
EP : p-ethylphenol
MP : p-cresol 107
OH
107
OH
122 77 29
51
39
77
90
63
29
VP : p-vinylphenol
39
51
91
65
PP : p-phenylphenol 120
OH
170
OH 91
29
51
141
115
65
39
105
89
39
85
51 63
102
152
127
B : 4,4'-ethylidenediphenol
A : 4,4'-methylenediphenol 200
199
OH 107
HO
OH
HO
214 77 94 29 39 55 65
183 152 165 128 141
254
210
29 39
55 65 77 91
115121
181 141152 169
216
E : 4,4'-(cyclohexane-1,1-diyl)diphenol
C : 4,4'-(ethene-1,1-diyl)diphenol
225
212 197
268
OH
HO
HO 65 82 91 29 39 51
165 152 181 118 139
OH 107 131
224
268 286
77 91 39 29 55 65
199 165 185 152
212
251 239
290
342
268
Tsuge, Ohtani and Watanabe
130 Polycarbonate (thermally stabilized) O
(CH3)3CCH2 C(CH3 )2
COO
C(CH3 )2
O
COO
O
COO
C(CH3 )2 CH2C(CH3)3
n
H3C
CH3 CH3
BA
D
MP
MA
P
EP VP
TIC
OP PP
0
B A
C
10
Peak Notation
Assignment of Main Peaks
P MP EP VP PP MA
phenol p-cresol p-ethylphenol p-vinylphenol p-isopropylphenol p-isopropenylphenol
OP
HO
A
HO
B
HO
C
HO
BA
bisphenol A
D
HO
Molecular Weight
C(CH3)2CH2C(CH3)3 C H2 C(CH3)2 OH
HO
C(CH3)2 OH
H3C
30 [min]
20
OH
Retention Index
Relative Intensity
94 108 122 120 136 134
983 1078 1169 1220 1231 1306
15.9 16.4 7.1 5.4 5.2 13.0
206
1620
7.8
184
1834
4.5
212
1881
7.5
214
2142
8.7
228
2207
100.0
310
2723
32.3
CH3
CH 3
[ Related Reference ] 1) Ishida, Y.; Kawaguchi, S.; Ito, Y.; Tsuge, S.; Ohtani, H. J. Anal. Appl. Pyrolysis 1997, 40-41, 321.
269
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
130
EGA thermogram
Averaged mass spectrum 213
107
100
44
300
400
500
119 135
29 50
600
700 ºC
programming rate: 20ºC/min
77
55 65
0
200
91 152 165 183
100
197
150
200
228 239
253
317 329 347 362
289
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
MP : p-cresol
P : phenol 94
OH
107
OH
66
77
39 55
29
79
29
51
39
90
63
VP : p-vinylphenol
EP : p-ethylphenol 107
OH
120
OH
91
122 77 29
39
51
65
91
29
MA : p-isopropenylphenol
39
65
51
89
105
OP : 4-(1,1,3,3-tetramethylbutyl) phenol 134
OH
135
119
HO 91 29
39
51
65
77
105
29 41
B : p-hydroxy-2,2-diphenylpropane
57 65 77 91
107 119
206
149
C : 4,4'-ethylidenediphenol 197
199
OH OH
HO
214
212 29 39 51 65
103
77
119 135 152 165 179 115
29 39
BA : bisphenol A
55 65 77 91
115121
181 141152 169
216
D : 4,4'-(3,3,5-trimethylcyclohexane-1,1-diyl)diphenol 239
213
HO
OH 310 228
HO
119 29 39
55 65 77
91
107
135 152 165 181 197
230
29 41 55 6577 91
OH 253 107 121 145159 185197212 165 225
295
270
Tsuge, Ohtani and Watanabe
131 Brominated polycarbonate; Br-PC Br Br
Br OCO
C(CH3 )2 Br
Br
Br
Br
O
OCO
O
C(CH3 )2
OCO
O n
Br
Br Br
E
C LB
P A
TIC
BB
0
B
D 10
Peak Notation
Assignment of Main Peaks
LB BB P A B C D E
CO2, hydrogen bromide etc. bromobenzene phenol o-bromophenol p-bromophenol 2,6-dibromophenol 2,4-dibromophenol 2,4,6-tribromophenol
30 [min]
20
Molecular Weight 156 94 172 172 250 250 328
[ Related Reference ] 1) Sato, H.; Kondo, K.; Tsuge, S.; Ohtani. H.; Sato, N. Polym. Degrad. Stab. 1998, 62, 41.
Retention Index 150 937 983 1078 1292 1365 1397 1669
Relative Intensity 100.0 6.4 29.2 17.7 10.3 49.3 6.8 98.8
271
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
131
EGA thermogram
Averaged mass spectrum 82
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
44 94
63 29
143
119 50
100
174
150
196
252
222
200
330
275
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
LB : hydrogen bromide
BB : bromobenzene 80
H
77
Br
Br
156
51 29
74
38
39
106
129 141
A : o-bromophenol
P : phenol 94
OH
172 174
OH Br 65
66 39
39
55
29
79
B : p-bromophenol
93 87
53
32
117119
143146
C : 2,6-dibromophenol 172
OH
252
OH
174
Br
Br 65 63
Br
93
39 50
32
86
117 119
143 146
29 38
86
143 92 117 126 146 172174 197
252
OH
330
OH Br
Br
Br
63
Br 62
Br 143 172 92 86 117 126 146 174
223
E : 2,4,6-tribromophenol
D : 2,4-dibromophenol
53 29 38
61
197
223
29
37
61
141 91 111 118 81
222 170 152 175 197
250
301
272
Tsuge, Ohtani and Watanabe
132 Polysulfone; PSF O
C(CH3)2
O
SO2 n
P
MD b
MB,VD
TIC
DE
PC
ED
LB
0
a
ID DT
F 10
Peak Notation
Assignment of Main Peaks
LB P PC DE
SO2 phenol p-cresol diphenyl ether
MD
4-methyl(diphenyl ether)
F
fluorene
ED
4-ethyl(diphenyl ether)
DT
di-p-tolyl ether
C
30 [min]
20
Molecular Weight
O
C
O
O
C
C
C
Retention Index
Relative Intensity
64 94 108 170
985 1078 1419
43.5 100.0 11.2 11.2
184
1532
32.8
166
1614
2.1
198
1639
10.9
198
1644
3.5
1665
13.2
210
1758
10.1
-
2707 3218
12.3 37.9
O
182
MB
C
VD
4-vinyl(diphenyl ether)
ID
4-isopropenyl(diphenyl ether)
O
C
196
C C
O
C C
a b
unidentified unidentified * bonding hydrogen is omitted [ Related References ]
1) Crossland, B.; Knight, G. J.; Wright, W. W. Br. Polym. J. 1986, 18, 156. 2) Almen, P.; Ericsson, I. Polym. Degrad. Stab. 1995, 50, 223. 3) Perng, L. -H. J. Polym. Sci., Part A Polym. Chem. 2000, 38, 583. 4) Ohtani, H. ; Ishida, Y. ; Ushiba, M. ; Tsuge, S. J. Anal. Appl. Pyrolysis 2001, 61, 35.
273
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
132
EGA thermogram
Averaged mass spectrum 94 66 39
100
200
300
400
500
48
600
700 ºC
programming rate: 20ºC/min
77 107
32
128 50
141 184 152 165 195 210 228 242 260 276 289 304
100
150
200
250
365
300
350
[m/z]
400
( m/z range : 29 - 600 amu )
PC : p-cresol
P : phenol 94
OH
107
OH
66
77
39 55
31
51
39
79
DE : diphenyl ether
90
63
MD : 4-methyl(diphenyl ether) 170
184
O
O 141 51 39
91
77 65
115
94
128
39
155
ED : 4-ethyl(diphenyl ether)
51
77
65
115 128
141 155 169
DT : di-p-tolyl ether 183
198
O
O 198
91 77 51
39
91 105
65
65 128 141 155 169
39 51
MB, VD : 2-methyldibenzo[b,d]furan +
77
107
128 141
155
169 183
ID : 4-isopropenyl(diphenyl ether)
4-vinyl(diphenyl ether) O
196
210
O
+ 182
O
195 39
51
77 65
152
91 115
120
167
141
a : unidentified
77 91 39 51 65
115 119 141152 165 181
b : unidentified 365
289
380
304 39 51 65
77 91 119 144 165181 195 152 115
39 5165
77
165183 195 115 152
271
274
Tsuge, Ohtani and Watanabe
133 Poly(phenylene oxide); PPO CH3 O n
CH3
X1 TP X2 OC D4 D3
D6 D5
T4 T3 T6 T2 T5
D2 D1 TIC
X3
PC
0
T1
10
Peak Notation
Assignment of Main Peaks
OC PC X1 X2 X3 TP
o-cresol p-cresol 2,6-xylenol (monomer) 2,4-xylenol 3,5-xylenol 2,4,6-trimethylphenol
D1
HO
C
C C
C
D2 HO
C
O C
C
C C HO C
1058 1077 1113 1153 1172 1213
72.9 7.2 100.0 74.7 9.0 72.5
242
1996
15.6
256
2038
21.3
228
2139
31.4
242
2185
49.6
242
2221
28.3
256
2263
40.8
362
2810
9.6
376
2843
15.3
350 ?
2991
22.7
364 ?
3019
31.8
364 ?
3057
16.4
378 ?
3086
28.7
HO
D5
C
C C
D6 C HO
O
C
HO
HO
C
C
C
C
C
C
O C
C
C
T2
HO C HO
C O
HO C
T4
O
C O
C
C
C
C
HO C
C
C C
O C
HO
108 108 122 122 122 136
(dimer group)
C
C
C
C HO
D4
T5
Relative Intensity
C
HO
D3
T3
Retention Index
C
HO C
T1
Molecular Weight
C O
HO
30 [min]
20
C O
O
C
C
C
C
HO C
C
O C
O
HO C
T6
HO
(*bonding hydrogen is omitted)
O C
(trimer group)
C
O C
HO C
[ Related References ] 1) Jachowicz, J.; Kryszewski, M.; Kowalski, P. J. Appl. Polym. Sci. 1978, 22, 2891. 2) Chandra, R. Prog. Polym. Sci. 1982, 8, 469. 3) Usami, T.; Keitoku, F.; Ohtani, H.; Tsuge, S. Polymer 1992, 33, 3024. 4) Takayama, S.; Matsubara, N.; Arai, T.; Takeda, K. Polym. Degrad. Stab. 1995, 50, 277.
275
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates 133
EGA thermogram
Averaged mass spectrum 107 122 77
100
91
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
39
51
135
65
152 165 181 197 211 228
31 50
100
150
200
242 258 250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
X1 : 2,6-xylenol
OC : o-cresol 108
OH
OH
77
77
91
90 51
39
29
63
122
107
39
29
51
65
TP : 2,4,6-trimethylphenol
X2 : 2,4-xylenol 107
OH
121
122
OH
77 39
29
51
136
91
91
65
39
29
D2 : 2,4-dimethyl-3-hydroxy-2',4',6'-trimethyldiphenol
121
HO
O
HO
228
108
135 122 77 29 41 53 65
91 107
181 195 211 226
241
29 39 51 65
258
D4 : 4-(2-hydroxy-3-methylbenzyl)-2,6-dimethylphenol
77 91
165 181 141152
199 213 230
D6 : 4-(2-hydroxy-3,5-dimethylbenzyl)-2,6-dimethylphenol
122
HO
117
D3 : 4,6'-methylenebis(2-methylphenol)
256
HO
77
65
51
135 242
HO
HO
HO 256 122
77 29 39 51 65
91 107
135 152165 181 195 211
227
77 29 39 53 65
244
T2 : 4-(4-(mesityloxy)-2,6-dimethylphenoxy)
91
107
152165 179197
-2,6-dimethylphenoxy)-2,6-dimethylphenol 376
O
362 HO
O
O
O HO
41 53 65
7791 119 135
258
T4 : 4-(4-(2-hydroxy-3-methylphenoxy)
-2,6-dimethylphenol HO
211225 241
188
239 223 255
361
242
195 225 77 91 122 107 137 165 181 209 41 53 65
244
347
276
Tsuge, Ohtani and Watanabe
134 Modified poly(phenylene oxide); Modified PPO CH3 CH2CH(C6H5)
m
O
+
n
CH3 D4 D3 S
D1
SS
T
10
toluene ethylbenzene styrene (S monomer) α -methylstyrene o-cresol 2,6-xylenol (PO monomer) 2,4-xylenol 2,4,6-trimethylphenol Ph-C-C-C-Ph C=C(Ph)-C-C-Ph (S dimer)
D1
HO
C C
C
C
C
C O
C
HO
HO
C
C
C
C
O
O
C
C
C
C HO
HO
C
C
C
(PO trimer group)
HO
C
C C
C
C C
O C
C
HO
C
HO
242
1996
6.4
256
2038
8.6
228
2139
13.3
242
2185
242
2221
22.9 14.5
256
2263
19.7
312
2487
18.8
362
2810
2.2
376
2843
4.7
348
2991
2.8
362
3019
5.9
362
3057
2.8
376
3085
7.7
362
3227
6.9
376
3288
6.7
C
HO
C
T6
O C
C
HO C
C
C
O C
C C
HO
13.6 7.6 100.0 9.1 16.0 35.7 24.4 34.5 8.5 3.2
C
C
HO
C
HO
769 866 894 987 1059 1114 1153 1213 1674 1734
C
C
O C
T4
T8
C
C
C
HO
T2
T7
(PO dimer group)
C
C=C(Ph)-C-C(Ph)C-C-Ph (S trimer)
SSS
92 106 104 118 108 122 122 136 196 208
C HO
C
HO
D6
T5
C C
HO C
HO
C O
C
C
D5
Relative Intensity
C HO C
D4
C HO
C HO
D3
Retention Index
C O
D2
T3
Molecular Weight
Assignment of Main Peaks
C
30 [min]
20
T EB S αS OC X1 X2 TP SS’ SS
T1
20
OC
0
Peak Notation
T4 T6 T7 T8 T5 T3
15
10
αS
EB
T2 T1
TP
X1 TIC
SSS D5
D2
SS’ X2
D6
C
HO
C
O C
C C
C HO C
C
C HO
HO
HO
C
C
C C C
(*bonding hydrogen is omitted) (*Ph represents C6H5 (phenyl group))
[ Related References ] 1) Jachowicz, J.; Kryszewski, M.; Kowalski, P. J. Appl. Polym. Sci. 1978, 22, 2891. 2) Mukherji, A. K.; Butler, M. A.; Evans, D. L. J. Appl. Polym. Sci. 1980, 25, 1145. 3) Wandelt, B.; Kryszewski, M.; Kowalski, P. Polymer 1981, 22, 1236. 4) Chandra, R. Prog. Polym. Sci. 1982, 8, 469. 5) Jachowicz, J.; Kryszwski, M.; Mucha, M. Macromolecules 1984, 17, 1315. 6) Usami, T.; Keitoku, F.; Ohtani, H.; Tsuge, S. Polymer 1992, 33, 3024.
277
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates 134
EGA thermogram
Averaged mass spectrum 91 104
77
121 100
39
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51
135
65
242 152 165 178 196 213 228 258 50
100
150
200
306
250
362 376
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
OC : o-cresol
S : styrene 104
108
OH
103
78
77 90
51 39
X2 : 2,4-xylenol
OH
107
77 29
63
29
X1 : 2,6-xylenol
39
51
39
63
51
122
107
OH
77
91
65
39
29
51
122
91
65
SS' : 1,3-diphenylpropane
TP : 2,4,6-trimethylphenol 121
OH
92 136 196 105
91 29
39
51
65
77
117
51
39
D4 : 4-(2-hydroxy-3-methylbenzyl)-2,6-dimethylphenol
65 77 118
D6 : 4-(2-hydroxy-3,5-dimethylbenzyl)-2,6-dimethylphenol
122
HO
139 152 165 178
135 242
HO
HO
HO 256 122
29 39 51 65
77 91 107
135 152 165 181 195 211
227 244
SSS : 5-hexene-1,3,5-triyltribenzene (styrene trimer)
77 29 39 53 65
91
165 241 152 179 197211225
107
258
T2 : 4-(4-(mesityloxy)-2,6-dimethylphenoxy) -2,6-dimethylphenol 376
91
HO
O
O
117 39 51 6577
194 118143 165 179
207 221
312 297
415365 77
91 119 117 135
188 181
239 255
361
278
Tsuge, Ohtani and Watanabe
135 Polyethersulfone; PESF SO2
O n
b PD
DE
a
PP
P BF TIC
LB
15
20
25
DP
0
10
Peak Notation
Assignment of Main Peaks
LB P DP DE BF PP PD a b
SO2 phenol diphenyl diphenyl ether dibenzofuran O OH p-phenylphenol 4-phenyl(diphenyl ether) 1-phenoxy-4-(phenylsulfonyl)benzene 4,4'-sulfonylbis(phenoxybenzene)
30 [min]
20
Molecular Weight
O
64 94 154 170 168 170 246 310 402
Retention Index 985 1398 1420 1546 1730 2230 2806 3659
[ Related References ] 1) Crossland, B.; Knight, G. J.; Wright, W. W. Br. Polym. J. 1986, 18, 156. 2) Almen, P.; Ericsson, I. Polym. Degrad. Stab. 1995, 50, 223. 3) Botvay, A.; Mathe, A.; Poppl, L.; Rohonczy, J.; Kubatovics, F. J. Appl. Polym. Sci. 1999, 74, 1. 4) Perng, L. -H. J. Polym. Sci., Part A Polym. Chem. 2000, 38, 583. 5) Ohtani, H. ; Ishida, Y. ; Ushiba, M. ; Tsuge, S. J. Anal. Appl. Pyrolysis 2001, 61, 35.
Relative Intensity 99.81 100.00 4.31 68.53 18.90 3.10 16.83 12.90 64.29
279
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
135
EGA thermogram
Averaged mass spectrum 64
48
94 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
39
170
141
77
32
115 128
50
100
184 202 217 231 246 262
152 150
200
338
310
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
LB : sulfur dioxide
P : phenol 64
S
94
OH
O
O
48 66 44
39
32
55
29
84
79
DE : diphenyl ether
DP : diphenyl 154
170
O 141
39
51
76
51 63
77
39
102 115 128 139
115
65
94
128
155
PP : p-phenylphenol
BF : dibenzofuran 168
O
170
OH
139 39
51
69
84
141
115 98
113
39
PD : 4-phenyl(diphenyl ether)
85
55 63
102
127
a : 1-phenoxy-4-(phenylsulfonyl)benzene 246
310
O O
S O
O 77
39 51 63 77
115 141152 169 102 126
202 217 230 189
51 262
b : 4,4'-sulfonylbis(phenoxybenzene) O
402
O S O
O
217 77 51 39 63
185 115 141 201 92 129 168 215 233 261
152
309 338 370
39
63
185 217 115 141 129 152169 189 97 215 233
280
Tsuge, Ohtani and Watanabe
136 Poly(ether ether ketone); PEEK O
O
CO n
P
OD c PP OF OB BF PD XO DE BO a PF PB DP F
TIC
0
10
b
30 [min]
20
Peak Notation
Assignment of Main Peaks
P
phenol
DP
Molecular Weight
Retention Index
Relative Intensity
94
987
100.0
diphenyl
154
1402
0.1
DE
diphenyl ether
170
1422
1.2
BF
dibenzofuran
168
1551
2.4
166
1620
0.4
182
1658
0.2
170 170
1726 1735
0.2 0.3
186
1748
6.6
184
1893
1.5
196
1909
0.1
198
2041
3.1
-
2193 2197
0.6 0.6
262
2233
0.5
268
2387
0.3
274
2510
0.4
-
2915 3076
3.8 6.9
O
F
fluorene
BO
benzophenone
CO OH
PP
OD
m-phenylphenol p-phenylphenol O
OH
OH OH
OF
O O
XO
xanthone C O
OB
CO
OH
a
9-phenylfluorene 2-hydroxy-9-fluorenone
PD
1,4-diphenoxybenzene
PF PB b c
O O O
CO
unidentified unidentified
O
O
281
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
136
EGA thermogram
Averaged mass spectrum 94
66
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
39 55
31
77
129 141
110
50
100
157 170 150
186
262 200
250
300
[m/z]
( m/z range : 29 - 600 amu )
DE : diphenyl ether
P : phenol 94
OH
170
O 141 51 39
65
39
55
29
77
BF : dibenzofuran
115
94
65
32
79
154
OD : 4-phenoxyphenol 168
O
186
OH
O
139 32 39
51
84
69
98
39
113
OF : 2-dibenzofuranol
51
109
77 65
157
129
93
141
169
188
OB : 4-hydroxybenzophenone 184
OH
121
O
O OH 128 39
92
51 63
77
139
113
155
168
39 51 65
196
a : 9-phenylfluorene
77
93
198
105 141 152 169181
a : 2-hydroxy-9-fluorenone 242
196
O OH 139
32 44 51 65
119 94 113
165 139
32 39 51
215 226
b : unidentified
69 84
168
94 113 121
242
c : unidentified 121
197 121
195
290
288
139
39 51
65 77 93 115
141 168 185 157
213
261 273
29
39
65 51
93 113 89
167 150
176
231 202 229
271 272
282
Tsuge, Ohtani and Watanabe
137 Poly(phenylene sulfide); PPS S n
TM
TE
M DM
TIC
0
DS DT PM 10
Assignment of Main Peaks
M
phenyl mercaptan
DM
HS
DT
diphenyl thioether
DS
PT
ST 30 [min]
20
Peak Notation
Molecular Weight
SH
SH
S
SH
PM
T
SM
diphenylene sulfide
Retention Index
Relative Intensity
110
973
38.7
142
1301
7.5
186
1617
2.4
186
1757
3.4
184
1788
1.2
218
1974
41.4
216
2177
7.4
294
2664
2.5
292
2884
1.4
326
3070
13.1
432
3943
100.0
S
TM SM PT ST T
S
SH SH
S S
S S
S S
S S
TE
SH S
SH
S
[ Related References ] 1) Ehlers, G. F. L.; Fisch, K. R.; Powell, W. R. J. Polym. Sci., Part A Polym. Chem. 1969, 7, 2955. 2) Montaudo, G.; Puglisi, C.; Scamporrino, E.; Vitalini, D. Macromolecules 1986, 19, 2157. 3) Montaudo, G.; Puglisi, C.; Samperi, F. J. Polymer. Sci., Part A Polym. Chem. 1994, 32, 1807. 4) Perng, L. -H. Polym. Degrad. Stab. 2000, 69, 323.
283
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
137
EGA thermogram
Averaged mass spectrum 110 218 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
185 45
51 69 84 97
33 0
50
128
152 142
100
188
171
150
215
250
200
250
294
326
300
350
450 [m/z]
400
( m/z range : 29 - 600 amu )
M : phenyl mercaptan
DT : diphenyl thioether 110
SH
186
S
66
51 84
51
39
PM : diphenyl mercaptan
92
65 77
39
95
33
109 121
141
152
171
188
DS : diphenylene sulfide 186
184
SH
S 152 39
51 63
93
76
115
126 139
171
188
TM : 4-(phenylthio)benzenethiol
44 51 63
79
139
92
152
113 126
SM : dibenzo[b,d]thiophene-2-thiol 218
216
SH
SH
S
S
184
184 109 51 65 77 45
92
140
171
154 171
128
45
190 203
PT : 1,4-bis(phenylthio)benzene
51
69
108
85 95
127
139
215 152
190
ST : 2-(phenylthio)dibenzo[b,d]thiophene 292
294
S
S
S 185 145
S 51 77 45 65
152 109 139 171 95 129
51 69 77 93 32 44
217 215 230 245 260
115
129 146
247
phenylthio)benzenethiol SH
326
S
260 214 216
TE : 4-(4-(dibenzo[b,d]thiophen-2-ylthio)
T : (4-(4-(phenylthio)phenylthio)benzenethiol S
171 184
432
SH S S
184 217 51 65 77 97108 45
152 171 141
215
260
293
328
S 108 45 69 96
184 171 139 215 152
258 290
322 355
397
284
Tsuge, Ohtani and Watanabe
138 Poly(arylether nitrile); PEN CN O
O n
D
F E
BD CP
TIC
P 0
10
Peak Notation
Assignment of Main Peaks
P BD CP D
phenol 1,3-benzenediol p-cyanophenol unidentified
E
HO
F
unidentified
30 [min]
20
Molecular Weight
Retention Index
Relative Intensity
94 110 119 228
986 1281 1364 2086
10.0 15.1 8.8 100.0
227
2318
15.0
283
3148
49.9
CN O
OH
285
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
138
EGA thermogram
Averaged mass spectrum 228 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
63 29 44 51 0
89
100 115 126
50
200 144154 171182
100
150
212 200
230 253
312
283
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
P : phenol
BD : 1,3-benzenediol
OH
94
110
OH
OH
66 39 55
29
29
79
CP : p-cyanophenol
39
53
82 69
95
D : unidentified 119
HO
228
N
91
64 29
39
52
76
63 29 39 51
110
E : 2-hydroxy-6-(3-hydroxyphenoxy)benzonitrile HO
CN
OH
89
100 115 126 144 154 171182
200 202
F : unidentified
227
283
O
39 52 63
85 99 115126 143 154 170182 199
199 225 254 100 128141 150 174 202 230 39 51 74 87 113
286 310
230
286
Tsuge, Ohtani and Watanabe
2.2.16 Silicone polymers 139 Polydimethylsiloxane; PDMS Si(CH3)2
O
n
D9
D3
D4 D10
D6
D11
D5
D7
D13
D15 D17 D19
D8
D21
15
25
20
TIC
0
10
Peak Notation
Assignment of Main Peaks
30 [min]
20
Molecular Retention Weight Index
D3
S i(CH3 ) 2 O
3
222
D4
Si(CH3 ) 2 O
4
D5
Si(CH3 ) 2 O
D6
Si(CH3 ) 2 O
D7
Si(CH3 ) 2 O
D8
Si(CH3 ) 2 O
D9
S i(CH3 ) 2 O
D10
Si(CH3 ) 2 O
D11
S i(CH3 ) 2 O
D13
S i(CH3 ) 2 O
D15
S i(CH3 ) 2 O
D17
Si(CH3 ) 2 O
D19
Si(CH3 ) 2 O
19
Si(CH3 ) 2 O
21
D21
Relative Intensity
825
100.0
296
996
36.5
5
370
1152
18.2
6
444
1324
24.3
7
518
1497
17.7
8
592
1668
6.7
9
666
1828
2.2
10
740
1984
1.1
11
814
2135
0.8
13
962
2425
0.7
15
1110
2705
0.7
17
1258
2981
0.6
1406
3245
0.4
1554
3509
0.3
[ Related References ] 1) Grassie, N.; MacFarlane, I. G. Eur. Polym. J. 1978, 14, 875. 2) Ballistreri, A.; Garozzo, D.; Montaudo, G. Macromolecules 1984, 17, 1312. 3) Fujimoto, S.; Ohtani, H.; Tsuge, S. Fresenius Z. Anal. Chem. 1988, 331, 342. 4) Fujimoto, S.; Ohtani, H.; Yamagiwa, K.; Tsuge, S. J. High Res. Chromatogr. 1990, 13, 397. 5) Radhakrishnan, T. S. J. Appl. Polym. Sci. 1999, 73, 441.
287
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
139
EGA thermogram
Averaged mass spectrum 207 73 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
281 133 147 191 96 119 341 355 177 237 267 163 89 115 221 251 295 325 356
45 59 50
100
150
200
250
300
429 399 415
350
503
400
450
550 [m/z]
500
( m/z range : 29 - 600 amu )
D4 : octamethylcyclotetrasiloxane
D3 : hexamethylcyclotrisiloxane 207
O
281 O
Si
Si
O
Si
O
Si
O
Si
O
29
Si
Si
45
96 191 119 133 147 163 177 61 75 89 115
O 133 193 207 249 265 103 125 147 163177 235
45 59 73
D5 : decamethylcyclopentasiloxane
D6 : dodecamethylcyclohexasiloxane 73
73 Si
341
Si
O
O
355
267 Si
Si O
Si
O
O
Si O
Si
Si
Si
O
O
Si
Si
O
O O
429
147
325
356 45 59
251
193
133 154
87
342 45 59
339
D7 : tetradecamethylcycloheptasiloxane O
O
Si
Si
Si
O
Si
O
O
O
O
O
Si
O
Si
Si
O
147
Si
503 487
45 59 87
D9 : octadeamethylcyclononasiloxane 73
O
O
O Si
Si
Si
O
O
O
O
O
Si
207 191
133
Si
O
O
Si
355
Si O
281 267 295 249
356 401 385 415
327 328
457 489
73
O
Si Si
413
D10 : eicosamethylcyclodecasiloxane
Si
147
Si
221
341 415 399 311 342
207 221 265 191
O
Si
327 133
311
73
O
Si
281 Si
45 59 87
251
D8 : hexadecamethylcyclooctasiloxane
73 147
207
133 163
87
Si
O
147
Si
O
Si
Si
Si
Si
Si O
O
O
O
O
Si
Si
Si
Si
O Si O
O
281 221 45 59 87
133
429 355 281 341 356 401 267 295 325 459
207 191
221
D11 : docosamethylcycloundecasiloxane O
73 147
O
Si
Si
Si
O
O
O
Si
Si
O
Si
O
O
Si
Si
133
73
O
Si
221 45 59 87
133
O
O
O
O
503
533
O
Si
Si
Si
Si
Si
Si
O
O
O
O
O
O
Si
Si
221
Si
281
281 341 267 295327
429 461 415
Si
147 O
355
207 191
355 341 267 295 327 356
D13 : hexacosamethylcyclotridecasiloxane
O
O
Si
45 59 87
489
207 191
207
356 429 461
503 535
59
96
145
191
Si
Si
Si
O Si
355 429
267 295
341
356 370
415
461
503
288
Tsuge, Ohtani and Watanabe
140 Polymethylphenylsiloxane; PMPS Si(CH3)(C6H5)
O
P3
n
P5
DP B P4 BC
TIC
T
0
10
Peak Notation B T DP P3
P4
benzene toluene diphenyl O O
3
Si (CH3)(C 6H5 )
O
4
Si (CH3)(C 6H5 )
O
4
Si (CH3)(C 6H5 )
O
4
S i (CH3)(C 6H5 )
O
4
S i (CH3)(C 6H5 )
O
5
S i (CH3)(C 6H5 )
O
5
Si (CH3)(C 6H5 )
O
5
Si (CH3)(C 6H5 ) C H3
O
Si(CH3)(C6H5)
Relative Intensity 100.0 6.0 10.8
(cis form)
408
2336
4.6
(trans form)
408
2357
12.8
(c-c-c-c)
544
2826
0.9
(c-c-t-t)
544
2924
6.6
(c-t-c-t)
544
2944
2.9
(t-t-t-t)
544
2973
1.9
(c-c-c-c-c)
680
3427
2.9
(c-c-c-t-t)
680
3519
23.4
(c-c-t-c-t)
680
3543
25.9
(c-t-t-t-t)
680
3583
31.9
694
3689
15.3
3
Si (CH3)(C 6H5 )
P5
BC
Molecular Retention Weight Index 651 78 767 92 1402 154
Assignment of Main Peaks
Si (CH3)(C 6H5 )
30 [min]
20
5
O
4
S i(CH3 )2
C6H5
(stereoisomer)
[ Related References ] 1) Grassie, N.; MacFarlane, I. G.; Francey, K. F. Eur. Polym. J. 1979, 15, 415. 2) Fujimoto, S.; Ohtani, H.; Tsuge, S. Fresenius Z. Anal. Chem. 1988, 331, 342. 3) Fujimoto, S.; Ohtani, H.; Yamagiwa, K.; Tsuge, S. J. High Res. Chromatogr. 1990, 13, 397.
289
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
140
EGA thermogram
Averaged mass spectrum 197 78 135 315
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
91 51 39
73
50
105119
165 150 179
100
150
259 218 253 209 239 200
285
250
313 329 345 300
373
393 408 432 451
350
400
529
450
550 [m/z]
500
( m/z range : 29 - 600 amu )
P3 : 2,4,6-Trimethyl-2,4,6-triphenyl-
DP : diphenyl
1,3,5,2,4,6-trioxatrisilinane(cis) 154
315 Si O
O Si
Si O
393 150 91 165 195 45 65 77 105 137 209
76 51 63
39
102 115 128 139
253 258
tetraoxatetrasilocane (c-c-t-t)
1,3,5,2,4,6-trioxatrisilinane(trans) 315
451 218
O Si Si
Si O
O Si
179 156
393 91 377 408
329
45 6577 105 135
P4 : 2,4,6,8-Tetramethyl-2,4,6,8-tetraphenyl-1,3,5,7,2,4,6,8-
315 389 435 165 195 253 209 239 267299 329359 469 421
218
P4 : 2,4,6,8-Tetramethyl-2,4,6,8-tetraphenyl-1,3,5,7,2,4,6,8218
451
O Si
451
O Si O
373
529
Si
Si
O
O
Si O
373
195 91 315 389 253 165 77 435 135 209239 267299 329 359 43 65 105 421 468
513 544
P5 : 2,4,6,8,10-Pentamethyl-2,4,6,8,10-pentaphenyl-
179
315 195 91 253 313 389 135 165 210 267 45 77 105 239 285 329 359
468
1,3,5,7,9,2,4,6,8,10-pentaoxapentasilecane (c-c-t-c-t)
197
197 O
Si
Si
O Si
O
10
O
135
Si
Si
O
Si
O O Si
259 313
Si
Si
259 247
O
10
O
135
O
Si
453 375 391 437
525
P5 : 2,4,6,8,10-Pentamethyl-2,4,6,8,10-pentaphenyl-
247
43 73 91 119 159181
375 359 391
313
453 454
525
BC : 2,4,6,8,10-pentamethyl-3,5,7,9-tetraoxa-2,4,6,8,10-
1,3,5,7,9,2,4,6,8,10-pentaoxapentasilecane (c-t-t-t-t)
pentaphenyl-2,4,6,8,10-pentasilaundecane (stereoisomer) 135
197 O
247
375 391
Si O
Si O
Si O
197
Si O
O
313
Si O
O
10
Si
259
Si
Si
Si O
135
43 73 91 119 155181 208
435
P5 : 2,4,6,8,10-Pentamethyl-2,4,6,8,10-pentaphenyl-
1,3,5,7,9,2,4,6,8,10- pentaoxapentasilecane (c-c-c-t-t)
181
529
Si Si O
156 179
91 119
513 544
tetraoxatetrasilocane (t-t-t-t)
tetraoxatetrasilocane (c-t-c-t)
43
529
Si Si O
O
O
373
O
O
165 253 195 77 91 119 150 180 209 239 285 45 65
Si
408
P4 : 2,4,6,8-Tetramethyl-2,4,6,8-tetraphenyl-1,3,5,7,2,4,6,8-
P3 : 2,4,6-Trimethyl-2,4,6-triphenyl-
Si
377
329
Si
453 437
73 525
43 57
209 121 147183
271 255 283
345 403 465 511 542 333 395 451
290
Tsuge, Ohtani and Watanabe
141 Dimethylsiloxane-methylphenylsiloxane copolymer Si(CH3)2
O
Si(CH3)(C6H5)
O
n
D2P
DP2 D3P
B
D3P2
D2P2
DP3
D4P
TIC
D3
P3
D4
0
10
Peak Notation B
Molecular Retention Weight Index 78 655 222 824
Assignment of Main Peaks benzene
D3
Si (CH3)2 O
D4
Si (CH3)2 O
D2P
Si(CH3)2 O
2
Si(CH3 )(C6H5)
D3P
Si(CH3)2 O
3
Si(CH3 )(C6H5)
Si(CH3)2 O
4
Si(CH3 )(C6H5)
O
D4P
S i(CH3)(C6H5) S i(CH3)(C6H5)
Si(CH3) 2 O Si(CH3) 2
2
D3P2 +
P3
DP3
2.2
O
284
1304
33.0
O
358
1447
7.8
O
Si(CH3)(C6 H5) O
O
O
2
Si (C H3) (C6H5) O
Si(CH3) (C 6H 5)
S i(CH3)(C 6H5)
O
S i(CH3)(C 6H5)
O
3
Si(CH3)(C6 H5)
O
3
Si(CH3)(C6 H5)
O
Si(CH3)(C6 H5)
O
2
2
O
3
O
2
S i(CH3)(C6H5)
2
O
432
1620
5.4
(cis form)
346
1789
8.2
(trans form)
346
1833
7.8
(cis form)
420
1911
3.4
(cis form)
420
1921
1.5
(trans form)
420
1938
5.0
(trans form)
420
1947
1.7
(cis form)
556
2047
1.7
2076
4.2
2
2
S i(CH3)(C6H5)
2
O
2
Si(C H3)(C6H 5) O
2
Si(CH3)2
S i(CH3)2
997
O
Si(CH3)(C6 H5) O
Si(CH3)2 O S i(CH3)2
296
Si(C H3)(C6H 5 ) O
O
Si(CH3 )2 O Si(CH3) 2
100.0 6.9
4
S i(CH3) 2 O
D2P2
Relative Intensity
3
S i(CH3) 2 O
DP2
30 [min]
20
2
3
Si(CH3 )2 O
3
Si(CH3 )2 O
3
Si(CH3 )2 O
(cis form)
494
(trans form)
556
(trans form)
S i (C H3 )2 O O
3
Si(CH3)2
O
494
2092
2.0
(cis form)
408
2266
0.7
(trans form)
408
2355
2.1
(c-c)
482
2371
0.8
(c-t)
482
2430
2.1
(t-t)
482
2444
1.1
[ Related References ] 1) Grassie, N.; Francey, K.F. Polym. Degrad . Stab. 1980, 2, 53. 2) Fujimoto, S.; Ohtani, H.; Tsuge, S. Fresenius Z. Anal. Chem. 1988, 331, 342. 3) Fujimoto, S.; Ohtani, H.; Yamagiwa, K.; Tsuge, S. J. High Res. Chromatogr. 1990, 13, 397.
291
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
141
EGA thermogram
Averaged mass spectrum 207 78 73
253 269
135 91
51 45 32
119 147 105
50
100
200
300
400
500
100
165 177
700 ºC
327 343
281 223 239
150
600
programming rate: 20ºC/min
193
200
313
250
300
405 389 417
357 350
400
447
463 477
450
537539 550 [m/z]
500
( m/z range : 29 - 600 amu )
D3P : 2,2,4,4,6,6,8-heptamethyl-8-phenyl-1,3,5,7,2,4,6,8 D2P : 2,2,4,4,6-pentamethyl-6-phenyl-1,3,5,2,4,6-trioxasilinane
-tetraoxatetrasilecane
269
343
Si
Si
O
O
O
Si
Si
253
O 91
45
O Si Si
127 133 147 163177 195207 223 239
105
Si O O
164 191 135156 125 179 205
73 91
32 45
286
327 253 265 281
313
D4P : 2,2,4,4,6,8,8,10-nonamethyl-10-phenylDP2 : 2,2,4,6-tetramethyl-4,6-diphenyl-1,3,5,2,4,6-trioxatrisilinane (cis)
1,3,5,7,9,2,4,6,8,10-pentaoxapentasilecane 166
253 O Si
Si
O
82 98 115
O
Si
Si
331
O
O
Si 3951 69
O
O
10
O
Si
Si
Si
139
32 51 65 77
327
91
119 149165 195 181 105 133
156
156 O
Si O
O
327
195 179
253 239 267
313 343
389
420
D3P2 : 2,2,4,4,6,8,8,10-octamethyl-6,10-diphenyl1,3,5,7,9,2,4,6,8,10-pentaoxapentasilecane (trans)
3245
O
389 253 328 269 195 91 135 165 205 311 343 373 239 79 105 297
P3 : 2,4,6-trimethyl-2,4,6-triphenylcyclotrisiloxane (cis)
135
315 O
Si
Si
O
10
O
Si
Si
Si
O O
Si
197 73 43
91 121 165 149 177
329 313 358
401
463
-tetraoxatetratrisilocane (c-t) 187 389
Si
Si
O
O
Si
467
Si O
91 32 51 78
156 253 135 164 195221 267
311 373 328 359 405
468 451
O
O
Si
Si O
479 267
DP3 : 2,2,4,6,8-pentamethyl-4,6,8-triphenyl-1,3,5,7,2,4,6,8
O
405
Si Si
328
327 O
O
405
O
135 73 91 119
2943
Si
Si
Si Si
346
-tetraoxatetrasilocane (trans)
1,3,5,7,2,4,6,8-tetraoxatetrasilocane (cis) O
315
267 285
D2P2 : 2,2,4,4,6,8-hexamethyl-6,8-diphenyl-1,3,5,7,2,4,6,8
D2P2 : 2,2,4,4,6,8-hexamethyl-6,8-diphenyl-
Si
239 223
73
91
135
165 195 180 209 253 270
393 408
540
292
Tsuge, Ohtani and Watanabe
142 Polymethylsilsesquioxane; PMSQ CH3 Si
O
O Si
T6
O
n
CH3
iT8
T8 T7
Et
T10
iT10 iT10’
TIC
0
10
30 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Weight Index
Et T6
ethanol hexamethyl-T6
46 402
T7
heptamethyl-ethoxy-T7
506
T8 iT8 T10 iT10 iT10’
octamethyl-T8 isooctamethyl-T8 decamethyl-T10 isodecamethyl-T10 isodecamethyl-T10'
536 536 670 670 670
465 1321 1448 1467 1517 1544 1732 1738 1758
Relative Intensity 100.0 69.1 32.5 42.6 50.6 72.2 4.1 8.1 7.2
293
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
142
EGA thermogram
Averaged mass spectrum 31
45
100
200
300
400
224 253 283 320 195 209 238 261 313 329
73 0
50
100
150
200
250
300
389 405 350
400
600
700 ºC
521 491
447 433
500
programming rate: 20ºC/min
463
450
524 539 581597 567
507
500
600 [m/z]
550
( m/z range : 29 - 600 amu )
T6 : hexamethyl-T6
Et : ethanol
387
31
OH
Si
O
Si
O O
45 O Si O 186 193
142
T7-1 :heptamethyl-ethoxy-T7
O Si O
Si O
O Si 299
253
225
327
357 371
401
T7-2 : heptamethyl-ethoxy-T7 491
O
Si
O
O
491
Si O SiO
O
O
O
Si O O OSi O O Si O Si
387
238
447 431
Si O SiO
Si O O OSi O O Si O Si
461
223
144 172
29
Si
496
223
461 447 431
215
144
29
iT8 : isooctamethyl-iT8
T8 : octamethyl-T8 521 Si O
253
O
521 Si
Si O
O
Si
OO
Si
O
O
Si OO
Si
O Si
253
Si
505 524 417 447 475491
T10 : decamethyl-T10
223
159
S i O Si O O Si O O Si O O Si
32
Si
O
208 246 283 297 224
355 389 419
507 463 491 539
320 O
32
128
Si O Si
O
Si Si
Si
O O O
O
312
Si
208
417 447
505 524 491 538
283
507
549
32
320
Si O
O O
312
iT10‘ : isodecamethyl-iT10' Si O O Si Si O O O O Si Si O O O Si
O
O Si
96
Si
O O O Si O Si O O Si O O Si Si 299 373
iT10 : isodecamethyl-iT10 320
O Si O Si O O O O Si Si O O Si
O
Si O
O
O O
223
158
496
OO Si O S i O Si O
Si
312
O Si
91
183
208 246
283
507
547
294
Tsuge, Ohtani and Watanabe
143 Poly(methyl-phenyl) silsesquioxane; PMPSQ R Si
O
O Si R
B
Et
O
n
R=CH3(20 %), C6H5(80 %)
BP
EB St
TIC
0
10
Peak Notation
Assignment of Main Peaks
Et B EB St BP
ethanol benzene ethylbenzene styrene diphenyl
30 [min]
20
Molecular Retention Weight Index 46 78 106 104 154
466 656 872 895 1398
Relative Intensity 3.2 100.0 0.2 0.5 2.5
295
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
143
EGA thermogram
Averaged mass spectrum 78
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
51 39
74
154
50
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
Et : ethanol
B : benzene 31
78
OH 45
39
EB : ethylbenzene
52 74
St : styrene 78
104 78 91
103 51
106
51 39
63
32
32 39
BP : diphenyl 154
39
51 63
76
102 115 128 139
63
296
Tsuge, Ohtani and Watanabe
2.2.17 Polyurethanes 144 TDI-Polyester polyurethane; PU CONHC6H3(CH3)NHCO(O(CH2)4OCO(CH2)4CO)mO(CH2)4O
n
CP A6
T
THF
A7 LB
A10
A4
B
A2 A3
BD TIC
VA
0
A11 A5
A1 AA 10
Peak Notation LB B THF CP VA BD A1 AA T A2 A3 A4 A5 A6 A7 A8 A9 A10 A11
Assignment of Main Peaks
A8
A9 30 [min]
20
Molecular Retention Weight Index
CO2 etc. 1,3-butadiene tetrahydrofuran cyclopentanone pentanoic acid CH3(CH2)3COOH 1,4-butanediol CH3(CH2)3COO(CH2)2CH=CH2 unidentified 2,4-tolylene diisocyanate, 2,6-tolylene diisocyanate OCNC6H3(CH3)NCO CH2=CH(CH2)2OCO(CH2)4COOH (CH2)4OCO(CH2)4COO CH2=CH(CH2)2OCO(CH2)4COO(CH2)2CH=CH2 HO(CH2)4OCO(CH2)4COOH CH2=CH(CH2)2OCO(CH2)4COO(CH2)4OH HO(CH2)4OCO(CH2)4COO(CH2)4OH CH2=CH(CH2)2OCO(CH2)4COO(CH2)4OCO(CH2)3CH3 HO(CH2)4OCO(CH2)4COO(CH2)4OCO(CH2)3CH3 COO(CH2)4OCO(CH2)4COO(CH2)4OCO(CH2)4 CH2=CH(CH2)2OCO(CH2)4COO(CH2)4OCO(CH2)4COO(CH2)2CH=CH2
54 72 84 102 90 156 128 174 200 200 254 218 272 290 356 374 400 454
150 395 618 790 819 952 1077 1183 1370 1535 1571 1735 1824 2034 2342 2418 2723 3003 3080
[ Related References ] 1) Ohtani, H.; Kimura, T.; Okamoto, K.; Tsuge, S.; Nagataki, Y.; Miyata, K. J. Anal. Appl. Pyrolysis 1987, 12, 115. 2) Lattimer, R. P.; Muenster, H.; Budzikiewicz, H. J. Anal. Appl. Pyrolysis 1990, 17, 237.
Relative Intensity 53.2 13.9 55.0 100.0 1.4 31.5 1.4 1.4 50.4 15.8 6.8 11.5 2.5 43.0 46.8 2.1 3.6 18.1 8.7
297
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
144
EGA thermogram
Averaged mass spectrum 55
100
41 31
71
200
300
400
500
600
84
700 ºC
programming rate: 20ºC/min
129 111 145 146
101 50
100
174 173
201 202
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
B : 1,3-butadiene
THF : tetrahydrofuran 39
42
54
O
72 29
29
53
CP : cyclopentanone
BD : 1,4-butanediol 55
O
42
OH HO
31 84 41
71
57 29
69
AA : unidentified
A2 : adipic acid, 4-butenyl ester 55
54
OH
O 129
O
O
111 41 83
29 39
84
29
101
73
67
A4 : dibut-3-enyl adipate
141
A6 : 3-butenyl 4-hydroxybutyl adipate
55
55
O
O
O
O
129
O HO
O
O 129
71
183 29 43
101
83
141 155 165
A11 : dibut-3-enyl'-butane-1,4-diyl diadipate 55
O
O O
O
O
O O
O
129 111
29 41
101 7183
183
141 165
201 202
O
111
111 29 39
182
255 311
384
71
83
183
101 141 154 170
201 202
241
298
Tsuge, Ohtani and Watanabe
145 TDI-Polyether polyurethane; PU CONHC6H3(CH3)NHCO(O(CH2)4O)m
E3
T
n
E4 C
E2
B5
O2
B4 B3
O3
E5
A BA THF TIC
P LB
B
10
DF BO
0
B1
10
Peak Notation LB P B BA THF DF BO B1 E1 O1 T E2 O2 A B3 E3 O3 B4 E4 B5 E5 C
20
E1 O1
Assignment of Main Peaks CO2 propane n-butane butylaldehyde tetrahydrofuran O 2,3-dihydrofuran 1-butanol dibutyl ether CH3(CH2)3O(CH2)3CH3 CH3CH2O(CH2)4OCH=CH2 CH3(CH2)3O(CH2)4OH 2,4-tolylene diisocyanate, 2,6-tolylene diisocyanate OCNC6H3(CH3)NCO CH3CH2O[(CH2)4O]2CH=CH2 CH3(CH2)3O[(CH2)4O]2H unidentified CH3(CH2)3O[(CH2)4O]2(CH2)3CH3 CH3CH2O[(CH2)4O]3CH=CH2 CH3(CH2)3O[(CH2)4O]3H CH3(CH2)3O[(CH2)4O]3(CH2)3CH3 CH3CH2O[(CH2)4O]4CH=CH2 CH3(CH2)3O[(CH2)4O]4(CH2)3CH3 CH3CH2O[(CH2)4O]5CH=CH2 unidentified
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
44 44 58 72 72 70 74 130 144 146 174
150 300 400 608 620 651 655 885 1074 1141 1371
6.3 25.2 22.5 10.1 42.7 11.9 4.7 2.2 7.8 5.3 100.0
216 218 274 288 290 346 360 418 432 -
1552 1618 1694 1821 2028 2095 2245 2501 2725 2794 2973
8.5 6.5 1.6 2.2 11.2 3.3 5.5 15.3 7.4 0.8 14.7
299
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
145
EGA thermogram
Averaged mass spectrum 71
100
55
41
200
300
400
29
85 91
106
50
500
600
700 ºC
programming rate: 20ºC/min
145 148
174
129
173
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
E1 : vinyl-4-ethoxy butylether
BA : butylaldehyde 44
57
O 29
O
O
41 29
100
71
72
85
57 116
T : 2,4-tolylene diisocyanate
E2 : 1-ethoxy-4-(4-vinyloxy)butoxy)butane 71
174 O
O C
C N
O
O
145
O
N 146 39
51
91
64 76
43 173
85
98
129 111
147
E3 : 3,8,13,18-tetraoxaicos-1-ene
O2 : 4-(4-butoxybutoxy)butan-1-ol 55
57
29
118 117
71
71
O
O
O
O
OH
O
O
43 29
85
43 55
100 116 129
145 146
85
29
129
100
174
145
111
174
E4 : 3,8,13,18,23-pentaoxapentacos-1-ene
B4 : 5,10,15,20-tetraoxatetracosane 71
71 O
O
O
O
43
43
55
85
29
98
111 124
143 148
174
O
O
O
O
O
129
55 85 100
29
143 147
116
217
C : unidentified
B5 : 5,10,15,20,25-pentaoxanonacosane
71
71 O
O
O
O
O
129 55
43 29
55
85 98
124 114
143 147
43 173
215
29
85 100 115
143 147
173
217
300
Tsuge, Ohtani and Watanabe
146 MDI-Polylactone polyurethane; PU CONHC6H4CH2C6H4NHCO(O(CH2)5CO)mO(CH2)4O
n
M
CL
TIC
LB HF
CP
HA
0
D’ D
A
T
C
10
Peak Notation
30 [min]
20
Molecular Retention Weight Index
Assignment of Main Peaks
Relative Intensity
LB
propylene etc.
-
295
0.4
HF
tetrahydrofuran
72
613
0.2
CP
cyclopentanone
84
789
1.9
HA
5-hexenoic acid
114
994
2.6
CL
ε -caprolactone
114
1157
24.3
O
CH2=CH(CH2)3COOH
O O C
A
CH3(CH2)4OCO(CH2)5OH
202
1408
1.3
D’
CH2=CH(CH2)3COO(CH2)5COOH
228
1735
4.4
228
1785
1.6
250
2139
100.0
342
2598
1.5
410
2645
3.2
D M T C
(CH2)5COO(CH2)5COO
(CL dimer)
diphenylmethane diisocyanate
OCNC6H4CH2C6H4NCO
(CH2)5COO(CH2)5COO(CH2)5COO
(CL trimer)
CH2=CH(CH2)3COO(CH2)5COO(CH2)5COO(CH2)3CH=CH2
301
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
146
EGA thermogram
Averaged mass spectrum 55 42 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
29
84
115
70
97
50
132 128
152 165
100
150
250
208 221
180 193
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
CP : cyclopentanone
HF : tetrahydrofuran 42
55
O
O
84
72 41 29 29
CL : ε -caprolactone
HA : 5-hexenoic acid 60
39
67
55
O
O
42
OH
68
O 84
29
96
29
114
87
114 97
D' : 6-(5-hexenoyloxy)hexanoic acid
A : pentyl-6-hydroxyhexanoate 41
70
O
69
69
O
56
OH
97
97
55
O
OH
O
41
115
O
114 31 29
87
128137 152
D : 1,8-dioxacyclotetradecane-2,9-dione (ε -caprolactone dimer) O O
55
O
41
C
N
N
250 C O
O
69
97 84
210
M : diphenylmethane diisocyanate
115
29
128 133 156
81
169
208
O 128 141 156 169
221 39 51 63
210
77
132 90 104 125
165180 152 190
231
T : 1,8,15-trioxacyclohenicosane-2,9,16-trione (CL trimer) C : 6-oxo-6-(6-oxo-6-(pent-4-enyloxy)hexyloxy)hexylhex-5-enoate 115
115
69
O
O
O
29
O
O O
O
55 41
O O
O
97 41 55
183
O
69 97 84
O
128
229250 281
324
401
29
81
128 141
169 201
297 250 281
430
302
Tsuge, Ohtani and Watanabe
147 Urethane rubber; U CONHC6H4CH2C6H4NHCO(O(CH2)2OCO(CH2)4CO)mO(CH2)2O
n
CP MI
LB
D
A E M EG
TIC
B C
0
O1
F O3
O 2’ O2
O4
10
Peak Notation
30 [min]
20
Assignment of Main Peaks
Molecular Retention Weight Index
Relative Intensity
LB A EG CP B C O1
CO2 acetaldehyde ? ethylene glycol cyclopentanone 1,4-butanediol unidentified CH3(CH2)3COO(CH2)2OH
44 44 62 84 90 124 146
150 409 705 790 947 1024 1129
58.2 20.3 12.4 100.0 6.5 0.9 3.6
M O2 O2’ E F O3 MI O4
(CH2)2OCO(CH2)4COO CH2=CHOCO(CH2)4COO(CH2)2OH CH3CH2OCO(CH2)4COO(CH2)2OH CH3(CH2)3COO(CH2)2OCO(CH2)3CH3 unidentified HO(CH2)2OCO(CH2)4COO(CH2)2OH diphenylmethane diisocyanate OCNC6H4CH2C6H4NCO CH3(CH2)3COO(CH2)2OCO(CH2)4COO(CH2)2OH
172 216 218 230 234 250 318
1350 1531 1592 1748 1803 1867 2137 2262
9.3 1.1 2.2 4.4 4.2 6.2 39.6 3.8
344
2543
33.0
D
( CH 2) 2O C O (CH2)4C OO
2
303
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
147
EGA thermogram
Averaged mass spectrum 55
98
100
200
300
400
500
600
84
700 ºC
programming rate: 20ºC/min
41
173
111
31
154 129 142
69 50
100
174 188
150
213 200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
A : acetaldehyde
EG : ethylene glycol
29
31
HO
44
O
OH
43
62 61
58
CP : cyclopentanone
B : 1,4-butanediol 42
55
O
OH HO
31 84 41
57 29
84
O1 : 2-hydroxyethyl pentanoate
M : 1,4-dioxecane-5,10-dione
85
O
57
142
10
84 41
41
103 104
73
O
O2' : ethyl 2-hydroxyethyl adipate
29
O
O
111
O
154
OH
O O
54 101
69
129 142
N
N
68
31
137
173
D : 1,4,11,14-tetraoxacycloicosane-5,10,15,20-tetraone O
173 99
C 55
165180 152 193
86 41
231
29
68
20
O
113
221
132
O
O 208
103 104 125
109
82
250 O
77
126
41
174
MI : diphenylmethane diisocyanate
29
98
O
155
83
31
39 51 63
99
O
173
45
129
68
E : ethane-1,2-diyl dipentanoate O
55
C
112
O O
O
55
O
OH
O
29
71
69
155 126 142
174
217
O O
O O 285
344
304
Tsuge, Ohtani and Watanabe
2.2.18 Cellulose-type polymers 148 Cellulose CH2OH H
O
O
H OH
H
H
OH
H n
M
PA LB P
TIC
AO
LO G L’
MF FO FA
L
0
10
Peak Notation
Assignment of Main Peaks
LB PA M AO
CO2 pyruvic aldehyde CH3COCHO hydroxyacetaldehyde etc. acetone alcohol CH3COCH2OH O
FA FO MF
Molecular Retention Weight Index
O
O
5-methyl-2-furfural O
O
O
H3C
C H O
LO L’ L
3,6-dianhydro-α-glucopyranose ?
O
O O
150 650 654 651
18.7 23.2 58.9 8.8
96
833
7.5
98
924
6.9
110
963
6.8
110
998
17.6
O OH
144 ?
1190
8.9
126
1229
20.8
144
1309
18.7
162
1483
100.0
O
O
O
O
levoglucosan
O
O
levoglucosenone OH
44 72 74
C H2 O H
P G
Relative Intensity
C H O
2-furfural H3 C
30 [min]
20
OH OH
O OH
[ Related References ] 1) Schulten, H. -R.; Toertz, W. Anal. Chem. 1978, 50, 428. 2) Schulten, H. -R.; Bahr, U.; Goertz, W. J. Anal. Appl. Pyrolysis 1981, 3, 137. 3) Shafizadeh, F. J. Anal. Appl. Pyrolysis 1982, 3, 283. 4) Shafizadeh, F. J. Appl. Polym. Sci., Appl. Polym. Symp. 1983, 37, 723. 5) van der Kaaden, A. V.; Haverkamp, J.; Boon, J. J.; de Leeuw, J. W.; J. Anal. Appl. Pyrolysis 1983, 5, 199. 6) Evans, R. J.; Milne, T. A.; Soltys, M. N.; Schulten, H. –R. J. Anal. Appl. Pyrolysis 1984, 6, 273. 7) Piskorz, J.; Radlein, D.; Scott, D. S. J. Anal. Appl. Pyrolysis 1986, 9, 121. 8) Funazukuri, T.; Hudgins, R. R.; Silveston, P. L. Ind. Eng. Process Des. Dev. 1986, 25, 172. 9) Richards, G. N. J. Anal. Appl. Pyrolysis 1987, 10, 251. 10) Pouwels, A.; Eijkel, G. B.; Boon, J. J J. Anal. Appl. Pyrolysis 1989, 14, 237. 11) Yano, T.; Ohtani, H.; Tsuge, S.; Obokata, T. Tappi J. 1991, 74, 197. 12) Kelly, J.; Mackey, M.; Helleur, R. J. J. Anal. Appl. Pyrolysis 1991, 19, 105. 13) Yano, T.; Ohtani, H.; Tsuge, S.; Obokata, T. Analyst, 1992, 117, 849. 14) Ishida, Y. ; Ohtani, H. ; Tsuge, S. ; Yano, T. Anal. Chem. 1994, 66, 1444.
305
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
148
EGA thermogram
Averaged mass spectrum 29 43 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
60 70
98
85
50
114
126
138
152
100
164 200 [m/z]
150
( m/z range : 29 - 600 amu )
PA : pyruvic aldehyde
M : hydroxyacetaldehyde
43
31
O
HO O
O 29 56
60
42
72
72
FA : 2-furfural
AO : acetone alcohol 43
96
O
O OH
O 39
31
74
29
53
55
FO : 5-methylfuran-2(3H)-one
P : 5-(hydroxymethyl)dihydro-2(3H)-furanone 98
H3C
O
82
67
114
O
O
O
OH 58
55 42
29 69
29
84
110
42
128
G : 3,6-dianhydro-α -glucopyranose 43
97
O O OH
69
85
LO : 5-(hydroxymethyl)-2-furfural O
57
29
68
126
41
O
O
85
69 96
OH
116 128
29
L' : 2-hydroxy-6,8-dioxabicyclo[3.2.1]octan-4-one
81
29
109
60
O
O
O HO
97
O
OH 43
140
L : levoglucosan
O 144 87
53
142
OH
57 73
69 113
29 126 146
43 89
98
115 126 144
167 182
OH
205 220
306
Tsuge, Ohtani and Watanabe
149 Methylcellulose; MC CH2OR H
B
O
O
H OR
H
H
OR
H n
R=H , CH3
A LB
IP TIC
0
10
Peak Notation LB A IP B
Assignment of Main Peaks CO2 + acetaldehyde methanol isopentane O
O
30 [min]
20
Molecular Retention Weight Index 44; 44 32 72 74
[ Related Reference ] 1) Schwarzinger, C.; Tanczos, I.; Schmidt, H. J. Anal. Appl. Pyrolysis 2002, 62, 179.
150 320 454 580
Relative Intensity 80.3 100.0 19.5 94.5
307
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
149
EGA thermogram
Averaged mass spectrum 45 29 100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55
71
87
50
97
111
127
141
100
155
173
205
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
A : methanol
B : methoxyacetaldehyde 31
45
H H
O
O H
H 29
44
58
55
74
O
308
Tsuge, Ohtani and Watanabe
150 Ethylcellulose CH2 OC2H5 H
O H OC2H5 H
O H
B
OC2 H5
H
n
C F
EO
D
K
HI G
J
E LB
A 10
20
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB EO A B C D E F G H I J K
propylene etc. ethanol unidentified unidentified unidentified unidentified unidentified unidentified unidentified unidentified unidentified unidentified unidentified
30 [min]
20
Molecular Retention Weight Index 295 465 46 654 82 ? 1175 156 1199 150 1270 172 ? 1293 1490 200 1611 198 1724 262 1775 290 2438 246 2752 318
Relative Intensity 65.5 100.0 53.5 29.2 25.0 7.1 16.1 21.3 16.9 18.6 17.4 16.5 24.3
309
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
150
EGA thermogram
Averaged mass spectrum 31 59 43 97
71
100
200
300
400
500
85
600
700 ºC
programming rate: 20ºC/min
113
125 141 155 169 183
50
100
150
201 202
229
246
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
A : unidentified
EO : ethanol 31
59
31
OH 45
45 69
B : unidentified
C : unidentified 83
83 156
43 29
78
111
43 55
99
111
29
71
55
127
71
E : unidentified
156
99 127
F : unidentified 97
113 141
59
171
85
29 59
31
69
41
125
85
115
143
41
200 97
69
125
155
H : unidentified
156
170
202 217
I : unidentified
59
59
141
101 73 85
129
43
86
29
116
29
159 145 174 173
43
73
262 199 216
101
117 129 157171 187 199 216
244
244
290
K : unidentified
J : unidentified
116
125
116 59 29
73 43
201
81 101 139155
183
202
247 259
301
333
59 85 172 217 2943 73 101 129 155 201 245
319 291
361
405
508
310
Tsuge, Ohtani and Watanabe
151 Cellulose acetate; CA CH2OCOCH3 H
O H OCOCH3 H
O
H
OCOCH3
H
G
LB
n
I F A
B
C D 5
H
JK
E
10
20
15
AA
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB A AA B C D
CO2, ketene H2C=CO, etc. acetic acid acetic anhydride 2-hydroxyethyl acetate unidentified (acetic ester) unidentified
E F G H I J K
O
O
unidentified unidentified unidentified unidentified unidentified unidentified
(acetic ester)
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
60 102 104 110 110
150 623 721 766 846 984
40.6 100.0 0.4 15.2 2.8 0.8
124
1288
0.9
186
1328
3.3
158 170 186 184 228
1344 1371 1505 1556 1599
6.1 2.8 4.1 2.8 2.6
311
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
151
EGA thermogram
Averaged mass spectrum 43
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
60
29
97
81
69 50
110
126
139
100
157 200 [m/z]
150
( m/z range : 29 - 600 amu )
AA : acetic anhydride
A : acetic acid 45
43
O
O
O
60
OH
O
29
94
60 65
62
B : 2-hydroxyethyl acetate
C : unidentified
43
53
O
81
HO O 29
73
60
43
E : 4,6-dimethyl-2H-pyran-2-one
63
95
F : unidentified
96
O
31
91
43
124
53 43
O 81
114 109
67
57
29
G : unidentified
73
156
43
82
82 54 71
98 110 125
142
184
54
29
99
71
113 125
142
184
J : unidentified
I : unidentified
43
43
70 82 31
126 141
H : unidentified
43
29
86 98
54
69 100 112 124
142 157 171 185
29
54
82
100 112 126
142 171 185
312
Tsuge, Ohtani and Watanabe
152 Cellulose acetate-propionate; CAP CH2 OR H
O
O
H OR
H
H
OR
R=COCH3 or COC2H5
H n
DB
LB AP BP D
AC TIC
A
P
0
PA
B
E F G
C
H
10
BS 30 [min]
20
Peak Notation
Assignment of Main Peaks
LB AC A P AP PA B C D E F G H DB BP BS
CO2 , propylene etc. acrolein acetic acid propionic acid hydroxy-2-butanone ? propionic anhydride unidentified unidentified unidentified unidentified unidentified unidentified C O O C 4H 9 unidentified dibutyl phthalate (plasticizer) C O O C 4H9 butyl palmitate CH3(CH2)14COO(CH2)3CH3 (plasticizer) butyl stearate CH3(CH2)16COO(CH2)3CH3 (plasticizer)
Molecular Retention Weight Index 56 60 74 88 130 130 180 182 222 ? 206 ? 212 256 278 312 340
150 490 607 773 868 937 985 1335 1528 1607 1624 1686 1782 1981 2150 2350
Relative Intensity 37.5 8.1 3.9 100.0 23.6 2.2 1.1 2.6 5.2 3.8 4.4 4.7 5.9 73.4 12.5 3.8
313
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
152
EGA thermogram
Averaged mass spectrum 57
149
29
100
200
300
400
500
74
45
600
700 ºC
programming rate: 20ºC/min
81
97104
50
126135
177
100
150
205
223
2 00
300 [m/z]
250
( m/z range : 29 - 600 amu )
A : acetic acid
AC : acrolein 56
43
O
O OH 60
29
44 29
72
P : propionic acid
AP : hydroxy-2-butanone
29
O
82
57
O
74
45
29
OH
HO
57 87
42
84
D : unidentified
PA : propionic anhydride 57
O
57
O
29
O 29 82 43
72
83
95
39
110
E : unidentified
75
131139 156
99 110
F : 4-(1,1,3,3-tetramethylbutyl) phenol 149
O O O
212
135
O HO
29
39
57 65 76
177 93 105 121132
166
195
222
29
41
57 95
65 77
107 119
149
206
H : unidentified
G : unidentified
57
57
29
29 41
69 82
98 113 98 110 126 138 156 171 185
213
39
68
85
126
139
154 170
182 200
314
Tsuge, Ohtani and Watanabe
153 Cellulose acetate-butyrate; CAB CH2OR H
O
O
H OR
H
H
OR
R=COCH3 or COC3H7
H n
LB
C AB
A MB B
F G
TIC
0
10
Peak Notation
Assignment of Main Peaks
LB MB A C B AB F G
CO2 methylbutene acetic acid 2-hydroxyethyl acetate butanoic acid CH3CH2CH2COOCOCH3 unidentified unidentified
30 [min]
20
Molecular Retention Weight Index 44 70 60 88 130 -
150 480 608 766 829 955 1328 1344
Relative Intensity 27.8 7.4 100.0 22.5 79.8 14.6 4.1 5.2
315
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
153
EGA thermogram
Averaged mass spectrum 43
100
200
300
400
500
60
600
700 ºC
programming rate: 20ºC/min
29
71
81
97
50
109
126
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
MB : methylbutene
A : acetic acid 45
55
O
70
60
OH 39
29
29
82
62
B : n-butanoic acid
C : 2-hydroxyethyl acetate 43
60
O
O
HO OH
O 73
41 29
29
73
60
88
91
112
F : unidentified
AB : acetic butyric anhydride 43
43
O
O 71
O 114 29
87
55
101
29
110
G : unidentified 43
82 29
54 72
99
125
142
184
57 70
86 98
126135
156
316
Tsuge, Ohtani and Watanabe
154 Hydroxyethylcellulose; HEC CH2OR H
O H OR
H
H
OR
O H
n
R=H , or(CH2)2OH
LB C E D
A B
AA
F ED TIC
G
HA
0
10
Peak Notation LB AA HA ED A
Assignment of Main Peaks CO2 acetaldehyde hydroxyacetaldehyde ethylene glycol O
O OH
B C D E F G
diethylene glycol HO(CH2CH2O)3H HO(CH2CH2O)3CH2CHO HO(CH2CH2O)4H HO(CH2CH2O)4CH2CHO HO(CH2CH2O)5H [ Related Reference ] 1) Arisz, P. W.; Boon, J. J. J. Anal. Appl. Pyrolysis 1993, 25, 371.
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
44 44 60 62
150 403 650 706
104
906
66.4
110 150 192 194 236 238
982 1239 1470 1514 1745 1796
100.0 84.0 44.9 43.0 19.2 14.7
94.9 35.3 14.5 89.4
317
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
154
EGA thermogram
Averaged mass spectrum 45
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
31 58
89 90
75
112 119
50
133
100
200 [m/z]
150
( m/z range : 29 - 600 amu )
AA : acetaldehyde
HA : hydroxyacetaldehyde 31
29
HO
O
O 44
58
42
60
72
A : 1,4-dioxan-2-ol
ED : ethylene glycol 31
45
HO
O
OH
O
58 29
OH 74 43
62 61
87
86
C : triethylene glycol
B : diethylene glycol 45
45
O HO
OH
58
D : 2-(2-(2-hydroxyethoxy)ethoxy)ethoxy)
HO
O
O
O
45
O
58
31
163
F : 14-hydroxy-3,6,9,12-tetraoxatetradecan-1-al
75
45 O
O
O
O
O
O
OH
119 133
163
O
O
O
OH
89
58 73
90
O
HO
O
87 31
119
G : pentaethylene glycol
45 HO
105
OH
89 119 103 117 133
75
O
HO
87 58
89 90
75
O
E : tetraethylene glycol
acetaldehyde 45
58
31
110
96
O
HO
75 76
31
31
104 103
103 117 119 133 147
163 175
31
58
73
119 133 103 115
151 163
195
318
Tsuge, Ohtani and Watanabe
155 Carboxymethyl cellulose; CMC CH2OR H
LB
AA TIC
O H OR
H
H
OR
O H n
R=H , or CH2COOH Degree of etheration 0.8~1.0
BD
HA AO
A
0
10
Peak Notation
Assignment of Main Peaks
LB AA HA BD AO
CO2 acetaldehyde hydroxyacetaldehyde 2,3-butanedione acetone alcohol
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
44 44 60 86 74
150 403 653 690 707
100.0 6.8 4.4 3.2 8.5
126
1061
2.0
O
A
OH
319
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
155
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
29
57
85
69
50
91 150 [m/z]
100
( m/z range : 29 - 600 amu )
AA : acetaldehyde
HA : hydroxyacetaldehyde 31
29
HO
O
O
43
58
44
60
72
AO : acetone alcohol
BD : 2,3-butanedione 43
O
43
O
OH O 86
60
31
70
55
A : 2-hydroxy-3,4-dimethyl-2-cyclopenten-1-one 126
O OH 41 111
56 69 31
83 97
31 74
320
Tsuge, Ohtani and Watanabe
2.2.19 The other natural polymers, etc 156 Glue
LB
G H
B C
A TIC
E F
D 0
10
Peak Notation
30 [min]
20
Assignment of Main Peaks
Molecular Retention Weight Index
Relative Intensity
LB
CO2
44
150
A
acetaldehyde
44
408
5.4
B
pyrrole
67
755
15.3
C
toluene
92
766
6.4
D
1-ethylpyrrole
95
814
1.1
E
2-methylpyrrole
81
844
3.3
F
phenol
94
985
2.7
154
1781
45.5
210
2221
13.0
N
G
O
N
N
H N
O
N
100.0
O
H
N N O
OH
321
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
156
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55
70
29
84
94 111
50
124 134
100
154
170
186 192
150
210 250 [m/z]
200
( m/z range : 29 - 600 amu )
A : acetaldehyde
B : pyrrole
29
O
67
H N
44
41
64
33
81
52
52
D : 1-ethylpyrrole
C : toluene 91
95
80
N 44 29 39
65
51
53
67
89
F : phenol
E : 2-methylpyrrole 80
H N
94
OH
53 39
41
29
G : hexahydropyrrolo[1,2-a]pyrazine-1,4-dione N N
O N
41
86 70 98
55 126 135
166
186
29
N
124
41
55 30
107
70 154
83
O
81
H : 2-hydroxyoctahydrodipyrrolo[1,2-a:1',2'-d]pyrazine-5,10-dio
111
O
65 55
29
93
66
OH 210
O 96 112
138
154 165 182193
223
322
Tsuge, Ohtani and Watanabe
157 Shellac CH2OH (CH2)5 CHOH CH (CH2)7 O O
H
n
O O
R R
D E
FG
LB B
TIC
A
C
0
10
Peak Notation LB A B C D E F G H
Assignment of Main Peaks CO2 unidentified CH3(CH2)5CHO (CH3)2C=CH(CH2)2CH=C(CH3)2 unidentified unidentified unidentified unidentified unidentified
30 [min]
20
Molecular Retention Weight Index 44 114 138 -
[ Related Reference ] 1) Wang, L.; Ishida, Y.; Ohtani, H.; Tsuge, S.; Nakayama, T. Anal. Chem. 1999, 71, 1316.
150 842 902 995 1181 1485 1912 1961 2256
Relative Intensity 54.1 4.3 7.4 5.9 56.7 88.1 25.3 38.3 100.0
323
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
157
EGA thermogram
Averaged mass spectrum 55
41 67
81
91
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
131
29
105
50
135 148
100
150
203
217
171 187189
232
244
200
300 [m/z]
250
( m/z range : 29 - 600 amu )
B : heptanal
A : unidentified 67
96
70
41
O
55
39 53
29
81
81
29
96 108
110
128
D : unidentified
C : 2,7-dimethyl-2,6-octadiene
69
69 55
41 41
84
29 82
55
29
95
107
123
E : unidentified 55
97
138
112
F : unidentified 189
73 83
41
111 204 91
29
98
129 144
107
77
154 162174
41 55 67 213
G : unidentified
133 131
159 171 175
29
H : unidentified 113
173 91
55 41 29
216 234
73
117
131 145
77
85 102
131 141 148
41
216 234 256
29
55
67
155 174
246 189
202
218
324
Tsuge, Ohtani and Watanabe
158 Chitin CH2OH H
LB
O
O
H OH
H
H
NHCOCH3
H n
C D
B HA A TIC
AAc
AAm
Pr Pd
0
10
Peak Notation LB A HA AAc Pd Pr AAm B C D
Assignment of Main Peaks CO2 etc. acetaldehyde hydroxyacetaldehyde acetic acid pyridine pyrrole acetamide C6H7NO2 ? C7H7NO2 ? unidentified
30 [min]
20
Molecular Retention Weight Index 44 60 60 79 67 59 125 137 185
? ? ?
150 408 651 607 748 757 782 1010 1224 1894
Relative Intensity 65.7 13.6 12.6 56.9 3.7 3.6 33.4 33.7 25.0 100.0
[ Related References ] 1) van der Kaaden, A.; Boon, J. J.; de Leeuw, J. W.; de Lange, F.; Schuyl, P. J. W. Anal. Chem. 1984, 56, 2160. 2) Lal, G. S.; Hayes, E. R. J. Anal. Appl. Pyrolysis 1984, 6, 183. 3) Franich, R. A.; Goodin, S. J. J. Anal. Appl. Pyrolysis 1984, 7, 91. 4) Davies, D. H.; Hayes, E. R.; Lal, G. S. R. A. A. Muzzarelli, C. Jeuniaux, G. W. Gooday (Eds.), Chitin in Nature and Technology, Plenum Press, New York 1986, 365. 5) Sato, H. ; Tsuge, S. ; Ohtani, H. ; Aoi, K. ; Takasu, A. ; Okada, M. Macromolecules 1997, 30, 4030. 6) Sato, H. ; Mizutani, S. ; Tsuge, S. ; Ohtani, H. ; Aoi, K. ; Takasu, A. ; Okada, M. ; Kobayashi, S. ; Kiyosato, T.; Shoda, S. Anal. Chem. 1998, 70, 7. 7) Sato, H. ; Ohtani, H. ; Tsuge, S. ; Aoi, K. ; Takasu, A. ; Okada, M. Macromolecules 2000, 33, 357.
325
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
158
EGA thermogram
Averaged mass spectrum 44
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
59
29
84 91
69
105
50
125
139
152
100
167 200 [m/z]
150
( m/z range : 29 - 600 amu )
A : acetaldehyde
HA : hydroxyacetaldehyde 31
44
29
HO
O
O
60
42
56
72
62
78
Pd : pyridine
AAc : acetic acid 43
79
N
O 60
52
OH
29
44
31
82
62
Pr : pyrrole
97
69
AAm : acetamide 67
H N
59
O
44
NH 2 39
55
29
79
31
B : C6H7NO2
C : C7H7NO2 43
109
30
73 39 68 86
58
95
109
29
125
D : C7H9NO2 59
43 101 114 72 29
85
130139
160
185
54
81
137
95
122
326
Tsuge, Ohtani and Watanabe
159 Chitosan CH2OH H
LB
O
O
H OH
H
H
NH2
H n
HA D A TIC
AP
AA P
0
10
Peak Notation LB A HA AA P AP D
Assignment of Main Peaks CO2 acetaldehyde hydroxyacetaldehyde ? acetic acid pyrazine acetylpyrazine C7H9NO2 ?
30 [min]
20
Molecular Retention Weight Index 44 44 60 60 80 122 139
150 408 ? 656 602 732 1025 ? 1869
Relative Intensity 100.0 31.0 38.0 23.0 20.6 15.4 35.3
[ Related References ] 1) Mattai, J.; Hayes, E. R. J. Anal. Appl. Pyrolysis 1982, 3, 327. 2) Lal, G. S.; Hayes, E. R. J. Anal. Appl. Pyrolysis 1984, 6, 183. 3) Sato, H. ; Mizutani, S. ; Tsuge, S. ; Ohtani, H. ; Aoi, K. ; Takasu, A. ; Okada, M. ; Kobayashi, S. ; Kiyosato, T. ; Shoda, S. Anal. Chem. 1998, 70, 7.
327
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
159
EGA thermogram
Averaged mass spectrum 44
29
100
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
55
80
67
94 109
50
131132
146
100
160 200 [m/z]
150
( m/z range : 29 - 600 amu )
A : acetaldehyde
HA : hydroxyacetaldehyde 31
44
29
HO
O
O
60
42
58
AA : acetic acid
72
79
P : pyrazine 43
60
80
N
O OH
N 53
29 70
79
38
D : C7H9NO2
AP : acetylpyrazine O
29
122
43
N
59
80 52
94
N
43 101 114
29
67
107
72 29
84
130139
158
185
328
Tsuge, Ohtani and Watanabe
160 Ivory
LB
D
P AN TIC
C CP
MP
0
10
Peak Notation LB AN CP P MP C
Assignment of Main Peaks CO2 acetonitrile 1-vinylaziridine pyrrole 1-methylpyrrole 2-methylpyrrole p-cresol N
D O
N
O
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
44 41 69 67 81 81 108
150 470 681 757 842 852 1078
100.0 22.4 20.0 33.8 8.3 5.4 16.6
154
1772
82.1
329
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
160
EGA thermogram
Averaged mass spectrum 44
100
55
200
300
400
500
70
83
29
111
50
600
700 ºC
programming rate: 20ºC/min
94 124 136
100
154
164
186192
150
210 250 [m/z]
200
( m/z range : 29 - 600 amu )
AN : acetonitrile
CP : 1-vinylaziridine 41
N
41
N
29
57
69
64
56
29
P : pyrrole
84
99
MP : 1-methylpyrrole 67
H N
80
N 41 53 33
52
79
41
29
68
C : p-cresol
MP : 2-methylpyrrole 80
H N
107
OH 42
42
53 93
29
111
D : hexahydropyrrolo[1,2-a]pyrazine-1,4-dione N O
83
O
111
154
70
N 41 55 30
97
55 67
29
93
98 126 143
186
77 68 125 138
153
330
Tsuge, Ohtani and Watanabe
161 Synthetic lignin; DHP
F
H
C
D
B A
TIC
E
0
10
Peak Notation A
30 [min]
20
Assignment of Main Peaks H 3CO
Molecular Retention Weight Index
Relative Intensity
124
1095
8.6
CH 3
138
1200
22.7
CH=CH2
150
1325
27.2
164
1462
27.2
180
1685
2.0
178
1756
100.0
358
3263 3272
95.8
HO
B
H 3CO HO
C
H 3 CO HO
D
H 3 CO
CH=CHCH3
HO
E
H3CO HO
F
CH2OH
H 3CO C HO HO
H
O
H3CO HO
OH O OCH3
331
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
161
EGA thermogram
Averaged mass spectrum 137
100
29 39
51
200
300
400
500
151
123 77
600
700 ºC
programming rate: 20ºC/min
91
65
109
50
164 178
100
298 312 326 340 358 199205 216 241 255 260 284
150
200
250
300
400 [m/z]
350
( m/z range : 29 - 600 amu )
B : 2-methoxy-4-methylphenol
A : 2-methoxyphenol 109
HO O
138
123
O
124
HO
81
95 53 29
39
65
67
55
39
95
77
110
29
D : (E)-2-methoxy-4-(1-propenyl)-phenol
C : 2-methoxy-4-vinylphenol 150
O
O
HO
HO
164
135
149
77 107
77
51 39 63 91 118 29
341
429
29
39
55
103
65
104
131 133
E : 4-((1E)-3-hydroxy-1-propenyl)-2-methoxyphenol F : 4-hydroxy-2-methoxycinnamaldehyde 137
O
178
O
OH
O
180
HO
124
HO
135
91 29 39
55 65
77
190
161
29 39
206 219
H1 : 4,4'-(hexahydrofuro[3,4-c]furan1,4-diyl)bis(2-methoxyphenol) 151
107
77
151
109
161 192
H2 : 4,4'-(hexahydrofuro[3,4-c]furan -1,4-diyl)bis(2-methoxyphenol) O
O
151
O
O
147
124
91
51 63
OH
OH HO
HO O 137 131 29
55 81 103
137
358
131 163 205 180 221 259
327
403
O
O
O
542
29
39
55
77 65
109
358 163 205 189 221
259
299
327 343
332
Tsuge, Ohtani and Watanabe
162 Wood powder
LB
tE cE Va Eu
VS a
S
cP
VG HAa
tP
MG
SA AS
Fa
G
TIC
tS
cS
0
10
Peak Notation LB HAa
Molecular Retention Weight Index
Assignment of Main Peaks CO2 etc. hydroxyacetaldehyde O
30 [min]
20
Relative Intensity
-
150
30.6
60
652
4.1
96
835
3.5
124
1095
2.1
CHO
Fa
furfural
G
guaiacol
MG
4-methylguaiacol
138
1200
5.2
VG
4-vinylguaiacol
150
1325
6.0
S
syringol
154
1360
4.0
Eu
eugenol
164
1368
0.5
152
1411
0.8
164
1420
0.2
164
1462
2.0
162
1475
100.0
180
1576
10.3
194
1663
1.2
194
1713
7.8
196
1748
1.4
210
1929
0.3
208
1999
3.2
210
2005
2.0
HO CH3O
CH 3O HO CH 3O
HO
CH2CH=CH2
HO CH 3O
CHO
Va
vanillin
cE
cis-isoeugenol
HO
tE
trans-isoeugenol
CH3O
a
levoglucosan
VS
vinylsyringol
cP
cis-propenylsyringol
CH3O
CH=CHCH3
OCH3 OCH=CH2 CH 3O
OCH3
tP
trans-propenylsyringol
AS
acetosyringon
cS
cis-sinapylalcohol
C H3O
CH 3COO
HO CH 3O
O C
C H3
CH3O
trans-sinapaldehyde HO
tS
trans-sinapylalcohol
CH3O
CH3O HO
CH3O
SA
CH=CHCH3
CH =CHCH2OH
CH3O CH=CHCHO CH3O HO CH3O
CH=CHCH2OH
[ Related References ] 1) Genuit, W.; Boon, J. J.; Faix, O. Anal. Chem. 1987, 59, 508. 2) Faix, O.; Meier, D.; Fortmann, I. Holz als Roh- und Werstoff 1990, 48, 281 3) Kleen, M.; Gellerstedt, G. J. Anal. Appl. Pyrolysis 1991, 19, 139. 2) Kuroda, K.; Yamaguchi, A. J. Anal. Appl. Pyrolysis 1995, 33, 51. 5) Rodrigues, J.; Meier, D.; Faix, O.; Pereira, H. J. Anal. Appl. Pyrolysis 1999, 48, 121. 6) Yokoi, H. ; Ishida, Y. ; Ohtani, H. ; Tsuge, S. ; Sonoda, T. ; Ona, T. Analyst 1999, 124, 669. 7) del Rio, J. C.; Gutierrez, A.; Martinez, M. J.; Martinez, A. T. J. Anal. Appl. Pyrolysis 2001, 58-59, 441. 8) Martinez, A. T.; Camarero, S.; Gutierrez, A.; Bocchini, P.; Galletti, G. C. J. Anal. Appl. Pyrolysis 2001, 5859, 401.
333
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
162
EGA thermogram
Averaged mass spectrum 60
29
100
43
200
300
400
500
600
700 ºC
programming rate: 20ºC/min
73 97
85 50
114 126
144 150 167 180 196 213 216
100
150
302
200
250
350 [m/z]
300
( m/z range : 29 - 600 amu )
HAa : hydroxyacetaldehyde
Fa : furfural
31
96
O
HO O
O 39
42
60
29
72
G : guaiacol
67
50
82
108
MG : 4-methylguaiacol 109
HO
110
HO 124
138
123
O
O
81
64 29
53
39
55
39
65
92
VG : 4-vinylguaiacol
95 77
29
144
151
S : syringol 150
O
154
OH
135
O
O
HO 139 107
77 29
39
51 63
91
118
29
a : levoglucosan
51
65
96 79
125
166
VS : vinylsyringol
60
180
O O HO OH
73
O O
O
OH
165 137
29 43 89
98
115 131 144 160
205
tP : trans-propenylsyringol
29 39
220
51
65
77
91
105
122 151
AS : acetosyringon
O
181
OH
194
HO O
39
111
O
O 196
O 65 29 39 53
77
91 105
119
167 179 133 151
204
29
43
53 67
82 93 108 123 138
153 167
219 234
334
Tsuge, Ohtani and Watanabe
163 Gluten
b LB
PA
C
T
0
10
Peak Notation
c
Gl a
P
TIC
Assignment of Main Peaks
LB T P C GI
CO2 etc. toluene phenol p-cresol glutamic acid
a
HN
O
30 [min]
20
Molecular Retention Weight Index
Relative Intensity
92 94 108 147
150 767 983 1078 1688
98.3 23.7 5.4 21.8 58.6
154
1767
8.4
208
2292
100.0
244
2410
15.9
N O
b
unidentified O
c
HN N O
335
Pyrograms and Thermograms of 163 High Polymers, and MS Data of the Major Pyrolyzates
163
EGA thermogram
Averaged mass spectrum 44 84 70 55 100
200
300
400
500
91
29
600
700 ºC
programming rate: 20ºC/min
107
50
154
125
138
100
208 165
180
228 239 244
199
150
250 [m/z]
200
( m/z range : 29 - 600 amu )
T : toluene
P : phenol 91
94
OH
66 39
51
39
65
89
55
29
C : p-cresol
79
110
Gl : glutamic acid 84
107
OH
O
O OH
HO NH2 77 41
51
95
41
68
30
66
98
113 128 140 150 165
b : unidentified
a : 1,4-diazabicyclo[4.3.0]nonane-2,5-dione 83
56
29
70
111 154
O
208
70
HN
41
N
55
98
30
41
126 135
O
175 199 216
343
c : hexahydro-3-(phenylmethyl) pyrrolo[1,2-a]pyrazine-1,4-dione 125
O HN N O 70 41 29
55
77
244 91
153 104
132
174
201
242
29
96 55
84 111
124
152 138
166
180
189
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PART 3
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline 3.1. EXPERIMENTAL CONDITIONS FOR MEASURING PYROGRAMS AND MS DATA OF THE MAJOR PYROLYZATES FOR THE CONDENSATION POLYMERS BY MEANS OF REACTIVE PYROLYSISGC/MS IN THE PRESENCE OF ORGANIC ALKALINE 3.1.1. Polymer samples In the following data acquisition, 33 condensation polymer samples selected from the 163 samples used in Part 2 for conventional pyrolysis were subjected to analysis like in the former edition.*
3.1.2. Measuring conditions for the pyrograms of the polymers and the MS data of the major peaks on each pyrogram by use of reactive pyrolysis in the presence of organic alkaline Figure 3.1 illustrates the schematic flow diagrams of the measuring systems of the reactive Py-GC/MS in the presence of organic alkaline, tetramethylammonium hydroxide [(CH3)4NOH, TMAH].** A methanol solution (25 wt%) of TMAH supplied by Aldrich (Steinheim, Germany) was used as the organic alkaline reagent. About 2 ml of the reagent solution was added to powdered polymer sample (ca. 50 mg) weighed into the same deactivated stainless steel sample cup used in Chapter 2.1.2 before mounting the cup into the pyrolyzer of which temperature was maintained at 420 � C to promote specific hydrolysis followed by methylation suppressing the contribution of conventional thermal decomposition. Basically the same Py-GC/MS measuring system shown in Figure 2.1 was used under the same conditions except for this sampling technique and the lower reaction temperature (420 � C) setting. The products formed through the specific reactions for a given condensation polymer were separated by a stainless steel capillary column (Frontier Lab. Ultra ALLOY-5) * Tsuge S, Ohtani H, Watanabe C. “Pyrolysis-GC/MS of high polymers - fundamentals and pyrogram compilations”. Techno System Co., Tokyo, 2006. ** Challinor J. M. J Anal Appl Pyrol 1989, 16, 323–333.
Pyrolysis-GC/MS Data Book of Synthetic Polymers/Tsuge ISBN 978-0-444-53892-5, Doi:10.1016/B978-0-444-53892-5.10003-3
Ó 2011 Elsevier B.V. All rights reserved.
337
j
338
Tsuge, Ohtani and Watanabe
Pyrolyzer He TMAH solution
sample cup
powder sample
vent
separation column GC/MS adaptor
GC Oven
Q-MS
Figure 3.1 Schematic flow diagram of Py-GC/MS system (from the upper to the lower flow). (a) Carrier gas: 100 ml/min of He flow at the pyrolyzer, 1 ml/min at the separation column through a splitter (1/100); (b) pyrolyzer: a micro-furnace pyrolyzer (Frontier Lab., PY-2020iD) at 420 � C; (c) Pyrolyzer/GC interface temperature: 320 � C; (d) GC injection temp.: 320 � C; (e) sample size: ca. 50 mg weighed into a sample cup (ECO CUP-L: (o.d. 4.2 � i.d. 4.0 � 8 mm height, deactivated stainless steel cup); (f) GC separation column: Ultra ALLOY-5 (0.25 mm � 30 m; 0.25 mm of 5%diphenyl–95%dimethylpolysiloxane film), temp. programmed from 40 � C (2 min hold) – (20 � C/min) – 320 � C (13 min hold); (g) GC/MS interface temp.: 320 � C; (h) EI source (70 eV) temp.: 230 � C; (i) MS scan range: 29–600 (m/z) at 2000 amu/sec.
coated with 5%diphenyl–95%dimethylpolysiloxane liquid phase under a programming temperature condition; 40 � C (2 min hold) – (20 � C/min) – 320 � C (13 min hold). Thus, obtained mass spectrometric data for all the peaks on the pyrograms stored as the total ion chromatogram (TIC), and the selected mass spectra of the top 6 major peaks at most were compiled on this data book, together with the retention index (RI) data of the main peaks on the pyrograms. Typical reaction passes for condensation linkages in the presence of TMAH are as follows. O R1 C
O O R2
(CH3)4NOH
R1 C O
CH3
H3C O R2
O R3
O C O R4
(CH3)4NOH
R3 O
CH3
H3C O R4
CO2
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
3.1.3. Data descriptions for the reaction pyrograms and the MS data of the major peaks on the pyrograms for 33 condensation polymer samples In the following Chapter 3.2, one page was allocated for the most condensation polymers. For example, the observed data for poly(acrylic acid) is given in page 340. At the top of the page, you can find the following statements:
R01 [042] Poly(acrylic acid); PAA CH 2CH(COOH)
n
where the sample number, R01 (042) is followed by the full name with its abbreviation and chemical structure. Here, “R01” designates the No. 01 for the series of Reaction Pyrolysis Data, and the following number in the parenthesis, (042) corresponds to that in Chapter 2.2 for the conventional pyrolysis data number. The upper display is its reaction pyrogram at 420 � C, where most of the prominent components are formed through reactive pyrolysis in the presence of TMAH. Under the pyrogram, you can see the peak assignment table for the pyrogram together with molecular weight (MW), retention index (RI), and relative peak intensity data. At the bottom of the page, the selected mass spectra for up to the top 6 major peaks are compiled. On the other hand, facing two pages were allocated for some of the condensation polymers yielding more than 6 well-assigned mass spectra for their pyrolyzates. For example, as shown in the facing two pages (pp. 344–345), at the top of the associated first page, you can find the statements for unsaturated polyester as follows:
R04 [104] Unsaturated polyester; UP CH2CH(C6H5)
CHCHCOOCH2CH2OCO
COOCH2CH2OCO
n
where the sample number, R04 (104) is followed by the full name with its abbreviation and chemical structure. The upper display is its reaction pyrogram at 420 � C, followed by the peak assignment table for the pyrogram together with MW, RI, and relative peak intensity data. As the footnote, the related references in which the concerned pyrolysis information is reported were listed. At the right hand page, its selected mass spectra for up to 12 major peaks are compiled.
339
340
Tsuge, Ohtani and Watanabe
3.2 DATA COMPILATION OF PYROGRAMS OF 33 CONDENSATION POLYMERS THROUGH REACTIVE PYROLYSIS R01 [042] Poly(acrylic acid; isotactic); PAA CH 2CH(COOH)
n
M3
M5
M2
M4
M6
M2 ’
2
10
Peak Notation M2’ M2 M3 M4 M5 M6
Assignment of Main Peaks C(COOC)-C-C-COOC C=C(COOC)-C-C-COOC (dimer) C=C(COOC)-C-C(COOC)-C-C-COOC (trimer) C=C(COOC) C-C(COOC) 2C-C-COOC (meso (m)) C=C(COOC) C-C(COOC) 2C-C-COOC (racemic (r)) C=C(COOC) C-C(COOC) 3C-C-COOC(pentamer) C=C(COOC) C-C(COOC) 3C-C-COOC (hexamer) *bonding hydrogen is omitted
25 [min]
20
Molecular Retention Index Weight 160 172 258 (tetramer) 344 430 516
1150 1211 1691 2127 2138 2556 2966
Relative Intensity 19.9 31.4 100.0 26.5 25.2 77.9 47.8
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R01 [042]
M2' : dimethyl glutarate O
O O
M2 : dimethyl 2-methylenepentanedioate 112
59 O
O
100
O
O 140
129 42
59
O 39
87
29
81 97
29
74
121
M4 : tetramethyl oct-7-ene-1,3,5,7-tetracarboxylate (meso form)(tetramer)
M3 : trimethyl hex-5-ene-1,3,5-tricarboxylate O
O
O
O
O
O
59
O
133
194
161
59 106 79 167
227
O O
O O
O
192 220
105
252
313 280
153
29
M5 : pentamethyl dec-9-ene-1,3,5,7,9-pentacarboxylate (pentamer)
100 79 112 41 67
91
41
125
41 29
59
O O
134
79
314
M6 : hexamethyl dodec-11-ene-1,3,5,7,9,11hexacarboxylate(hexamer)
O
187
O
O
O
O
247 275
O
O
O
O
59
O
O
79
306 334
399 366
100
O
172 153
41 31
O
O
O
O
O
O
O
O
O
O
227 361 325
420
485
341
342
Tsuge, Ohtani and Watanabe
R02 [099] Diallyl phthalate resin; DAP CH2CHCH2OCO
COOCH2CHCH2
n
BD
PA
MB
M
2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
MB
methyl benzoate
Molecular Weight COOCH 3
Retention Index
Relative Intensity
136
1102
1.4
148
1328
6.6
194
1470
100.0
246
1761
0.3
O
PA
phthalic anhydride
O
COOCH 3
O
BD COOCH 3
C OOCH2CH=CH 2
M
(monomer)
COOCH 2CH=CH2
MB : methyl benzoate
PA : phthalic anhydride O
105
O
104 76
O
O
77
O
136
50
51
74 74
29
148
38
91
BD : dimethyl phthalate
M : diallyl phthalate (monomer) 163
O
41
149
O O
O
O
O O
O
76
77 50
92
104
120 133
194
50 29
104 98
132
189 172
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R03 [100] Poly(ethylene glycol bisallyl carbonate); CR-39 CH2 CHCH2 OCOOCH2 CH2 OCH2OCOOCH2 CHCH2
n
B
A MB MC 2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
Molecular Retention Relative Weight Index Intensity
MC A B
CH3OCOOCH3 CH3OCH2CH2OCH2CH2OH CH3OCH2CH2OCH2CH2OCH3
90 120 134
613 944 954
3.2 51.5 100.0
MB
methyl benzoate
136
1102
16.0
COOCH 3
MC : dimethyl carbonate
A : diethylene glycol monomethyl ether
45
45
O
O
O
59
29
O
HO
59
O 29 62
B : diethylene glycol dimethyl ether 59
O
75
90
O
MB : methyl benzoate O
105
O O
29
89 90
77 136
45 51
89 75
102
29
39
74
92
343
344
Tsuge, Ohtani and Watanabe
R04 [104] Unsaturated polyester; UP CH2 CH(C6H5)
CHCHCOOCH2 CH2 OCO
COOCH2 CH2 OCO
n
BD
PA PB’ SS PB
S ME
BO MBBA
2
SSS DOP
10
Peak Notation
Assignment of Main Peaks
ME S BO MB BA PA
CH3OCH2CH2OCH3 styrene CH3OCOCH=CHCOOCH3 methyl benzoate benzoic acid phthalic anhydride
25 [min]
20
Molecular Retention Relative Weight Intensity Index 90 104 144 136 122 148
652 899 1023 1102 1168 1334
2.8 100.0 4.3 6.3 6.0 56.4
194
1146
97.3
196 194 208 312 390
1677 1697 1746 2493 2563
10.0 6.6 9.0 28.1 11.2
COOCH 3
BD COOCH 3
PB PB’ SS SSS DOP
CH2(C6H5)CH2CH2(C6H5) CH(C6H5)=CHCH2(C6H5) CH2=C(C6H5)CH2CH2(C6H5) (styrene dimer) CH2=C(C6H5)CH2CH2(C6H5) CH2CH2(C6H5) (styrene trimer) dioctyl phthalate
[ Related Reference ] 1) Challinor, J. M. J. Anal. Appl. Pyrolysis 1989, 16, 323.
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R04 [104]
ME : ethylene dimethyl ether
S : styrene 104
45
O O 78
103
51
29 60
39
90
BO : dimethyl fumarate
63
MB : methyl benzoate
O
105
113
O O
O
O
85
77
O
136 59
29
41
51 100
69
144
BA : benzoic acid
29
74
39
PA : phthalic anhydride 105
O
104
O 122
77
O
OH 51
31
O 74
38
76
50 74
94
29
BD : dimethyl phthalate
148
38
PB : 1,3-diphenylpropane 163
92
O O 105
O O 29 39
65
77 50
74
92 104
120 133
39
194
149
PB' : 1-propene-1,3-diyldibenzene
196
77
51
148
118
30
179
SS : 3-butene-1,3-diyldibenzene (styrene dimer) 162
91
104
76 50 29 41
74
132 92
121
51 29 39
149
SSS : 5-hexene-1,3,5-triyltribenzene
65
104
208
130
77
165 180 193
DOP : dioctyl phthalate
(styrene trimer)
149
91
O OC8H17 OC8H17
117 3951 65
77
194 207 129 152165 178 221234
167
O
57 312
29
43
71
83 93104 121132
279 178
202
231
260
345
346
Tsuge, Ohtani and Watanabe
R05 [105] Epoxy resin; EP CH2CH(OH)CH2O
C(CH3)2
OCH2CH(OH)CH2N
CH2
N
n
b
IP’
DM BA
P
IP
a
AD DA c
OC 2
10
Peak Notation
Assignment of Main Peaks
P OC IP IP’
phenol o-cresol p-isopropylphenol p-isopropenylphenol
a
H3CO
b
HO
DM
H 2N
C(CH3) 2
C(CH3)2
CH2
25 [min]
20
Molecular Retention Weight Index
OCH3
OCH3
NH 2 HO
C(CH3)2
OH
Relative Intensity
94 108 136 134
982 1059 1228 1304
31.6 9.6 21.6 100.0
256
2088
13.2
242
2144
94.0
198
2161
39.3
228
2197
29.9
226
2270
14.1
BA
bisphenol A
AD
H2N
DA
H3CH N
CH 2
N(CH 3) 2
240
2360
3.0
c
(H3C) 2N
CH2
N(CH 3) 2
254
2378
11.6
CH 2
N(CH 3) 2
[ Related Reference ] 1) Challinor, J. M. J. Anal. Appl. Pyrolysis 1989, 16, 323.
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R05 [105]
OC : o-cresol
P : phenol 94
108
OH
OH
77 66 39
90
51 39
55
29
79
63
30
IP : p-isopropylphenol
IP' : p-isopropenylphenol 134
121
OH
OH 119
91
136 91
77 29
39
39
65
51
29
107
a : 2,2-bis(4'-methoxyphenyl)propane
65
51
77
105
b : 2-(4'-hydroxyphenyl)-2-(4'-methoxyphenyl)propane 227
241 O
O
HO
242
256
133 152 165183195 211226 121
29 41 51 63 77 91
O
119 133 152 165 183 197 212
91 29 39 51 65 77
DM : diaminodiphenylmethane
BA : bisphenol A 198
213
HO
OH
NH 2
H 2N 106
182 65 77 30 39 52
93
130 143152
39 5565 77
91
119 107 135 152
228 181 198
DA : N,N-dimethyl-4-(4-(methylamino)benzyl)aniline
AD : 4-(4-aminobenzyl)-N,N-dimethylaniline 226
77 90 32 42 51 63
106118
120134
182
134 152 165
210 77 91 111 32 4251 65
196
c : 4,4'-methylenebis(N,N-dimethylaniline) 254
N
N
42
96
134 126 117
N H
N
NH2
N H
240
210 166
237 224
196 152165180
210 223
347
348
Tsuge, Ohtani and Watanabe
R06 [107] Bismaleimide triazine resin; BT resin O C(CH3 )2
N
O
CO N
N
CH2
CO
N
CO CO
N N
O
n
O
b
c d a
2
f h e g
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
a
unidentified
b
H3CO
c
HO
d
H 2N
CH2
e
H2 N
f
H2N
g
H3 C H N
CH 2
h
H3CH N
CH 2
Molecular Retention Weight Index
Relative Intensity
171
1394
8.4
256
2105
100.0
242
2150
1.1
NH 2
198
2166
1.3
CH 2
NHCH 3
212
2260
6.1
CH 2
N(CH 3) 2
226
2279
2.9
NHCH 3
226
2353
7.0
N(CH 3) 2
240
2371
4.1
C(CH3) 2
C(CH3)2
OCH3
OCH3
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R06 [107]
a : unidentified
b : 2,2-bis(4'-methoxyphenyl)propane 171
241 O
58
O
143 256 29
70 42
85
99
113
39 51 63 77 91
156
133 121
165
195 211
c : 2-(4'-hydroxyphenyl)-2-(4'-methoxyphenyl)propane d : diaminodiphenylmethane 198
227
HO
O NH 2
H2N 106
182
242 119 133
39 51 65 77 91
152 165 181 197 212
30 39 52
e : 4-(4-aminobenzyl)-N-methylaniline
65 77
93
130 143152 168
f : 4-(4-aminobenzyl)-N,N-dimethylaniline 226
212
H2 N
NH2
N H
106 120 77 91 30 39 51 65
182 196
N
106
152 168
77 91 30 42 51 65
182
134 118
152 165
210 194
h : N,N-dimethyl-4-(4-(methylamino)benzyl)aniline
g : 4,4'-methylenebis(N-methylaniline) 226
N H
N H
240
N H
N 120 196
77 91 30 39 51 65
112
152 165 180
120 134 211
91 30 42 51 65 77
112
196 152 165 180
210 223
349
350
Tsuge, Ohtani and Watanabe
R07 [108] Polyetherimide; PEI CO O
C(CH3)2
CO N
O
N
CO
CO
n
c
h
b a
f d
HA
ID 2
g
e
i
BA
10
20
Peak Notation
Assignment of Main Peaks
HA
p-hydroxybenzaldehyde COOCH 3
a
Molecular Retention Index Weight
Relative Intensity
122
1396
1.9
194
1464
4.8
136
1481
51.0
150
1500
100.0
164
1507
2.2
210
1759
10.6
256
2093
1.7
242
2147
30.8
228
2203
1.5
238
2492
1.7
-
2714 3228
8.6 4.0
COOCH 3
b
H3CHN
c
H3CHN
d
(H3 C)2N
NHCH 3
N(CH3)2
N(CH3)2 CH2
ID
O
CCH3
e
H3CO
f
HO
C(CH3)2
HO
C(CH3) 2
BA
C(CH3) 2
OCH3
OCH3
OH
H2N
g h i
N
CO CO
unidentified unidentified
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R07 [108]
HA : p-hydroxybenzaldehyde
a : dimethyl phthalate 122
OH
163
O O 29
O
93 O 29 O
65 39
80
53
39
51
66 76
104 94
194 120
135
c : N,N,N'-trimethyl-1,3-phenylenediamine
b : N1,N3-dimethylbenzene-1,3-diamine
150
136
N H
N H
N H
106
N 106
67 51
30 39
94
77
150
120
29
d : N,N,N',N'-tetramethyl-1,3-benzenediamine
121
74
42 51
135
91
ID : 4-isopropenyl diphenyl ether
164
N
210
O
N 120 77 73
42 30
53
135 195
149 91
104
77 91 39 51 65
115 119 141152 165
f : 2-(4'-hydroxyphenyl)-2-(4'-methoxyphenyl)propane
e : 2,2-bis(4'-methoxyphenyl)propane
227
241 O
O
HO
O
242
256 77 91 29 41 51 63
115
133 152 165 183
91 107119 134 29 39 51 65 77
211226
BA : bisphenol A
153165 183 197 212
g : 2-(3-aminophenyl)isoindoline-1,3-dione 213
HO
H2N
238
O
OH N O 39 55 65 77
91
119 107 135
228
76 39 50 65
169
h : unidentified
91 104 119 134
154 167 181
210
i : unidentified 365
289
380
304 77 91 39 51 65
194
119 144 165181 195
39 5165
77
165183 195 115 152
271
351
352
Tsuge, Ohtani and Watanabe
R08 [109] Polypyromellitimide; PI O
CO
CO
CO
CO
N
N n
i e a d b
h f g
2
j 14
8
10
Peak Notation a
Assignment of Main Peaks H3CO
25 [min]
20
NHCH3
Molecular Retention Relative Index Weight Intensity 137
1309
3.4
194
1512
0.1
252
1855
1.4
310
2164
4.7
COOCH 3
b
COOCH 3 H3 COCO
and its isomers COOCH 3
c COOCH 3 H3 COCO
COOCH3
H3 COCO
COOCH3
d
e
H2 N
O
NHCH 3
214
2238
29.8
f
H2N
O
N(CH3 ) 2
228
2249
7.3
H3 C H N
O
NHCH3
228
2330
40.4
h
H3CH N
O
N(CH 3) 2
242
2344
100.0
i
(H3C) 2N
O
256
2354
10.5
g
N(CH 3)2
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R08 [109]
a : p-methoxy-N-methylaniline
b : dimethyl phthalate 122
163
O
NH
O
O 137
30
40
52
90
66
77 74
29 39 50
77
c : 1,2,4-benzenetricarboxylic acid, trimethyl ester O
O O
194
d : 1,2,4,5-benzenetetracarboxylic acid, tetramethyl ester
221
O
279 O
O
92 104
O
O O
O
O
O O
29 39
59
103 119135
75
O O
162
29 43 59 75
252
193
O 233
162
105 124
310
251
f : 4-(4-aminophenoxy)-N,N-dimethylaniline
e: 4-(4-aminophenoxy)-N-methylaniline
228
214 H2N
O
NH
H 2N
O
N
136
122 53 29 39
65
80 93 108
171
108
185 31
39 53 65 79
120
156
199
213
h : N,N-dimethyl-4-(4-(methylamino)phenoxy)aniline
g : 4,4'-oxybis(N-methylaniline) 228 HN
O
242 HN
NH
O
N
122
30 39 52
65 77
94 106
134
170
185
122
199 213
i : 4,4'-oxybis(N,N-dimethylaniline) 256 N
O
N
136 4251 65 77 92104
127
168 184
226 241 213
65 77 30 4251
94104
136 154 170
199 213 227
353
354
Tsuge, Ohtani and Watanabe
R09 [110] Polyaminobismaleimide; PABM CH2
CO
CH
CO
N
CH2
CO
CH2
CO
CH
N
NH
CH2
NH n
DA
e
b d
a
MD
c 2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
DA
H 2N
CH2
NH 2
198
2164
100.0
a
H2 N
CH 2
NHCH 3
212
2255
17.0
b
H2N
CH 2
N(CH 3) 2
226
2274
4.6
c
H3 C H N
CH 2
NHCH 3
226
2348
6.7
d
H3CH N
CH 2
N(CH 3) 2
240
2366
4.5
MD
(H3C) 2N
CH2
N(CH 3) 2
254
2384
0.7
e
CO H2C N H2C CO
294
2974
85.0
CH2
NHCH3
Molecular Retention Weight Index
Relative Intensity
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R09 [110]
DA : diaminodiphenylmethane
a : 4-(4-aminobenzyl)-N-methylaniline 212
198
NH2
N H
NH 2
H 2N 106
182 65 77 30 39 52
98
130
106 120
182 196
77 91 30 39 51 65
152 168
b : 4-(4-aminobenzyl)-N,N-dimethylaniline
152 168
c : 4,4'-methylenebis(N-methylaniline) 226
H2 N
226
N H
N
N H 120
77 91 30 42 51 65
106
118
196
182
134
210
152 165
77 91 30 39 51 65
195
d : N,N-dimethyl-4-(4-(methylamino)benzyl)aniline
112
211
139 152 165 180
MD : 4,4'-methylenebis(N,N-dimethylaniline) 254
240
120 134 91 30 42 51 65 77
196 152 165 180
112
280
O
55 2939
N H
106
O
182 77 90
132
167
197
223 235
265
210
134 210 223
e : 1-(4-(4-(methylamino)benzyl)phenyl)pyrrolidine -2,5- dione
N
N
N
N H
N
294
118 29 42 51 65
91 104
165 152
237 194
223
355
356
Tsuge, Ohtani and Watanabe
R10 [115] Poly(ethylene terephthalate); PET COOCH2CH2OCO n
c
a
b
2
10
Peak Notation
Assignment of Main Peaks
a b
CH3OCH2CH2OH CH3OCH2CH2OCH3
c
H3COCO
25 [min]
20
Relative Intensity
Molecular Retention Index Weight
COOCH3
76 90
627 645
1.2 15.5
194
1516
100.0
[ Related Reference ] 1) Challinor, J. M. J. Anal. Appl. Pyrolysis 1989, 16, 323.
a : methoxyethanol
b : ethylene dimethyl ether 45
45
O
O O
HO 29 29
60
76
c : dimethyl terephthalate 163
O
O
O
O
29 39
50
76 75
103 104 120
194
135 179
90
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R11 [116] Poly(butylene terephthalate); PBT COOCH2CH2CH2CH2OCO
n
c
a b 2
10
Peak Notation
Assignment of Main Peaks
a b
CH3O(CH2)4OCH3 CH3O(CH2)4OH
c
H3COCO
25 [min]
20
Molecular Retention Index Weight
COOCH3
a : 1,4-dimethoxybutane
Relative Intensity
118 104
851 882
18.0 6.1
194
1516
100.0
b : butylene glycol methyl ether
45
45 58
O
O
O
HO 58
29
71
86
31
103 104
c : dimethyl terephthalate 163
O
O
O
O
29 39
50
76 75
194
135
103 120
149
179
71
89 90
357
358
Tsuge, Ohtani and Watanabe
R12 [117] Poly(ethylene naphthalate); PEN CH2CH 2OCO COO n
DN
ME DE
2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
ME DE
CH3OCH2CH2OH CH3OCH2CH2OCH3
DN
H3COCO
Molecular Retention Index Weight
COOCH3
ME : methoxyethanol
Relative Intensity
76 90
626 645
1.1 8.5
244
2118
100.0
DE : ethylene dimethyl ether 45
45
O
O O
HO 29 29 76
58
DN : dimethyl-2,6-naphthalene dicarboxylate 213 O
244
O O O
185
126 154
29 39
63 77 91
114
142
170
199
229
60
90
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R13 [118] Poly(p-hydroxybenzoic acid); type A O
O
CO
CO
O
CO n
c a
b
2
10
Peak Notation
Molecular Retention Index Weight
Assignment of Main Peaks
a
H3CO
b
H3COCO
c
H3CO
25 [min]
20
COOCH3
COOCH3
OCH3
Relative Intensity
166
1387
96.4
194
1512
50.7
214
1965
100.0
[ Related References ] 1) Ohtani, H. ; Fujii, R. ; Tsuge, S. J. High Resolut. Chromatogr. 1991, 14, 388. 2) Ishida, Y. ; Ohtani, H. ; Tsuge, S. J. Anal. Appl. Pyrolysis 1995, 33, 167.
a : methyl 4-methoxybenzoate
b : dimethyl terephthalate 135
163
O
O
O
O O 166 77 29 38
50
92
63
123
199 O
171 128 29 39 51 63 76
102
139 156 115
O
29 39
c : 4,4'-dimethoxy-1,1'-biphenyl O
O
107
214
50
76
103 104 120
194
135 149
179
359
360
Tsuge, Ohtani and Watanabe
R14 [119] Poly(p-hydroxybenzoic acid); type B O CO
O
CO n
b c
a 2
10
Peak Notation
Molecular Retention Index Weight
Assignment of Main Peaks
a
H3CO
b
H3CO
COOCH3
H3CO
c
25 [min]
20
108
920
0.6
166
1396
100.0
216
1974
78.1
COOCH3
[ Related References ] 1) Ohtani, H. ; Fujii, R. ; Tsuge, S. J. High Resolut. Chromatogr. 1991, 14, 388. 2) Oba, K. ; Ishida, Y. ; Ohtani, H. ; Tsuge, S. Polym. Degrad. Stab. 2002, 76, 85.
a : anisole
b : methyl 4-methoxybenzoate 135
108 O 65
O
78
O
O 166 39 51
77
93 29 38
29
c : methyl 6-methoxy-2-naphthoate 185
216
O O
O 157
114 142 29 39 50
63
88
127
173
201
50
63
Relative Intensity
92
107 123
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R15 [120] Polyarylate; PAR O
C(CH3)2
OCO
CO
n
d
b c
a 2
10
Peak Notation
Assignment of Main Peaks
a
H3CO
b
Molecular Retention Weight Index
C(CH3) 3
H3COCO
c
H3COCO
d
H3CO
25 [min]
20
COOCH3
COOCH3
C(CH3) 2
OCH3
a : p-methoxy-tert-butylbenzene
Relative Intensity
164
1251
1.0
194
1517
21.2
194
1530
23.0
256
2107
100.0
b : dimethyl terephthalate 163
149
O
O
O
O 121 41 51
65
77
91
109
O
164 134
39
c : dimethyl m-phthalate
50
103 104 120
76
194
135 179
d : 2,2-bis(4'-methoxyphenyl)propane 241
163 O O
O
O O 135
O 39
50
76
103
120
194 149
179
256 121133 152 165183 39 51 63 77 91 113
211226
361
362
Tsuge, Ohtani and Watanabe
R16 [121] Poly(1,4-cyclohexane dimethylene terephthalate) H2C
CH2 OOC
COO
n
DP
H1 H2 H3 H4
2
10
Peak Notation
Molecular Retention Weight Index
Assignment of Main Peaks
H1 H3COH2C
CH 2OCH3
H2 H3 H3COH2C
H4
CH 2OH
H3COCO
DP
172
1246
28.6
cis form
172
1253
12.2
trans form
158
1300
7.9
cis form
158
1311
3.4
194
1516
100.0
COOCH3
H2 : 1,4-bis(methoxymethyl)cyclohexane (cis)
95
45 108
45
Relative Intensity
trans form
H1 : 1,4-bis(methoxymethyl)cyclohexane (trans) O
25 [min]
20
O
95
O
108 O
67 67
29
79
79
140
55 127
55
29
140
125
H3 : (4-(methoxymethyl)cyclohexyl)methanol (trans)
H4 : (4-(methoxymethyl)cyclohexyl)methanol (cis)
95
95 O
O
45
OH
67
45
79
67 79
108
108
55
29
OH
55
126
31
126 140
DP : dimethyl terephthalate 163
O
O
O
O
29 39
50
76
194
135
103 120
149
179
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R17 [122] Poly(lactic acid); PLA CH 3 OCHCO
n
B
A
DB MB
DS DA
2
10
Peak Notation
20
Molecular Retention Relative Weight Index Intensity
Assignment of Main Peaks CH3
A
OHCHCOOCH3 CH3
B
CH3OCHCOOCH3 CH3O(CH2)4OCH3 CH3O(CH2)4OH CH3OCO(CH2)2COOCH3 CH3OCO(CH2)4COOCH3
DB MB DS DA
104
749
38.1
118
799
100.0
118 104 146 174
856 886 1033 1242
4.8 3.8 8.1 1.7
[ Related Reference ] 1) Urakami, K.; Higashi, A.; Umemoto, K.; Godo, M.; Watanabe, C.; Hashimoto, K. Chem. Pharm. Bull. 2001, 49, 203.
A : methyl 2-hydroxypropanoate
B : methyl 2-methoxypropanoate
45
59 O
OH
O
O O
O 29
29
43
61
DB : 1,4-dimethoxybutane
88
75
89
103
MB : butylene glycol methyl ether 45
45 58
O
O
O
HO 58
29
71
86
31
103 104
71
76
89
DA : dimethyl hexanedioate
DS : dimethyl succinate 115
O
O
59
O
114
O
O O
O
O 55
74 41 29
87 29
45
101
72
101
83
143
363
364
Tsuge, Ohtani and Watanabe
R18 [123] Poly(ε -caprolactone); PCL (CH2)5COO
n
A
C 2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
A B
CH3O(CH2)5COOCH3 CH3O [ (CH2)5COO ] CH3
Molecular Retention Weight Index 160 274
2
1150 1926
Relative Intensity 100.0 0.2
[ Related Reference ] 1) Sato, H. ; Kiyono, Y. ; Ohtani, H. ; Tsuge, S. ; Aoi, H. ; Aoi, K. J. Anal. Appl. Pyrolysis 2003, 68, 37.
B : 6-methoxy-6-oxohexyl 6-methoxyhexanoate
A : methyl 6-methoxyhexanoate 45
129
69
O
O
O
45 O
87 55 29
74
O
O
55
O
O
97
87 98
113 128
29
145 160
115
143
188
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R19 [124] Poly(butylene succinate / adipate); PBSA O(CH2 )4OCO(CH2 )2 CO
O(CH2 )4OCO(CH2 )4CO
n
DS
DB
MB DA
2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
DB MB DS DA
CH3O(CH2)4OCH3 CH3O(CH2)4OH CH3OCO (CH2)2COOCH3 CH3OCO (CH2)4COOCH3
Molecular Retention Relative Weight Index Intensity 118 104 146 174
856 886 1033 1241
45.0 46.2 100.0 26.8
MB : butylene glycol methyl ether
DB : 1,4-dimethoxybutane 45
45 58
O
O
O HO
58
29
71
86
29
103
DS : dimethyl succinate
71
89
DA : dimethyl hexanedioate 115
O
O
59
O
114
O
O O
O O
55 41 87
29
45
101
143
74
72
83
29 101
123
365
366
Tsuge, Ohtani and Watanabe
R20 [125] Poly(3-hydroxybutylic acid); PHB H
OCHCH2C CH3
O
OH n
B3
A M
B2 B1
2
10
Peak Notation
Assignment of Main Peaks
A B1 B2 B3
methyl acetate CH2=CHCH2COOCH3 CH3CH=CHCOOCH3 (cis form) CH3CH=CHCOOCH3 (trans form)
Molecular Retention Relative Weight Index Intensity
CH3
M
25 [min]
20
CH3OCHCH2COOCH3
74 100 100 100
487 718 735 765
6.1 10.7 25.3 100.0
132
886
19.6
[ Related Reference ] 1) Sato, H. ; Hoshino, M. ; Aoi, H. ; Seino, T. ; Ishida, Y. ; Aoi, K. ; Ohtani, H. J. Anal. Appl. Pyrolysis 2005, 74, 193.
A : methyl acetate
B1 : methyl 3-butenoate 41
43
O
O O 59
O 74
59
29
100
69 29
B2 : methyl 2-butenoate (cis)
B3 : methyl 2-butenoate (trans)
69
69
O
O
O 39
O
100 41 85 100
29
59
29
85
M : methyl 3-methoxybutanoae 59
O
O
O
75 29
43
85
102
117
59
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R21 [126] Poly(butylene succinate / carbonate); PEC O(CH2)4OCO(CH2)2CO
O(CH2)4
OCO
n
S
B1 B2
2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
B1 B2 S
CH3O(CH2)4OCH3 CH3O(CH2)4OH CH3OCO(CH2)2COOCH3
Molecular Retention Relative Weight Intensity Index 118 104 146
B1 : 1,4-dimethoxybutane
855 886 1034
37.7 47.0 100.0
B2 : butylene glycol methyl ether
45
45 58
O
O HO
O 58
29
71
86
29
103
71
S : dimethyl succinate 115
O O O O
55 87
29
45
72
101
89
367
368
Tsuge, Ohtani and Watanabe
R22 [127] Polycarbonate (melt method); MM-PC H
O
C(CH3)2
OCO n
b
a 2
10
Peak Notation
Molecular Retention Weight Index
Assignment of Main Peaks
a
H3CO
b
H3CO
C(CH3) 2
25 [min]
20
OCH3
108
922
0.2
256
2103
100.0
[ Related References ] 1) Ito, Y. ; Ogasawara, H. ; Ishida, Y. ; Ohtani, H. ; Tsuge, S. Polym. J. 1996, 28, 1090. 2) Oba, K. ; Ishida, Y. ; Ito, Y. ; Ohtani, H. ; Tsuge, S. Macromolecules 2000, 33, 8173. 3) Hayashida, K. ; Ohtani, H. ; Tsuge, S. ; Nakanishi, K. Polym. Bull. 2002, 48, 483.
a : anisole
b : 2,2-bis(4'-methoxyphenyl)propane 108
241
O 65
29
O
O
78
39 50
256
93 39 51 63 77 91
Relative Intensity
133 121
165183
211226
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R23 [128] Polycarbonate (solvent method); SM-PC (CH3)3C
OCO
O
C(CH3)2
OCO
O
C(CH3)3
n
b
a 2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
a
H3CO
C(CH3)3
b
H3CO
C(CH3)2
Molecular Retention Index Weight
OCH3
164
1252
1.5
256
2103
100.0
[ Related References ] 1) Ito, Y. ; Ogasawara, H. ; Ishida, Y. ; Ohtani, H. ; Tsuge, S. Polym. J. 1996, 28, 1090. 2) Oba, K. ; Ishida, Y. ; Ito, Y. ; Ohtani, H. ; Tsuge, S. Macromolecules 2000, 33, 8173. 3) Oba, K. : Ohtani, H. ; Tsuge, S. Polym. Degrad. Stab. 2001, 74, 171. 4) Hayashida, K. ; Ohtani, H. ; Tsuge, S. ; Nakanishi, K. Polym. Bull. 2002, 48, 483.
a : p-methoxy-tert-butylbenzene
b : 2,2-bis(4'-methoxyphenyl)propane 149
241
O
O
121 29 41 51
65 77
91
O
164
256
109 133
51
77 91
Relative Intensity
133 121
165 183
211 226
369
370
Tsuge, Ohtani and Watanabe
R24 [129]
Bisphenol Z polycarbonate O
OCO n MM
2
10
Peak Notation
Assignment of Main Peaks
MM
H3 CO
Molecular Retention Weight Index 296
OCH3
MM : 1-(2-methoxyphenyl)-1-(4-methoxyphenyl)cyclohexane 253 O
296
O
121 29 41 55 65 77 91
115
145
227
153165 178 199 210
25 [min]
20
265
2536
Relative Intensity 100.0
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R25 [130] Polycarbonate (thermally stabilized) O
(CH3)3CCH2 C(CH3 )2
COO
C(CH3 )2
O
COO
O
COO
C(CH3 )2 CH2C(CH3 )3
n
CH3
H3 C CH3
B C
A 2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
A
H3CO
B
H3CO
C
H3CO
Molecular Retention Weight Index
C(CH3)2CH2C(CH3)3
C(CH3)2
OCH3 OCH 3
220
1564
2.1
256
2101
100.0
338
3584
75.1
CH3
H3C
CH 3
[ Related Reference ] 1) Ishida, Y.; Kawaguchi, S.; Ito, Y.; Tsuge, S.; Ohtani, H. J. Anal. Appl. Pyrolysis 1997, 40-41, 321.
A : 1-methoxy-4-(2,4,4-trimethylpentan-2-yl)benzene B : 2,2-bis(4'-methoxyphenyl)propane 241
149
O
O
O
29 41
57 65 77 91 109
121 133
133 121 152165 183 195 211226 29 39 51 63 77 91 115
220
163
C : 4,4'-(3,3,5-trimethylcyclohexane-1,1-diyl) bis(methoxybenzene) 267
O
O
338
29 41
55
121 159 7791 115 135 165
209 225 199
281 307 323
Relative Intensity
256
371
372
Tsuge, Ohtani and Watanabe
R26 [132] Polysulfone; PSF O
C(CH3)2
O
SO2 n
a
b
MM
A 2
c
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
A
H3CO
MM
H3 CSO2
a
H3 CO
C(CH3) 2
b
H3 CO
SO2
c
unidentified
Molecular Retention Weight Index
OCH3 OCH3 OCH3
Relative Intensity
108
922
1.3
186
1699
2.4
256
2103
92.8
278
2607
100.0
380
3232
1.2
[ Related Reference ] 1) Ohtani, H. ; Ishida, Y. ; Ushiba, M. ; Tsuge, S. J. Anal. Appl. Pyrolysis 2001, 61, 35.
A : anisole
MM : methyl 4-methoxyphenyl sulfone 108
171 O
O 65
O
78
S
186
77 107
O 92 63
39 51
93 31 38
32
a : 2,2-bis(4'-methoxyphenyl)propane
O
O
O
133 121
77 91
64 29 41 50
211 226
c : unidentified 365
380 77 3951
102
141
165179195
257
139
155
O S O
256 165 183
50
155
b : 4,4'-sulfonylbis(methoxybenzene)
241
39 51
123
O
278
123
77 92 107 139
199 171 214 183
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R27 [135] Polyethersulfone; PESF SO2
O n
b
a 2
10
Peak Notation
Assignment of Main Peaks
a
H3CO
b
H3 CO
SO2
25 [min]
20
Molecular Retention Weight Index
OCH3
Relative Intensity
108
108
1.5
278
278
100.0
[ Related Reference ] 1) Ohtani, H. ; Ishida, Y. ; Ushiba, M. ; Tsuge, S. J. Anal. Appl. Pyrolysis 2001, 61, 35.
a : anisole
b : 4,4'-sulfonylbis(methoxybenzene) 108 O
O
65
78
39 51 31
155
O S O
64
93 29 41 50
O
278 123
77 92 107
171
199
214
246
373
374
Tsuge, Ohtani and Watanabe
R28 [136] Poly(ether ether ketone); PEEK O
O
CO n
b
a
c
2
10
Peak Notation
Assignment of Main Peaks
a
H3CO
b
H3CO
CO
OCH3
c
H3CO
CO
O
Molecular Retention Index Weight
OCH3
OCH3
a : p-methoxyanisole
Relative Intensity
138
1170
27.2
242
2285
100.0
334
3140
33.7
b : 4,4'-dimethoxybenzophenone 123
O
25 [min]
20
135 O
O 138 O
95 41 29
52
63
80
108
29
c : (4-(4-methoxyphenoxy)phenyl)(4-methoxyphenyl) methanone 334 O
O
O
O
135
227
77 92 39 50
64
107 128
O
242
77 92
156171184
211 255
303319
50
64
211 107
128
156 171
199
227
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R29 [151] Cellulose acetate; CA CH 2OCOCH3 H
O H OCOCH3 H H
MA
O
H n
OCOCH3
DF
MA’
2
10
25 [min]
20
Peak Notation
Assignment of Main Peaks
DF MA MA’
dimethyl formal methyl acetate methoxyacetaldehyde
Molecular Retention Weight Index 76 74 74
471 487 584
[ Related Reference ] 1) Schwarzinger, C.; Tanczos, I.; Schmidt, H. J. Anal. Appl. Pyrolysis 2002, 62, 179.
DF : dimethyl formal O
O
MA : methyl acetate 45
43
O 75
O 29 74 29 76
MA' : methoxyacetaldehyde 45
O O
29
56
74
59
Relative Intensity 100.0 1.7 5.7
375
376
Tsuge, Ohtani and Watanabe
R30 [152] Cellulose acetate-propionate; CAP CH2 OR H
MPr
O
O
H OR
H
H
OR
R=COCH3 or COC2H5
H n
DP
MA DC
B a b
2
MP BP P MS
10
Peak Notation
Assignment of Main Peaks
MA DC MPr B DP a b MP BP MS P
methoxyacetaldehyde dimethyl carbonate methyl propionate n-butanol dimethyl phthalate unidentified unidentified palmitic acid, methyl ester dibutyl phthalate stearic acid, methyl ester palmitic acid, butyl ester
25 [min]
20
Molecular Retention Index Weight
(plasticizer)
(plasticizer) (plasticizer) (plasticizer) (plasticizer)
74 90 88 74 194 270 278 298 312
584 613 623 654 1464 1560 1728 1923 1971 2125 2143
Relative Intensity 8.4 1.6 100.0 6.3 61.5 4.4 0.7 9.4 7.3 2.5 1.5
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R30 [152]
MA : methoxyacetaldehyde
DC : dimethyl carbonate
45
45
O
O
O
O
29
59
31
O
62
74
56
MPr : methyl propionate
90
B : 1-butanol 56
57
O
OH
41
O
31
29 88
45
74
DP : dimethyl phthalate
a : unidentified 163
149
O O O O
77 92
50
29
104
120 133
194
149
b : unidentified
29 41
57
77 91
109
121 133
220
163
MP : palmitic acid, methyl ester 74
163
O 87
O
149 43 55 76
29 41 50
92 104
181
135
29
97
143 129
171185199
227 239
270
MS : stearic acid, methyl ester
BP : dibutyl phthalate 149
74 O O
87
O O 43
O
55 143
O 29 41
76
104 121
29
205 223
P : palmitic acid, butyl ester 57
O O 257 41 29
239 71
83 97 116
157
185
213
312
97
129
199 185
255 267
298
377
378
Tsuge, Ohtani and Watanabe
R31 [153] Cellulose acetate-butyrate; CAB CH2OR H
MB
O
O
H OR
H
H
OR
R=COCH3 or COC3H7
H n
MA DF
e a
b
c
d
2
10
Assignment of Main Peaks DF MA MB a b c d e
dimethyl formal methyl acetate methyl butanoate unidentified unidentified unidentified unidentified unidentified
25 [min]
20
Molecular Retention Index Weight 76 74 102 100 128 158 154 205
471 487 724 800 1040 1225 1256 2277
Relative Intensity 10.6 52.2 100.0 31.3 4.3 7.4 4.0 12.8
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R31 [153]
DF : dimethyl formal
MA : methyl acetate 45
O
43
O
O 75
O
29
74 29
59
57
MB : methyl butanoate
a : unidentified
43
100
74
O 29
O
41
56 70
87
59 29
85
102
b : unidentified
c : unidentified 127
97
158
128 39
53
111 67
82 113
32
d : unidentified
45 53
29
69 81
53
111
83
45 111
68
81
125
173
139
95 29
143
e : unidentified 154
39
97
29
59
71
101 125 141 157
205
379
380
Tsuge, Ohtani and Watanabe
R32 [157] Shellac CH
2
O H
(C H
2
)5
CHOH CH (C H
2
f
)7 n
O
O
O O
R
R
e a
2
b c
d
g
h i
j
k
10
25 [min]
20
Molecular Retention Index Weight
Peak Notation
Assignment of Main Peaks
a
CH3O(CH2)12COOCH3 OCH3
242
1725
0.5
b
CH3(CH2)7CH(CH2)4COOCH3
272
1861
7.1
c
hexadecenoic acid, methyl ester
268
1917
0.5
322
2131
9.2
336
2221
21.1
360
2384
100.0
346
2447
12.6
410 438 466
2522 3029 3231 3429
0.5 3.1 1.7 1.0
d
H 3CO H 3COC
H 3CO H 3COC
Relative Intensity
COOCH3
CH 2OH COOCH3
e CH 2O CH3
OCH3 f
CH3O(CH2)6CHCH(CH2)7COOCH3 OCH3 OCH3
g
CH3O(CH2)6CHCH(CH2)7COOCH3 OH
h i j k
unidentified 1-octacosanol 1-triacontanol 1-pentacontanol [ Related Reference ]
1) Wang, L. ; Ishida, Y. ; Ohtani, H. ; Tsuge, S. ; Nakayama, T. Anal. Chem. 1999, 71, 1316.
381
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R32 [157]
a : methyl tetradecanoate
b : methyl 6-methoxytetradecanoate
74
127
O O
87
41 55
43 55 29
143
129
101
199 211 185
157
242
c : hexadecenoic acid, methyl ester 87
O O
O
83 95
29
109
241 257
191
d : C18H26O5 45
O
113
159
69
O
55
67
81
O
O
O
O
95 145
41 55 67 29
95
127
166
185
227
e : C19H28O5
HO 262 217234
275
307 322
f : methyl 9,10,16-trimethoxyhexadecanoate 291
O
45
109 135 121 185 153 167
29
O
O
75 129 115 155
91 59
O
272
181
O
197213 227
71
95
201
304
O
O
O O
O
159
45
259
137
336
257
55 29
109
81
169185
126
329
265
g : methyl 10-hydroxy-9,16-dimethoxyhexadecanoate h : unidentified 95
71
O
O
45
145155
55
O
187201
4555
119
169
251
187
125
251
320
j : 1-triacontanol 57 83 97
HO
43
111
125
139 153 181 210 236 264 292 323
29
HO 71 111
125 364
392
29
k : 1-dotriacontanol 57 8397 HO 43 69 111
29
95 67 87 109
29
315
i : 1-octacosanol 57 83 97 45 69
145
109
81
29
155
O
OH
125 139 181 195 222 249 281 153
344
405
448
139 153 181 196 223 250
315
392
420
382
Tsuge, Ohtani and Watanabe
R33 [161] Synthetic lignin; DHP
b
d a MV
DS
E
2
c
MI
10
Peak Notation DS
Assignment of Main Peaks H3CO
25 [min]
20
CH=CH 2
Molecular Retention Weight Index
Relative Intensity
164
1371
0.2
182
1454
6.0
166
1487
6.0
178
1502
0.2
208
1749
34.5
270
1805
72.4
370
3222
37.5
386
3297
100.0
H3CO H 3CO
CH 2OCH3
E H 3CO H 3CO
CHO
MV H 3CO H3CO
CH=CHCH3
MI H3CO
a
H 3CO
CH=CHCH2OCH3
H 3CO
b
H 3CO
CH(OCH 3)CH(OCH3)CH 2OCH3
H 3CO H3CO
CH
CH
CH=CHCH 2OCH3
c H3CO
H 3CO OCH 2
d
H 3CO
OCH 3
CHCHCHCH
OCH 3
OCH 2 H 3CO
OCH 3
[ Related References ] 1) Mckinney, D. E.; Carson, D. M.; Clifford, D. J.; Minard, R. D.; Hatcher, P. G. J. Anal. Appl. Pyrolysis 1995, 34, 41. 2) del Rio, J. C.; Martin, F.; Gonzalez-Vila, F. J. Trends Anal. Chem. 1996, 15, 70. 3) Vane, C. H.; Abbott, G. D.; Head, I. M. J. Anal. Appl. Pyrolysis 2001, 60, 69. 4) Kuroda, K.; Nakagawa-Izumi, A. J. Agric. Food Chem. 2005, 53, 8859. 5) Kuroda, K.; Nakagawa-Izumi, A. Org. Geochem. 2005, 36, 53. 6) Klingberg, A.; Odermatt, J.; Meier, D. J. Anal. Appl. Pyrolysis 2005, 74, 104. 7) Kuroda, K.; Nakagawa-izumi, A. J. Anal. Appl. Pyrolysis 2006, 75, 104.
Pyrograms for 33 Condensation Polymers and MS Data of the Major Pyrolyzates Obtained in the Presence of Organic Alkaline
R33 [161]
DS : 3,4-dimethoxystyrene
E : 1,2-dimethoxy-4-(methoxymethyl)benzene 164
O
151 O
O 77
29
43
O 149
182
O
91 121
51 63
29 39
MV : 3,4-dimethoxybenzaldehyde
65 77
51
107
91
124 139
166
MI : 1,2-dimethoxy-4-(prop-1-enyl)benzene 178
166 O
O O O
O 107
95 51 29 41
65
163
91
77 107 119
41
151
137
31
63
51
79 131
a : 1,2-dimethoxy-4-(3-methoxy-1-propenyl)benzene b : 1,2-dimethoxy-4-(1,2,3-trimethoxypropyl)benzene 181
177 O
O
208
O
O O O
51 65
29
77
91 115
131
O
O
146 161
193
45
c : 1-(3,4-dimethoxystyryl)-2,3-dimethoxy-5-
77 91
137
270
d : 1,4-bis(3,4-dimethoxyphenyl)hexahydrofuro 165
370
O O
O 151 177
O
O
166
[3,4-c]furan
(3-methoxyprop-1-enyl)benzene O
151
O
O O
O 386 O
45
71
89 115
151 165 181
339 355
55
77 95
138 115
189 219 235
355
383
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APPENDIX
Monographs and Reviews for Pyrolysis-GC of Polymers
Monographs M-1 Stevens MP. Characterization and analysis of polymers by gas chromatography. New York: Marcel Dekker; 1969. M-2 May RW, Pearson EF, Scothern D. Pyrolysis-gas chromatography (Anal. Sci. Monograph, No. 3) The Chemical Society. London: Burlington Howe; 1977. M-3 Berezkin VG, Alishoyev VR, Nemiraskaya IB. Gas chromatography of polymers ( J. Chromatogr. Library vol. 10). Amsterdam: Elsevier; 1977. M-4 Jones CE, Cramers CA, editors. Analytical pyrolysis (Proceedings of 3rd international symposium on analytical and applied pyrolysis, Amsterdam 1976). Amsterdam: Elsevier; 1976. M-5 Voorhees KJ, editor. Analytical pyrolysis. London: Butterworths; 1984. M-6 Liebman SA, Levy EJ, editors. Pyrolysis and GC in polymer analysis (Chromatographic Science Series, vol. 29). New York: Marcel Dekker, Inc.; 1985. M-7 Ohtani H, Tsuge S. Polymer characterization by high-resolution pyrolysis-gas chromatography. In: Mitchell Jr, II-H J, editor. Applied polymer analysis and characterization. Munich: Hanser Publisher; 1987. M-8 Hammond T, Lehrle RS. Pyrolysis GLC. In: Booth C, Price C, editors. Comprehensive Polymer Science, vol. 1. Oxford: Pergamon Press; 1989. Chapter 27. M-9 Irwin WJ. Pyrolysis technique. In: Winefordner JD, editor. Treatise on analytical chemistry, part I thermal methods. 2nd ed. vol. 13. New York: John Wiley & Sons; 1993. M-10 Smith CG, et al., editors. Pyrolysis gas chromatography (CRC handbook of chromatography polymers vol. 2, I.4, III.3, and IV.3). Boca Raton: CRC Press; 1994. M-11 Wampler TP, editor. Applied pyrolysis handbook. New York: Marcel Dekker; 1995. M-12 Irwin WJ. Gas chromatography: pyrolysis gas chromatography (Encyclopedia of analytical science). Academic Press; 1995. M-13 Moldoveanu SC. Analytical pyrolysis of natural organic polymers. Amsterdam: Elsevier; 1998. M-14 Ohtani H, Tsuge S. Pyrolysis gas chromatography/mass spectrometry (Py-GC/MS). In: Montaudo G, Lattimer RP, editors. Mass spectrometry of polymer. CRC Press; 2002. Chapter 3. M-15 Moldoveanu SC. Analytical pyrolysis of synthetic organic polymers. Amsterdam: Elsevier; 2005. M-16 Kusch P, Knuppf G, Morrisson A. Analysis of synthetic polymers and copolymers by pyrolysis-gas chromatography/mass spectrometry. In: Bregg RK, editor. Horizons in polymer research. New York: Nova Science; 2005. Chapter 5. M-17 Wampler TP, editor. Applied pyrolysis handbook. 2nd ed. Boca Raton: CRC Press; 2007.
Reviews R-1 Irwin WJ, Slack JA. Analytical pyrolysis in biomedical studies. Analyst 1978;103:673–704. R-2 Irwin WJ. Analytical pyrolysis - an overview. J Anal Appl Pyrol 1979;1:3–25. R-3 Wolf CJ, Grayson MA, Fanter DL. Pyrolysis gas chromatography of polymers. Anal Chem 1980;52:348A–58A. R-4 Wheals BB. Analytical pyrolysis techniques in forensic science. J Anal Appl Pyrol 1981;2:277–92. R-5 Hu JC-A. Chromatography for polymer characterization. Anal Chem 1981;53:311A–8A.
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Monographs and Reviews for Pyrolysis-GC of Polymers
R-6 Tsuge S. Structural characterization of polymers by pyrolysis-gas chromatography. Tr Anal Chem 1981;1:87–90. R-7 Liebman SA, Levy EJ. Advances in pyrolysis GC systems: applications to modern trace organic analysis. J Chromatogr Sci 1983;21:1–10. R-8 Liebman SA, Wampler TP, Levy EJ. Developments in pyrolysis capillary GC. J High Res Chromatogr, Chromatogr Commun 1984;7:172–84. R-9 Jones ST. Application of pyrolysis gas chromatography in an industrial research laboratory. Analyst 1984;109:823–8. R-10 Hu JC-A. Chromatopyrography. Adv Chromatogr 1984;23:149–97. R-11 Hummel DO, Du¨ssel H-J, Czybulka G, Wenzel N, Holl G. Analytical pyrolysis of copolymers. Spectrochim Acta 1985;41:279–90. R-12 Levy EJ, Wampler TP. Identification and differentiation of synthetic polymers by pyrolysis capillary gas chromatography. J Chem Educ 1986;63:A64–8. R-13 Tsuge S. Characterization of polymers by high-resolution pyrolysis-gas chromatography with fusedsilica capillary columns. Chromatography Forum 1986;1:44–51. R-14 Tsuge S, Ohtani H, Matsubara H, Ohsawa M. Some empirical consideration on the pyrolysis-gas chromatographic conditions required to obtain characteristic and reliable high-resolution pyrograms for polymer samples. J Anal Appl Pyrol 1987;11:181–94. R-15 Hammond T, Lehrle RS. Pyrolysis-GLC Applied to composition analysis, general characterization and the detailed specification of polymers. Br Polym J 1989;21:23–30. R-16 Tsuge S, Ohtani H. Structural characterization of polymeric materials by pyrolysis-GC/MS. Polym Degrad Stab 1997;58:109–30. R-17 Haken JK. Pyrolysis gas chromatography of synthetic polymers - a bibliography. J Chromatogr A 1998;825:171–87. R-18 Wampler TP. Introduction to pyrolysis-capillary gas chromatography. J Chromatogr A 1999;842:207–20. R-19 Wang FC-Y. Polymer analysis by pyrolysis gas chromatography. J Chromatogr A 1999;843:413–23. R-20 Moldoveanu SC. Pyrolysis GC/MS, present and future (recent past and present needs). J Microcolumn Sep 2001;13:102–25. R-21 Challinor JM. Review: the development and applications of thermally assisted hydrolysis and methylation reaction. J Anal Appl Pyrol 2001;61:3–34. R-22 Watanabe C, Hosaka A, Kawahara Y, Tobias P, Ohtani H, Tsuge S. GC-MS analysis of heart-cut fractions during evolved gas analysis of polymeric materials. LC GC N Am 2002;20:374–8. R-23 R-23 Watanabe C, Sato K, Hosaka A, Ohtani H, Tsuge S. Development of a multifunctional pyrolyzer for evolved gas analysis, thermal desorption, and/or pyrolysis-GC of polymeric materials. Am Lab News 2002;10:14–5. R-24 Tsuge S, Ohtani H, Watanabe C, Kawahara Y. Application of a multifunctional pyrolyzer for evolved gas analysis and pyrolysis-GC of various synthetic and natural materials. Am Lab 2003;35(1):32–7. R-25 Tsuge S, Ohtani H, Watanabe C, Kawahara Y. Application of a multifunctional pyrolyzer for evolved gas analysis and pyrolysis-GC of various synthetic and natural materials; part 2. Am Lab 2003;35(3):48–52. R-26 Tsuge S, Ohtani H, Watanabe C. Application of a multifunctional pyrolyzer for evolved gas analysis and pyrolysis-GC of various synthetic and natural materials: part 3. Am Lab 2003;35(12):16–8. R-27 Tsuge S, Ohtani H, Watanabe C. Application of a multifunctional pyrolyzer for evolved gas analysis and pyrolysis-GC of various synthetic and natural materials: part 4. Am Lab 2004;36(2):22–6. R-28 Sobeih KL, Baron M, Gonzalez-Rodriquez J. Recent trends and developments in pyrolysis-gas chromatography. J Chromatogr A 2008;1186:51–66. R-29 Rial-Otero R, Galesio M, Capelo J-L, Simal-Gandara J. A review of synthetic polymer characterization by pyrolysis-GC-MS. Chromatographia 2009;70:339–48. R-30 Shadkami F, Helleur R. Recent applications in analytical thermochemolysis. J Anal Appl Pyrol 2010;89:2–16.
INDEX A AAS [Acrylonitrile-acrylate-styrene copolymer], 60 ABS [Acrylonitrile-butadiene-styrene copolymer], 58 ACM [Acrylic rubber], 100 Acrylic rubber, 100 Acrylonitrile-acrylate-styrene copolymer, 60 Acrylonitrile-styrene copolymer, 54 Acrylonitrile-butadiene rubber, 160 Acrylonitrile-butadiene-styrene copolymer, 58 Acrylonitrile-p-chlorostyrene copolymer, 78 Acrylonitrile-EPDM-styrene copolymer, 62 Acrylonitrile-methyl acrylate copolymer, 104 Acrylonitrile-styrene alternating copolymer, 56 Acrylonitrile-vinyl chloride alternating copolymer, 124 Acrylonitrile-vinyl chloride copolymer, 122 AES [Acrylonitrile-EPDM-styrene copolymer], 62 AS [Acrylonitrile-styrene copolymer], 54
B Bismaleimide triazine resin, 222, 348 Bisphenol Z polycarbonate, 266, 370 BR [High cis-butadiene rubber], 150 Brominated polycarbonate, 270 Brominated epoxy resin, 220 Br-PC [Brominated polycarbonate], 270 BT resin [Bismaleimide triazine resin], 222, 348
C CA [Cellulose acetate], 310, 375 CAB [Cellulose acetate-butyrate], 314, 378 CAP [Cellulose acetate-propionate], 312, 376 Caproamide-hexamethylene adipamide copolymer, 186 Carboxymethyl cellulose, 318 Cellulose, 304 Cellulose acetate, 310, 375 Cellulose acetate-butyrate, 314, 378 Cellulose acetate-propionate, 312, 376 CHC [Epichlorohydrin-ethylene oxide rubber], 198
Chitin, 324 Chitosan, 326 Chlorinated poly(vinyl chloride), 114 Chlorinated polyethylene, 116 Chloromethylated styrene-divinylbenzene copolymer, 80 Chloroprene rubber, 156 Chlorosulfonated polyethylene, 120 CHR [Epichlorohydrin rubber], 196 CM [Chlorinated polyethylene], 116 CMC [Carboxylmethyl cellulose], 318 CPVC [Chlorinated poly(vinyl chloride)], 114 CR [Chloroprene rubber], 156 CR-39 [Poly(ethylene glycol bisallyl carbonate)], 208, 343 Cresol formaldehyde resin (novolak), 204 CSM [Chlorosulfonated polyethylene], 120
D DAP [Diallyl phthalate resin], 206, 342 DHP [Synthetic lignin], 330, 382 Diallyl phthalate resin, 206, 342 Dimethylsiloxane-methylphenylsiloxane copolymer, 290
E EP [Epoxy resin], 218, 346 EPDM [Ethylene-propylene-diene rubber], 28 Epichlorohydrin rubber, 196 Epichlorohydrin-ethylene oxide rubber, 198 Epoxy resin, 218, 346 Ethylcellulose, 308 Ethylene-acrylic acid copolymer, 32 Ethylene-ethyl acrylate copolymer, 36 Ethylene-methyl methacrylate copolymer, 30 Ethylene-propylene copolymer, 26 Ethylene-propylene-diene rubber, 28 Ethylene-vinyl acetate copolymer, 34 Ethylene-vinyl alcohol copolymer, 38 EVA [Ethylene-vinyl acetate copolymer], 34
F FEP [Tetrafluoroethylene-hexafluoropropylene copolymer], 131
387
j
388
Index
G Glue, 320 Gluten, 334
H HEC [Hydroxyethylcellulose], 316 High cis-butadiene rubber, 150 Higher methacrylate copolymer, 98 Hydrogenated acrylonitrile-butadiene rubber, 162 Hydrogenated natural rubber, 158 Hydroxyethylcellulose, 316
Nylon-12 [Polylauroamide], 176 Nylon-12,6 [Poly(dodecamethylene adipamide)], 184 Nylon-4,6 [Poly(tetramethylene adipamide)], 178 Nylon-6 [Polycaproamide], 172 Nylon-6,10 [Poly(hexamethylene sebacamide)], 182 Nylon-6,6 [Poly(hexamethylene adipamide)], 180 Nylon-6/66 [Caproamide-hexamethylene adipamide copolymer], 186 Nylon-MXD6 [Poly(m-xylene adipamide)], 188
P I IIR [Isobutylene-isoprene rubber], 24 IO [Polyethylene ionomer], 40 Isobutylene-isoprene rubber, 24 Ivory, 328
K Kevlar, 232
M MBS [Methyl methacrylate-butadiene-styrene copolymer], 52 MC [Methylcellulose], 306 MDI-polylactone polyurethane, 300 Melamine formaldehyde resin, 212 Methyl acrylate-vinyl chloride alternating copolymer, 128 Methyl acrylate-vinyl chloride copolymer, 126 Methylcellulose, 306 Methyl methacrylate-butadiene-styrene copolymer, 52 Methyl methacrylate-methyl acrylate copolymer, 96 MF [Melamine formaldehyde resin], 212 MM-PC [Polycarbonate (melt method)], 262, 368 Modified poly(phenylene oxide), 276 Modified PPO [Modified poly(phenylene oxide)], 276
N Natural rubber, 154 NBR [Acrylonitrile-butadiene rubber], 160 Nomex [Poly(m-phenylene isophthalamide)], 234 NR [Natural rubber ], 154 Nylon-11 [Polyundecanoamide], 174
PAA [Poly(acrylic acid; isotactic)], 94, 340 PAAm [Polyacrylamide], 106 PABM [Polyaminobismaleimide], 228, 354 PAI [Polyamideimide], 230 PAN [Polyacrylonitrile], 102 P(AN-VC) [Acrylonitrile-vinyl chloride copolymer], 122 PAR [Polyarylate], 248, 361 PBA [Poly(butyl acrylate)], 92 PBMA [Poly(n-butyl methacrylate)], 84 PBT [Poly(butylene terephthalate)], 240, 357 PBSA [Poly(butylene succinate/adipate)], 256, 365 PCL [Poly(3-caprolactone)], 254, 364 PCTFE [Polychlorotrifluoroethylene], 132 PDMS [Polydimethylsiloxane], 286 PDVB [Polydivinylbenzene], 70 PE (HDPE) [Polyethylene (high density)], 12 PEA [Poly(ethyl acrylate)], 90 P(E-AA) [Ethylene-acrylic acid copolymer], 32 PEC [Poly(butylene succinate/carbonate)], 260, 367 P(E-EA) [Ethylene-ethyl acrylate copolymer], 36 PEEK [Poly(ether ether ketone)], 280, 374 PEI [Polyetherimide], 224, 350 P(E-MMA) [Ethylene-methyl methacrylate copolymer], 30 PEN [Poly(arylether nitrile)], 284 PEN [Poly(ethylene naphthalate)], 242, 358 P(E-P) [Ethylene-propylene copolymer], 26 PESF [Polyethersulfone], 278, 373 PET [Poly(ethylene terephthalate)], 238, 356 P(E-VA) [Ethylene-vinyl alcohol copolymer], 38 PF [Phenol formaldehyde resin (novolak)], 200 PHB [Poly(3-hydroxybutylic acid)], 258, 366 PHEMA [Poly(2-hydroxyethyl methacrylate)], 86
389
Index
Phenol formaldehyde resin (novolak), 200 Phenol formaldehyde resin (resol), 202 PI [Polypyromellitimide], 226, 352 PLA [Poly(lactic acid)], 252, 363 PMA [Poly(methyl acrylate)], 88 PMAH [Poly(maleic anhydride)], 108 P(MA-VC) [Methyl acrylate-vinyl chloride copolymer], 126 PMMA [Poly(methyl methacrylate)], 82 P(MMA-MA) [Methyl methacrylate-methyl acrylate copolymer], 96 PMP [Poly(4-methyl-1-pentene)], 22 PMPS [Polymethylphenylsiloxane], 288 PMPSQ [Poly(methyl-phenyl)silsesquioxane], 294 PMS [Poly(p-methylstyrene)], 74 P-a-MS [Poly(a-methylstyrene)], 68 PMSQ [Polymethylsilsesquioxane], 292 Polyamideimide, 230 Polyaminobismaleimide, 228, 354 Polyacrylamide, 106 Polyarylate, 248, 361 Poly(acrylic acid; isotactic), 94, 340 Polyacrylonitrile, 102 Poly(arylether nitrile), 284 Poly(1,2-butadiene), 152 Polybutene-1 (isotactic), 20 Poly(butyl acrylate), 92 Poly(butylene succinate/adipate), 256, 365 Poly(butylene succinate/carbonate), 260, 367 Poly(butylene terephthalate), 240, 357 Poly(n-butyl methacrylate), 84 Polycaproamide, 172 Poly(3-caprolactone), 254, 364 Polycarbonate(melt method), 262, 368 Polycarbonate(solvent method), 264, 369 Polycarbonate(thermally stabilized), 268, 371 Poly(p-chlorostyrene), 72 Polychlorotrifluoroethylene, 132 Poly(1,4-cyclohexane dimethylene terephthalate), 250, 362 Polydimethylsiloxane, 286 Polydivinylbenzene, 70 Poly(dodecamethylene adipamide), 184 Polyetherimide, 224, 350 Polyethersulfone, 278, 373 Poly(ethyl acrylate), 90 Polyethylene (high density), 12 Poly(ethylene glycol bisallyl carbonate), 208, 343
Polyethylene ionomer, 40 Poly(ethylene naphthalate), 242, 358 Poly(ethylene oxide), 194 Poly(ethylene terephthalate), 238, 356 Poly(ether ether ketone), 280, 374 Poly(hexamethylene adipamide), 180 Poly(hexamethylene sebacamide), 182 Poly(p-hydroxybenzoic acid) (type A), 244, 359 Poly(p-hydroxybenzoic acid) (type B), 246, 360 Poly(3-hydroxybutylic acid), 258, 366 Poly(2-hydroxyethyl methacrylate), 86 Poly(lactic acid), 252, 363 Polylauroamide, 176 Poly(maleic anhydride), 108 Poly(methyl acrylate), 88 Poly(methyl methacrylate), 82 Poly(4-methyl-1-pentene), 22 Polymethylphenylsiloxane, 288 Poly(methyl-phenyl)silsesquioxane, 294 Polymethylsilsesquioxane, 292 Poly(a-methylstyrene), 68 Poly(p-methylstyrene), 74 Polynorbornene, 164 Polyoxymethylene, 190 Polyoxymethylene(copolymer), 192 Poly(phenylene oxide), 274 Poly(phenylene sulfide), 282 Poly(p-phenylene/3,4-diphenylene ether terephthalamide), 236 Poly(m-phenylene isophthalamide), 234 Poly(p-phenylene terephthalamide), 232 Polypropylene(atactic), 16 Polypropylene(isotactic), 14 Polypropylene(syndiotactic), 18 Polypyromellitimide, 226, 352 P(S-DVB) [Styrene-divinylbenzene copolymer], 66 P(S-MA) [Styrene-methyl acrylate copolymer], 44 P(S-Mah) [Styrene-maleic anhydride copolymer], 64 P(S-MMA) [Styrene-methyl methacrylate copolymer], 48 Polystyrene, 42 Polysulfone, 272, 372 Polytetrafluoroethylene, 130 Poly(tetramethylene adipamide), 178 Polyundecanoamide, 174 Poly(vinyl acetate), 146
390
Index
Poly(vinyl alcohol), 142 Poly(vinyl butyral), 144 Poly(vinyl chloride), 110 Poly(vinyl fluoride), 134 Poly(vinylidene fluoride), 136 Poly(2-vinylpyridine), 76 Poly(vinyl pyrrolidone), 148 Poly(m-xylene adipamide), 188 POM [Polyoxymethylene], 190 at-PP [Polypropylene (atactic)], 16 iso-PP [Polypropylene (isotactic)], 14 syn-PP [Polypropylene (syndiotactic)], 18 PPO [Poly(phenylene oxide)], 274 PPS [Poly(phenylene sulfide)], 282 Propylene-tetrafluoroethylene rubber, 140 PS [Polystyrene], 42 PSF [Polysulfone], 272, 372 PTFE [Polytetrafluoroethylene], 130 PU [TDI-polyester polyuretane], 296 PU [TDI-polyether polyuretane], 298 PU [MDI-polylactone polyurethane], 300 PVA [Poly(vinyl alcohol)], 142 PVAc [Poly(vinyl acetate)], 146 PVB [Poly(vinyl butyral)], 144 PVC [Poly(vinyl chloride)], 110 P(VC-VAc) [Vinyl chloride-vinyl acetate copolymer], 118 P(VC-VdC) [Vinyl chloride-vinylidene chloride copolymer], 112 PVDF [Poly(vinylidene fluoride)], 136 PVF [Poly(vinyl fluoride)], 134 PVP [Poly(vinyl pyrrolidone)], 148
S SBR [Styrene-butadiene rubber], 166 SBS (TPS) [Styrene-butadiene-styrene block copolymer], 168 Shellac, 322, 380 SM-PC [Polycarbonate (solvent method)], 264, 369 Styrene-butadiene rubber, 166
Styrene-butadiene-styrene block copolymer, 168 Styrene-divinylbenzene copolymer, 66 Styrene-ethylene-butadiene-styrene block copolymer, 170 Styrene-maleic anhydride copolymer, 64 Styrene-methyl acrylate alternating copolymer, 46 Styrene-methyl acrylate copolymer, 44 Styrene-methyl methacrylate alternating copolymer, 50 Styrene-methyl methacrylate copolymer, 48 Synthetic lignin, 330, 382
T TDI-polyester polyuretane, 296 TDI-polyether polyuretane, 298 Tetrafluoroethylene-hexafluoropropylene copolymer, 131
U U [Urethane rubber], 302 UF [Urea formaldehyde resin], 210 Unsaturated polyester, 216, 344 UP [Unsaturated polyester], 216, 344 Urea formaldehyde resin, 210 Urethane rubber, 302
V Vinyl chloride-vinyl acetate copolymer, 118 Vinyl chloride-vinylidene chloride copolymer, 112 Vinylidene fluoride-hexafluoropropylene rubber, 138
W Wood powder, 332
X Xylene resin, 214
