Positive one-parameter semigroups on ordered banach spaces

Acta Applicandae Mathematicae 1, 221 296. 0167-8019/84/0023~0221511.40. 9 t984 by D. Reidel Publishing Company

221

Positive One-Parameter Semigroups on Ordered Banach Spaces CHARLES

J. K. B A T T Y * and D E R E K W. R O B I N S O N

Department of Mathematics, Institute of Advanced Studies, Australian National University, Canberra, Australia (Received: 9 May 1983) Abstract. In this review we describe the basic structure of positive continuous one-parameter semigroups acting on ordered Banach spaces. The review is in two parts. First we discuss the general structure of ordered Banach spaces and their ordered duals. We examine normality and generation properties of the cones of positive elements with particular emphasis on monotone properties of the norm. The special cases of Banach lattices, order-unit spaces, and base-norm spaces, are also examined. Second we develop the theory of positive strongly continuous semigroups on ordered Banach spaces, and positive weak*-continuous semigroups on the dual spaces. Initially we derive analogues of the FellerMiyadera-Phillips and Hille-Yosida theorems on generation of positive semigroups. Subsequently we analyse strict positivity, irreducibility, and spectral properties, in parallel with the Perron-Frobenius theory of positive matrices. AMS (MOS) subject classifications (1980). 46A40, 15A48, 06F20, 46L05, 46LI0, 54C40, 54C45, 47B55, 47D05, 47D07, 47B44, 46L55, 46L60, 46B20. Key words. Ordered Banach space, normal cone, generating cone, monotone norm, Riesz norm, orderunit, Banach lattice, C*-algebra, half-norm, dissipative, Co-semigrou p, C~-semigroup, Perron-Frobenius theory, irreducible semigroup.

Contents 1. ORDERED BANACH SPACES-2 222 1.0. Introduction 222 1.1. Normal generating cones 223 1.2. Monotone norms 229 1.3. Absolutely monotone norms 232 1.4. Interior points and bases 235 1.5. Banach lattices 239 1.6. Half-norms 242 1.7. Bounded operators 246 2. POSITIVE SEMIGROUPS 251 2.0. Introduction 251 2.1. Dissipative operators 254 2.2. Co-semigroups 260 2.3. C*-semigroups 271 *Permanent address: Dept. of Mathematics, University of Edinburgh, King's Buildings, Edinburgh, EH9 3JZ, U K .

222

CHARLES J. K. BATTY AND DEREK W. ROBINSON

2.4. Semigroup type and spectral bounds 275 2.5. Irreducibility and strict positivity 283 APPENDIX: Hahn-Banach theorems

292

NOTES AND REMARKS 293 REFERENCES 295

1. Ordered Banach Spaces 1.0, INTRODUCTION

The theory of ordered Banach spaces is a development of the structure associated with the classical Banach spaces of real functions. Each of these function spaces, e.g., C(X) or LP(X;d#), can be ordered by setting f / > g whenever the function f - g is pointwise positive. This ordering can, however, be described in a more geometric manner which is more convenient for the introduction of other order relations. The pointwise positive functions in each of the classical real Banach spaces form a convex cone P because if f, g/> 0 then ,~f + #g t> 0 for all positive ~.,/~. In terms of this cone the ordering f >~g is equivalent to the statement that f - g ~ P . More generally any cone P induces an order by setting f / > g whenever f - g ~ P. Properties of the order relation are then determined by the geometric and topological properties of the cone P. Duality properties are also important. If P is a convex cone in a real Banach space ~ one can define a cone P* in the dual ~ * as the elements of ~ * which are positive on P, and then ~ * is ordered by P*. If, for example, P is the cone of positive functions in LP(X; d/~) then P* can be identified with the positive functions in Lq(X; d/~) whenever 1 ~

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

223

order defined by pointwise positivity. Moreover, the norm of a function and the norm of its modulus coincide, and as the modulus increases so does the norm. Spaces with these properties are called Banach lattices. They have been extensively studied and possess a rich, well understood, structure. Unfortunately they do not describe all the commonly encountered examples of ordered spaces. Consider the Banach space ~ of all bounded self-adjoint operators on the Hilbert space ~f'. Furthermore let ~'+ denote those operators with non-negative specturm, i.e., the positive (semi-) definite operators on ~,~f~.Then ~ + is a convex cone, with strong normality and generation properties, but the associated order on ~ is a lattice ordering if, and only if, ~,Whas dimension one. More generally if ~ is the selfadjoint part of a Banach *-subalgebra of all bounded operators on aW, ordered by ( f n ~ + , then the order has the lattice property if, and only if, the elements of commute. Since each commutative ~ can be identified with an algebra of continuous functions, these operator examples can be viewed as non-commutative versions of the continuous functions. It is naturally of interest to develop the theory of ordered Banach spaces in a way which unifies the classical function spaces and their non-commutative analogues. A useful notion for this unification is the Riesz norm discussed in Section 1.3, and it is of particular interest that this notion is self-dual. Therefore the theory of Riesz norm spaces also covers the duals, or preduals, of the function spaces, or operator spaces. A more specific concept which occurs both in the commutative and non-commutative setting is that of an order-unit. The constant function i is an order-unit ofL~(X; d/0 and the identity operator is an order-unit of the space of all bounded self-adjoint operators on a Hilbert space ~ , i.e., each element of the space is bounded by a multiple of the order-unit. In geometric terms order-units are identifiable as interior points of the cone of positive elements. Interior points and the dual concept of base are discussed in detail in Section 1.4. Finally if ~' is a Banach space ordered by a positive cone ~ + then the Banach space ,~a of bounded operators on ~ can be ordered by specifying that an operator A 6 ~ is positive if A~+ _ ~ § The study of the positive bounded operators of+ is of interest for several reasons and in Section 1.7 we discuss relationships between order properties of ~ and ~ . 1.1. NORMAL GENERATING CONES

An ordered Banach space (~, ~ +, I1 PIt consists of a real Banach space ~ with norm II II and a positive cone M§ which is defined as a norm closed subset of ~ satisfying

for all 2,/~/> O. Elements of ~ will be denoted by a, b, c. . . . and ~ closed ball of radius ~, i.e., M = { a ; a E ~ , Ilall ~<~t}.

will denote the

224

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Associated to each (8, ~ + , I1 II)there is an ordered dual space (~3", ~'*, I1 I1") consisting of the real linear functionals 8 " = {to, ~, r/.... } over ~ which are bounded, so that the dual-norm

II to II* = sup{Ito(a)l;

}

is finite, and of the weak*-closed dual cone ~ + which is defined by ~*+ -- {to; t o e ~ * , to(a)/> 0 for all a e ~ + }. Note that the dual cone automatically satisfies

The norm closed ball of radius ~ in .~* is denoted by ~ * Order relations are defined on ~ , and on ~*, by setting a >/b whenever a - b e ~ + , and { >_-r/ whenever ~ - r / e ~ * . Thus a t>0 is equivalent to a e ~ + , and ~ t>0 is equivalent to ~ e ~ * . There are two deficiencies in this structure. First there is no condition which ensures that ~'§ is large enough to introduce an interesting order relation and there is no condition which ensures that ~ + is not too large. The purpose of this section is to introduce and analyze such conditions. Further refinements of these conditions are discussed in the subsequent sections. We begin with the weakest possible form of such conditions. First the cone 9 + is defined to be weakly generating i f ~ + - ~+.is norm dense in ~ , i.e., if each a e ~ is the norm limit of a sequence { b - c,},>~, of differences of elements b,, e e l + . Similarly the dual cone ~ * is *-weakly generating if ~ * - ~ * is weak*-dense in ~*. Second the cone ~ + is defined to be proper, or pointed, if

-

= {0}.

This is equivalent to antisymmetry of the order ~>, i.e., a I> b and a ~
The generation property has the tendency to make ~ + "large' and the dual cone .~* 'small'. Conversely, the pointedness property requires ~ + to be 'small' and ~ * to be 'large'. This elementary observation is at the root of a series of duality properties of which the following proposition is the simplest. P R O P O S I T I O N 1.1.1. The following pairs of conditions are equivalent: 1. (1'.) ,9+ ( 8 * ) is (*)-weakly generating, 2. (2'.) ~ * ( ~ + ) is proper, i.e., l ~ 2 and 1' r 2'. The proof of this statement is a straightforward application of the Hahn-Banach

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

225

theorem on which we will not elaborate. Instead we turn to the analysis of stronger properties of generation and pointedness. First the cone ,~+ is defined to be generating if ~ = ~ + - ~ + , i.e., if each a e ~ has a decomposition a = b - c with b, e 6 ~ + . This is equivalent to requiring that for each a6,~ there is a b 6 ~ + such that b ~>a, in which case a has the decomposition a = b - (b - a) into components b, b - a 6 ~ ' + . Second the cone ~ + is defined to be normal if there is an a/> 1 such that c < a ~~-1 > 0 . Thus , - ~ is a positive measure of the 'pointedness' of the cone. Normality is a condition of compatibility of the order and the topology. It is equivalent to the requirement that order-bounded sets are norm-bounded. This will be established in Proposition 1.4.3. Normality and generation for ~ * are defined analogously. Again there is a duality between these properties for ~ + and ~ * . But before giving this we first establish a uniformity of the generation property which allows a more precise indexation of generation and a subsequent closer comparison with normality.

P R O P O S I T I O N 1.1.2. 7he following conditions are equivalent: 1. ~ + is generating, 2. there is an ~ >~ 1 such that each a 6 M has a decomposition a = b - c with b, c 6 . ~ + and

Ilbtl v Ilcll-<

ltall.

P r o o f 2 ~ 1. By definition. 1 ~ 2. Condition 1 can be expressed as

~-~

U (.~ c~.~+ - . ~

n.~+).

Hence by the Baire category theorem there exists a/3 t> 1 such that

The proof is then completed by estimating that

for all ~ > ~. Since this last type ofestimate will be used several times in the sequel we present it in a suitably general form. But first recall that a subset ~6 c M is called a-convex if the conditions e e l , 2 ~>0, ~,>~ i )~ = 1, together with the existence of C = Z ~'ns n>~l

always imply that c6~. For example ~ t j , ~ c ~ + , , ~ p n , ~ + - , ~ n ~ ' + a-convex sets.

are all

226

CHARLES J. K. BATTY AND DEREK W, ROBINSON

LEMMA 1.1.3. If ~ ~_ ~ is a a-convex subset such that ~ t c ~ then ~ l ~- a~ for all ~ > t. Proof. For a e ~ and 0 < 6 < 1 choose al~.c~ such that Lla-a, ll < , ~ - H e n c e 6-1(a-at)e~t and one can choose azeC~ such that [ [ 6 - t ( a - a t ) - a z U <3. By iteration one finds a e ~ such that

~-~+ I a -- i

5-n+mam

< c5.

n = 1

Therefore setting 2r, = (1 - fi)5m- 1 one has

a - ( 1 - c 5 ) -x ~n J'mara < 5 ~ nl=l

and a~(1 - 5)- 1~ by a-convexity of eft.

[]

In comparing normality and generation properties of ~ + it is of interest to keep track of the index a of uniformity. This can be done in many ways, but we concentrate on the following pair. The cone ~ + is defined to be ~+-generating if each a e ~ has a decomposition a = b - c with b, c6:~+ and

Irbll + IPclV-< ~llall and to be fly-generating if the decomposition can be chosen such that

Ilbll ,, Ilelt ~/~llailClearly ct/> 1, by the triangle inequality, and a simple iterative argument establishes that one must have B/> 1. Next ~ + is defined to be approximately e+-generatin# if it is ~f+-generating for all e' > ct and approximately fl,,-generating if it is ff,,-generating for all ,8" > 13. Similarly we introduce two types of normally. The cone is defined to be %-normalifc ~
and to be fl §

if

c ~ a

~< b

implies

IIa II ~
The following statement now generalizes the duality properties contained in Proposition 1.1.1. T H E O R E M 1.1.4. The following pairs of conditions are equivalent: 1 v' (1 + .) N+ is ev-normal (fl+'normal), 2+. (2,,.) ~ * is e +-generating (fly-generating).

Moreover the following pairs of conditions are also equivalent: 1+ ' . ( 1' v - ) ~ + is approximately c~+-generating (approximately ~ ,,-generating), 2',/. (2'+ .) ~ * is c%-normal (fl+-normal). Proof. We concentrate on proving 1 + ~ 2 , , and 1',,<=*,2+. A proof of l v , ~ 2 + and I'+ r v can be constructed on similar lines and alternative proofs of these equivalences can be found in [6]. One main ingredient of the proof is the H a h n - B a n a c h theorem. The essential information is contained in the following general lemma which will subsequently be used several times in similar contexts.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

LEMMA

227

1.1.5. lf toe~* and 2,#e[~ then

sup{2to(a) + (1 -2)to(b)+(#-2)to(c)gb,

c>-O, Ilall + Ila-b-cll <.x}

= inf{ Ilqll*

v

II,- ~toll*;~+~*.,

~to.~ ~to}

and the infimum is attained, whenever it is finite. Proof. Let S denote the value of the s u p r e m u m and I the value of the infimum. N o w if b, c / > 0 , Ilall + I l a - b - ell ~ 1,, ~> to, a n d n I> ,to, then 2to(a) + (1 - 2)to(b) + (/~ - 2)to(c) <. (2to - q)(a - b - c) + r/(a)

~< II, - :-to II* " II, I1" Thus S ~ I. The converse inequality follows by application of the multiple H a h n - B a n a c h theorem, T h e o r e m A2 of the appendix, with n = 4 and with the Pi chosen such that Pl (b) = S IIb II,

p2(b) = S IIb II + 2to(b)

P3(b)=foJ(b) (+

if-be,~+, if - b ~ , ~ + ,

oc,

~r~to(b) Pg(b) = ( + ~;.

if-bee+ if - b r

Thus i f b 1 + b 2 + b 3 + b 4 = 0 one has 4

Pi(bi) = + ~c i=1

for

-

b 3 5 ~ + or

-

-

b4r

+ and

4

Z Pi(bl) = S( I[b, II + IIb2 II) - {2to(b,) + (1 - 2)to( - b3) + (/l - 2 ) t o ( - b,)} i=1

/>0 for - b 3, - b4eM + . Hence by T h e o r e m A2 there exists a linear functional q; ~ - ~ 1 ~ satisfying q <~Pi for i = 1,2,3,4. In particular qe:~*, H~II* <.s, I I ~ - : . t o l l * ~ s , r//> to, and q t> #to. Thus I ~< S. But this implies the equality I = S and also establishes that t/attains the infimum. [] N o w let us return to the p r o o f of T h e o r e m 1.1.4. 1+ ,:=:-2v. Choosing 2 = 1 and ~ = 0 in L e m m a 1.1.5 one finds, after a slight rearrangement of notation, that

sup{to(a); b <'-a<'-c, Ilbll + Ilcll

~< 1 } - - i n f { I[~ll* v

II.ll*;~,~/>0,to = ~ - ~}

and the infimum is attained. But this is just a statement ot the equivalence of/~+normality of ~'+ and /~v-generation of ~ * . For example if ~ + is /~+-normal, the identity gives fl Uto [I* ~> s = I and, since the infimum is attained, ~*+ i s / / v - g e n e r a t i n g Conversely if,~*+ is/~v-generating the identity gives ~lltolt*/> sup{to(a); b ~
Ilbtl + Ilcll ~ 1}

and this implies that :~+ is fl+-normal.

228

CHARLES J. K. BATTY AND DEREK W. ROBINSON

l'v~2' + . Leta=b-cwithb, then

c~M+ and IIbl[ v Ilcll
'

((b) - q(c) < to(a) < q(b) - ((c).

Therefore

Ito/a)l < ~'/II ~ I1" + II, II*)II a II. which implies that

IIto I1" < ~'t IIr I1" + H~ I1") Since this is valid for all//' > fl the cone M* is fl+-normal. 2'+ ~ 1'v . Condition l'v is equivalent to

for all fl' > ft. But the set M# n ~ + - Man M+ is a-convex and hence, by Lemma 1.1.3, it suffices to establish that ~1 - ( ~ p n ~ +

-~n~+).

But taking polars and using the bipolar theorem, Theorem A3 of the appendix, this is equivalent to ~ ' _ ( ~ n ~ + - ~ n ~ + )o. Now if c o e ( ~ n ~ + hence

-~on~+)

fl sup {to(a); a e ~

(,) ~ then f l t o ( a - b ) < 1 for all a, b e ~

n ~ + } - fl inf{to(b); b ~ l

n~+

and

n ~'+ } < 1.

But Lemma 1.1.3 with 2 = 0 and # = 1 gives sup{to(a); a e ~ , n ~ + } = inf{ 11r I1"; r

r t> to}

and replacing to by - to it also gives inf{to(b); b e ~

n ~ + } = - inf{ II~ It*, ~*,

~ ~> - to}.

Combining these identities with the foregoing inequality one deduces that flinf{ 11411* + II, I1". r q~*,

~
< 1.

Therefore t o e . ~ , by Condition 2'+ and (*) is valid.

[]

The second statement in Theorem 1.1.4 is optimal in the sense that approximate ~t-generation does not necessarily imply ~t-generation. Example 1.1.9 below provides a counterexample. This asymmetry between ~ and ~*, i.e., the appearance of approximate properties in ~, arises because ~ * is always weak*-compact but ~'~ has no general compactness property. In special cases, e.g., if ~ is reflexive, one can deduce from compactness that approximate ~-generation implies ~t-generation but not in general.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

229

EXAMPLE 1,1.6 (Classical function spaces). Let ~ = LP(X; dp) for some measure space (X;d/D and some p c [ l , oc]. Define q such that l/p+ 1/q = 1. Next let 8 + be the cone of pointwise positive functions in ~. It follows that ~ + is 1 +-, or (2 z P)v-, normal and lv-, or (21'q)+-, generating. The result for C(X) is identical to that for L~'(X; dp), i.e., .8+ is 1 +-, or 1 v-, normal and 1 v', or 2+-, generating. [] EXAMPLE 1.I.7 {C*-algebras). Let .~ be the self-adjoint part ofa C*-algebra and ~ + the cone of positive elements of the algebra. This is a non-abelian version of C(X) and the conclusions are identical, .8+ is 1 +-, or 1 v', normal and 1 v-, or 2+-, generating. [] EXAMPLE 1,1.8 (Affine functions). Let K be a compact convex subset of a locally convex Hausdorff space and A(K) the continuous affine functions equipped with the supremum norm. If A(K)+ is the set of pointwise positive functions it is again 1+-, or Iv-, normal and 1 v-, or 2+-generating. [] EXAMPLE 1.1.9 (Approximate 0t-generation). Let ~ be the Banach space of sequences a = {a}.>. 1 satisfying I. a ~ 0

as

2. a I + a 2 =

n~

E a.+2/2" n~>l

equipped with the supremum norm and let ~ + consist of the a e ~ with a t>0. It follows that ~ + is approximately l v-generating but not Iv-generating, and approximately 2+-generating but not 2+-generating. [] E X A M P L E 1.1.10 (A non-normal cone). Let .~ = L2(~";d"xt with norm 11"]12 and let H = - W denote the positive self-adjoint Laplace operator on ~ . Define

S~ = D(Hll2)and

Ilfll =(ltfll = for f ~ . mal.

+

IIH 1/27112 ) 1/2

d'x Is(x)l

J/

If ~ . is the cone of pointwise positive functions in M, then DS+ is not nor-

In the next sections we examine variants of the normality and generation conditions which are directly related to monotonicity properties of the norm.

1.2. M O N O T O N E N O R M S

Let (~, :~+, [[.[[ } be an ordered Banach space. The norm is defined to be ~-monotone if 0 ~ 1, and i f , = 1, we simplify the terminology by saying that the norm is monotone, If ~ + is a+-, or %-, normal, then []'1[ is , - m o n o t o n e and conversely if [['H is a-

230

CHARLES J. K. BATTY AND DEREK W. ROBINSON

monotone, then ~ + is (a + ~)+-,t or (2a + 1)v-, normal. Another relationship between normality and monotonicity is given in terms of equivalent norms. P R O P O S I T I O N 1.2.1. The following conditions are equivalent: 1. ~ + is normal, 2. there exists an equivalent monotone norm. In particular if ~ + is normal it is 1 +-normal with respect to the equivalent monotone norm

I/aI]+ = i n f { IlbH + Ilcll; c < a <~b} and it is 1 v-normal with respect to the equivalent monotone norm IlaHv=inf{Hbll vllcll;c<<-a<~b}. The proof that 1 ~ 2 follows by verifying that IIll 4, or IIll v, is an equivalent monotone norm. This is straightforward, as are the other statements, and hence we omit the details. We note in passing that duals to IIll + and II" II v are given by

IIco II* = inf{ I] ~ II* + II~ I1"; co -- ~ - ~, ~, ~*

},

e.g., the first identity is a consequence of Lemma 1.1.5 with 2 = 1, # = 0. Next we examine dual characterizations ofa-monotonicity. For this it is appropriate to introduce a different index of generation. The cone ~ + is defined to be a-dominating if each a e ~ has a decomposition a -- b - c with b, c e ~ + and IIb [I ~a and Ilbll a. Subsequently we also use the terminology (approximately) dominating in place of (approximately) l-dominating. T H E O R E M 1.2.2. The following conditions are equivalent: 1 IIll is a-monotone, 2. ~ * is a-dominating. Moreover the following are also equivalent: 1'. ~ + is approximately a-dominating, 2'. lll[* is a-monotone. Proof. The proof is very similar to that of Theorem 1.1.4 and so we only sketch the outlines. 1r This follows by another application of Lemma 1.1.5, but this time with 2 = 0 = p. After a slight rearrangement of notation the lemma gives sup {co(a); 0 ~
1} =

inf{ tl r/I[* ; q ~ ~ * , ~/~> co}

and the required equivalence follows straightforwardly. 1 ' ~ 2'. This is again an easy estimate.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

231

2 ' ~ 1'. Property 1' is equivalent to the statement that

#$1 ___(#S~, n#s+ - # S + ) for all ~t' > ~. But we next argue that ~ = (#S n #S+ - #S+) is a a-convex set and hence, by Lemma 1.1.3, it suffices to prove that

#s~ ___(#s n#s+ - #S+).

(,)

In order to establish the a-convexity of cg, assume c, e ~ and c = Y-2 c, exists in #S for 2 / > 0 and E2 = 1 . Then c = a - b w i t h a e # s n#s+ and b e # s + . But a = =EAa automatically exists in #S n#s+ and Y , 2 b must exist in #S+, because b, = a - c,. Finally (*) can be established in its polar form

#s~ ~(#s n#s+ - #s+)~ by a slight variation of the argument used to prove the analogous statement in Theorem 1.1.4. [] The case ct = l, corresponding to monotonicity of the norm, has an alternative dual characterization of a completely different nature. First note that for any ae#s there exists, by the n a h n - B a n a c h theorem, an toe#s* such that to(a)= IialI. If, however, a is positive, it is not generally possible to conclude anything about the positivity of to. For this one needs monotonicity of the norm. T H E O R E M 1.2.3. The following conditions are equivalent: 1. II II is monotone on #S, 2. for each ae#s + there is an toe#S* n # s * such that to(a) = II a II. Moreover the following conditions are also equivalent: 1". [1"[[* is monotone on #S*, 2*. /ftoe#s* then II to It* : sup{to(a); ae#s+ n #S,}. Proof. 1 ~ 2 . If toe#s* then since monotonicity of the norm IIll is equivalent to domination of #S*, by Theorem 1.2.2, there exists an qe#s*+ n#s* such that r/t> to. Therefore ifae#s+ and ~o(a) = IIa II one has

IIa II = to(a)

IIa II

and q satisfies Condition 2. 2 ~ 1. IfO ~
llall

then

1ra IJ = to(a) ~
232

CHARLES J. K. BATTY AND DEREK W. ROBINSON

positive functions, then the norm is monotone. Moreover for p c ( 1, ~ ) the norm of each positive f E L ~ is attained by the unique positive normalized element f P J/ IIf IIp-1 of the dual. Ifp = 1 or Go, or i f ~ = C(X), uniqueness fails in general. [] EXAMPLE 1.2.5 (C*-algebras). If ~ is the self-adjoint part of a C*-algebra, and ~ + the positive elements, then the norm is monotone because .~+ is Iv-normal (Example 1.1.7) and the dual norm is monotone because ~ + is 1 v-generating, and hence ~ * is l+-normal by duality. Moreover, if a~.~+\{O} and 0 9 ~ * satisfies 09ta) = II09 II * IIa I[, then 09 is automatically positive. This follows because .~* is 1+generating and if 09 = r / - r with q, Ce ~ * and [[09 l[ * = II~ I1" + IIr I1" one has 09(a) ~< r/(a) ~< 11r/[1* IIa ]j <~ [I09 I[* [1a 1[ which implies []r/[] * = [109 ][ *, [[~ ]]* = 0, and 09 is positive.

[]

EXAMPLE 1.2.6 (Affine functions). Consider the space M = A(K) of affine functions of Example 1.1.8. Then the norm and dual norm are both monotone and if a e.8+ \{0}, 09~.~*, and 09(a)= [109 [[* I]a [], then 09e.~*. These statements follow from Example 1.1.8 and the reasoning used in Example 1.2.5. [] EXAMPLE 1.2.7 (Two-dimensional spaces). Let ~ = ~2 with .8+ = ~2. The unit ball is convex but the norm is monotone if, and only if, the left derivative of the unit sphere at each point in the first quadrant is negative. The unit sphere in the third quadrant is determined by symmetry from the first quadrant, but monotonicity places no further restraint on the sphere in the second and fourth quadrants. [] 1.3. ABSOLUTELY M O N O T O N E NORMS

In this section we consider a more stringent notion of monotonicity for the norm, absolute monotonicity. This is of interest for several reasons. First, the norms and dual norms of the classical function spaces, and of C*-algebras, have this property. Second, absolute monotonicity of an equivalent norm and its dual norm are characteristic of normal generating cones. Third, the concept is useful in the theory of semigroup generators, the topic of Part 2. Let ( ~ , : ~ + , ItlI) be an ordered Banach space. The norm I1"11 is defined to be g-absolutely monotone if - b ~i 0 and taking a = b6~+\{O} one must have g i> 1. Next we define the dual concept. The cone ,~+ is defined to be g-absolutely dominating if for each a ~ there is a b / > 0 such that - b ~ g. Subsequently we use the simplified termir, ology absolutely monotone for labsolutely monotone and (approximately) absolutely dominating for (approximately) 1-absolutely dominating. The duality between these concepts is as follows.

POSITIVE ONE-PARAMETER SEM1GROUPS ON ORDERED BANACH SPACES

233

1.3.1. The following conditions are equivalent: 1. IIll is g-absolutely monotone, 2. N* is g-absolutely dominating. Moreover the following conditions are also equivalent: 1'. N+ is approximately g-absolutely dominating, 2'. IIH* is e-absolutely monotone. Proof. The proof is analogous to the proofs of T h e o r e m 1.1.4 and 1.2.2. Hence we only sketch the outlines. 1 ,:*2. This follows from L e m m a 1.1.5 by setting 2 = 0 and/2 = - 1. After a slight rearrangement of notation this gives

THEOREM

sup{o)(a);b+_a >10, Ilbll

~< 1} = inf{ I],II*;,wN*., i> ___o)}

r

and the infimum is attained. The required equivalence follows immediately. 1' ~ 2'. If - b ~< a ~ b and - r/~< o ~< r / t h e n Io)r ~,(b). Hence if IIb [I ~ g' IIa H one concludes that ]l co II* ~<~' II, II* 2' ~ 1'. Define ~ by (~ = {a; d e N , - b ~ a ~< b for some beN~ }. It follows immediately that (~ is o-convex. Hence by L e m m a 1.1.3 it suffices to show that N 1 c ~ or, equivalently ~0 c N* But this follows directly from (*). [] The most interesting monotonicity and domination properties are those with ct = 1 and the most interesting situation is when both such properties are satisfied. We define the norm of an ordered Banach space (N, N + , I111) to be a Riesz norm (a stron 9 Riesz norm)if I1 II is absolutely m o n o t o n e and N+ is approximately absolutely dominating (absolutely dominating). There are several implications of T h e o r e m 1.3.1 for Riesz norms which are worth noting. First 1111 is a Riesz n o r m if, and only if, it is absolutely m o n o t o n e and the dual norm is also absolutely monotone. Second if IIll is a Riesz norm then the dual norm It" 1/* is a strong Riesz n o r m and conversely if IIll* is a Riesz norm then I1"11 is a Riesz norm. Finally, by combination of the various definitions, one concludes that II11 is a Riesz norm if, and only if, it has the representation - -

- -

at"

[lan = inf{ lib ]l; b e N , - b ~
IIll,

can

be

234

CHARLES J. K. BATTY AND DEREK W. ROBINSON

and then the dual Riesz norm is given by

II~o I[* = inf{ []t 1 1 1 " ; ' 1 ~ * , ' - '7 ~

~<'l}-

Proof. 1=>2. Since ~ + is generating a ~ l l a [ I , is everywhere defined. Now + is 9 v-normal for some ~/> 1 and hence - b ~< a ~< b implies IIa I[ ~ ~ IIb It. Therefore IIa II -< ~ IIa lit. But ~ + is also fl+-generating for some fl >/1 and hence a has a decomposition a = b - e with b, e >/0 and IIb II + IIe II ~ ~ IIa II. Since - (b + e) ~< a ~< (b + e) and J[b + e II -< IIb II + IIc II it follows t h a t IIa tl, -< ~ 11a II. Consequently IIll~ is equivalent to IIll. 2 o 1. since an equivalent Riesz norm exists ~ + is generating, by definition. Let [[" [j, denote the equivalent norm and chose ?, 6 > 0 such that y IJa Jl ~< IIa [I, ~< 6 IJa IJ for all a ~ . Then if 0 ~< a ~< b one has IIa I1~ ~< IIb II, by absolute monotonicity and hence I[a II ~ ~-1 ~ Itb [I Thus I1"II is ~-' 6-monotone and consequently ~ + is normal. The representation of the dual Riesz norm I1"I1" follows from L e m m a 1.1.5 with 2 = 0 and/~ = - 1. Explicitly one obtains

inf{ I1~ I1"; ~ * ,

-~ ~

~)

= sup{og(a); - b ~
= sup{l~o(a)l; Ilall, ~< 1} = II~o IlL

[]

There is another way of rephrasing the representation of a Riesz norm which is illuminating. If d _ a/> 0 and one sets b = (d + a)/2, c = (d - a)/2, then a = b - c, d = b + c, and b, c/> 0. Therefore the Riesz norm is given by Hall = i n f { lib + c l l ; a = b - c , b , c >~0}, and if IIll is a strong Riesz norm the infimum is attained. This states that a has a decomposition a = b - c as the difference of positive components b and c, such that Ilall ~ lib + eli. But b + c corresponds to a 'modulus' of a and the fact that a and its modulus have the same norm is a form of orthogonality of b and c. In particular examples, such as function spaces and C*-algebras, the existence of an appropriate norm conserving modulus allows one to verify the Riesz norm property. Finally this description of the Riesz norm in terms of positive and negative c o m p o nents can be amplified; absolute monotonicity of I][I is equivalent to the bound

llaH ~
~>0}

and approximate absolute domination of ~ + is equivalent to Ilalj ~ i n f { Jib + cJJ ; a = b - c , b , c / > 0 } . E X A M P L E 1.3.3 (Function spaces). I f ~ = LP(X; d/~) with ~'+ the pointwise positive functions then - f ~< g <~f implies Igl ~ Ifl and hence IIg IIp ~< IIf IIp, for all p e [ 1, @ ]. Thus the norms I111~ are all absolutely monotone. But g i v e n f one has - Ifl ~ f ~< Ifl and II Ill II~ = IIf ][p- Thus ~ + is absolutely dominating for all p c [ 1, ~ ]. Therefore all the LP-norms are strong Riesz norms. Similarly the supremum norm on C(X) is a strong Riesz norm. []

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

235

EXAMPLE 1.3.4(C*-algebras). Let ~ be the self-adjoint part of a C*-algebra ordered by the positive elements, then the C*-norm is a strong Riesz norm. This follows because each a e ~ has a modulus In[ satisfying lal ~ _+ a and Illalll = Ilall. In particular II II is absolutely dominating. But [1"II is absolutely monotone because ~+ is Iv-normal. [] EXAMPLE 1.3.5 (Two-dimensional spaces). Let 9~ - - R 2 with ~ + = B E . Monotonicity of the norm places restraints on S 1, and S 3, the segments of the unit sphere in the first, and third, quadrant (see Example 1.2.7). Now for a = (a 1, a 2 ) E S , consider the closed rectangle D, with vertices ( + a~, + a2). The norm on ~ is absolutely monotone if

nest

and

.~+ is absolutely dominating if

Uo~ a~Sl

Thus

I[ II is a (strong) Riesz norm Uo,,-

if, and only if,

aeSl

These characterizations can also be stated in terms of symmetry properties of ~ 1 , e.g., the norm is a Riesz norm if, and only if, "~1 is symmetric under reflections (a,, a 2 )~--*( - a,, a 2 ).

[]

In the next two sections we consider two special classes of ordered Banach space which extend-these examples, spaces with order units and spaces with a lattice ordering.

1.4. INTERIOR POINTS AND BASES

An element u of the cone ~ + is defined to be an interior point if ~ + contains an open neighbourhood of u, i.e., if there exists a x e > 0 such that {a; I[u - a II < E} ~ ~ + . The set of interior points o f ~ + is denoted by int ~ + . Note that if ueint ~ + , begS+, and 2 > 0, then 2u + beint ~ + . Therefore int 9~+ is either empty or norm dense in ,~+.

An element u e ~ + is defined to be an order-unit if

= U [2~>0

where the order-interval [c, b] is defined by [c, b3 =

{a;c

But if u e i n t ~ +

then a e [ - 2 u ,

2u] for all 2>[[al[/e, because I [ u - ( u + - a / 2 ) l[=

236

CHARLES J. K. BATTY AND DEREK W. ROBINSON

= IIa 11/2 < ~, and hence each interior point is an order unit. Conversely, if u is an order-unit then a t ~ [ - 2ou, 2oU] for some 2 0 > 0, by the Baire category theorem, and this implies {a; I/u - a[I < l/Zo} -~ a + . Thus each order-unit is an interior point of a + and the two concepts, interior point and order-unit, coincide. If Jut ~ + is non-empty then ~ + is generating and, for each ueint .~+,

IIa Ilu = inf{2 > 0; a t [ - 2u, 2u] } defines a semi-norm on a . Moreover ~'1 -~ [ - 20 u, 20 u] implies /Ia Ilu ~<20 (Ia[I. The semi-norm I[ II. is a norm if, and only if, .~+ is proper in which case it is a strong Riesz norm for which .~§ is 1 v-normal. It also follows by a series of simple estimates that N+ is normal with respect to t['tl if, and only if, 11"[I and hl'll, are equivalent norms. Now an ordered Banach space (~', M+, tlll) is defined to be an order-unit space if a + contains an interior point u and I1"I[ -- I1 I1~. Equivalently (a, a + , I1"I1) is an order unit space if a~ = [ - u, u] for some u ~ ' + . The first definition clearly implies the second, but a t --- [ - u, u] implies u6int v~+, Ilall ~< Ilall,, and conversely u IIa II. ~ a ~< u i[ a [1~ implies a~ IIa I1~,, i.e., IIa I1~ ~ IIa II. There is a dual concept defined in terms of bases. A base for ~ + is a norm-closed, convex, bounded, subset K of a + such that for each a ~ + there is a unique 2x(a ) ~>0 such that a62x(a)K, If ~ + has a base it is not difiqcult to show that it is normal, but not necessarily generating. If, however, a + is generating and has a base K -

rid II~ = inf{2 1>O; a~2 co(K u - K)} defines a norm on a . Again it is readily verified that IIll~ is a Riesz norm which is equivalent to I[" [1" Note that c o ( K w - K ) i s a-convex and hence the I[-[IK-unit ball is the closed convex ball U6(K w - K), by Lemma 1.1.3. Now an ordered Banach space (~, N+, II'll) is defined to be a base-norm space if ~ + is generating and has a base K and II'll = [I'IIK. Equivalently (~, N'+, II II) is a base-norm space if a~ = ~6(K w - K) for some base K. Similarly if II" H* ~ I1tl for some weak*-compact base K o f ~ * , or i f ~ * = co(K ~ - K~, then (.~'*, M*, II'll *} is defined to be a dual base-norm space. The duality between these concepts and the general representation of order-unit spaces is given by the following. THEOREM

1.4.1. The following conditions are equivalent." space, 2. (a*, a . ,* It [[*)is a dual base-norm space, 3. ~, 4+, I1 [I) is isometrically order-isomorphic to the space (,4(KI, A(K)+, [t[[o0 ) of continuous affine functions over some compact convex set K, ordered by the positive functions and equipped with the supremum norm. Moreover the followino conditions are equivalent: 1'. t~, a+, IIll) is a base-norm space,

1. In, a+, I1 It) is an order-unit

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

237

I111")is an order-unit space. Proof. 1 =~2. Let u be the interior element with I1" flu -- I1" II. F o r c o ~ *

2'.

Ilcoll*

=sup{co(b); -u

~
= cotu).

Therefore

g = {co,

II coil*

= 1}

is a w e a k * - c o m p a c t base for ~ * . Since ~ + is l v-normal, ,~* is 1 +-generating, by T h e o r e m 1.1.4, and hence ~ * = c o ( K w - K) = ~6(K u - K). 2 ~ 3. Let K be a w e a k * - c o m p a c t base for ~ ' * with ~ * = c o ( K w - K). For each b ~ define O(b) on K by (0(b))(co) = co(b). Then 0 is an isometric o r d e r - i s o m o r p h i s m o f ~ into A(K). N o w for aeA(K) define ~i on ~ * by a ( 2 ~ / - pC) = 2a(~) -/~a(~) when 2, p t>0 and ~/, ~ K . Since K is a base and a is affine this gives a well-defined linear functional ~i on ~ * . But ~ is weak*-continuous on ~ * = c o ( K w - K) by weak*-compactness and therefore ~ i ~ by the K r e i n - S m u l i a n theorem. Since 0(~i) = a the m a p p i n g 0 is surjective. 3 ~ 1. This is a simple verification with u = 1. 1 ' ~ 2'. Let K be a base of ~ + with , ~ = ~-6(K w - K). The associated functional a e ~ + ~ - , 2 x ( a ) ~ § extends to a linear functional on ~ which is an order-unit for .~* with IIll = I111". 2 ' ~ 1'. Let p be the order-unit of ~ * for which I111 = I111" and define K = {b; b e ~ + , p(b)= 1}. It follows from the bipolar theorem, T h e o r e m A3 of the appendix, that K is a base for ~ + and , ~ = ~6(K w - K). [] T h e o r e m 1.4.1 is an isometric version of part of the following result. PROPOSITION In this case,

1.4.2. 1. int ~ + :fi 0/f, and only if, ~ * has a weak*-compact base K.

int ~ + = {u; u e ~ + ,

inf co(u) > 0}.

If :~ + is normal, the correspondence between interior points of ~ + and weak*-compact bases for ~ * is bijective. 2. ~ + has a base K if, and only if, int .~* 4: 0. In this case, int ~ * = {p: p e ~ ' * , inf p(a) > 0}. aEK

If ~ + is generating, the correspondence between bases for K and interior points of J3* is bijective.

238

CHARLES J. K. BATTY AND DEREK W. ROBINSON

3. ~ + has a base K if, and only if, there is a constant a such that a

Za ~s

Z Ilall a6S

for all finite subsets S of ~ +. Proof. 1. If u 6 i n t ~ + , then K = {co;coe~*,co(u)-- 1I is a weak*-compact base for ~ * . If ~ * has a weak*-compact base K, elementary estimates show that int,~+ -- {u; u e ~ + , inf rco(u ) > 0/, and the Hahn-Banach separation theorem, Theorem A3 of the appendix, shows that int ~ + =fi0. If, moreover, ~'+ is normal, so ~ * is generating, 2 r extends to a linear functional on ~*, which is weak*-continuous on co(K u - K), a (norm) neighbourhood of 0 in ~*. By the Krein-Smulian theorem. 2~ belongs to ~ and hence to int ~ § 2. The proof is similar to part 1. If peint ~ * , then K = { a ; a 6 ~ + , p ( a ) - - 1} is a base for ~ § If ~ + is generating and has a base K, then 2 r extends to a linear functional in int ~ * . 3. If ~ § has a base K, and a = sup{ [Ia II/ll b [I;a, b e K } , it is readily verified that a II Y o sa II Xaos II a II Conversely, if this inequality is always satisfied, then IIb II >/1 whenever b 6 c o { a e ~ + ;llall = a I, so by the H a h n - a a n a c h separation theorem, there exists c o ~ * such that co(a) I> 1 whenever a E ~ + , IIa II = a Then q ~ * whenever [Ico - q ][* ~ I]E sail for all finite S _ ~ + , then [].[] is said to be a-additive. Alternatively, if for each finite S _~ ~1, there exists b ~ , such that a ~ b for all a~S, then :~ is said to be a-directed. The above result, together with weak*-compactness, shows that [[' [[ is a-additive if, and only if, ~ * is a-directed, It may also be shown that ~ is a'-directed for all a' > a if, and only if, ]['][ * is a-additive (see [6] ). The existence of interior points in ~ + and normality of ~ + are in a sense complementary properties. This complementarity can be summarized in terms of the set b(~) of norm-bounded sets in ~ and the set o(~) of order-bounded sets. P R O P O S I T I O N 1.4.3. 1. int ~ + :p 0/f, and only if, b(~) ~_ o(~). 2..~+ is normal if, and only if, o(~) ~- b(~). Proof 1. If {a; IIu - a 1[ < e} _ ~ + then ~x _ [ - e-~u, e-~u] and conversely if N~ _ [c, b] then {a; I1a - b II < 1 } _~ ~ + . 2. If ~ + is normal there is an a I> 1 such that [c, b] _~ ~ , for fl = a( [[b II v IIc II). Conversely if ~ + is not normal there exist sequences a . , b such that a.e[0, b.] and IIb. II Ila, ll>4". Thus defining b = E 2 - " b one has 2 - " a e[0, b] but 2-"a, [[ > 2 n. Thus [0, b] Cb(~). [] One immediate corollary is that o ( ~ ) = b(~') if, and only if, ~ + is normal and int ~ + :p 0. There are various weaker notions of interior point, or order-unit. For example u e ~ + is called a quasi-interior point if co(u) > 0

POSITIVE ONE-PARAMETER SEMIROUPS ON ORDERED BANACH SPACES

239

for all ~o~:~*\{0}. Equivalently u is a quasi-interior point if for each a~,8 and e > 0 there exists a b~M and 2~R+ with Ila-bll <~, b ~;.u. (The first of these definitions states that {0} = ( ~ + u - ~ + ) ~ and the second states the polar form ~=(R+u-~+).) Quasi-interior points exist only if .9+ is weakly generating, and the converse is true if ~ is separable. It can happen, however, that quasi-interior points exist but ~ + is not generating, e.g., this is the situation in the dual of the space given in Example 1.1.10. Nevertheless one has one of two extreme situations, the set qu.int ~@+ of quasi-interior points is empty, or norm-dense in ~ + . This follows because u~qu.intb~+ implies 2u + a ~ q u . i n t ~ + for all 2 > 0 and a ~ + . Furthermore int ~ + c qu.int ~ + with equality whenever int ~ + ~ 0. This is a consequence of the H a h n - B a n a c h separation theorem, Theorem A3 of the appendix. Any proper generating cone in a finite-dimensional space has both interior points and bases. But in i,qnite dimensions all possibilities occur. EXAMPLE 1.4.4 (Function spaces). Let ~ = L P ( X ; d # ) with p e [ l , @ ) and let ~ + be the cone of pointwise positive functions. If ~ is infinite-dimensional then i n t ~ + = 0 and qu.int M+ = { f ; f > 0 a . e . } ; if p > 1 then ~ has no bases and if p = 1 then ~ + has the base K = { f ; f ~>0,~ d p f = 1}. Note that if d# is not a-finite qu.int ~ + = ft. The case ,9 = L ~ (X; d~t) is somewhat different. This is an order-unit space with order-unit the constant function of value one and if M is infinitedimensional it has no bases. [] EXAMPLE 1.4,5(C*-algebras). Let M be the self-adjoint part of an infinitedimensional C*-algebra with identity ordered by the positive elements. Then M is an order-unit space, with order-unit the identity, and int M+ = qu.int ,~+ = {a; a >/0~ a invertible}. The theory of C'algebras [59-] shows that ~ has a subspace isometrically order-isomorphic to C(X) with X infinite. Since C(X)* has no interior points it follows that ~ + has no bases. [] E X A M P L E 1.4.6 (Order-units and bases). Let ~ be the subspace of l ~ consisting of the sequences of a={a,},~>~ satisfying a2,_ ~ + a z =a ~+a 2 and let ~ + = = {a; a e ~ , a, f> 0}. Then ~ is an order-unit space with order-unit a, = 1, int ~ + = = q u , i n t ~ + = { a ; a e ~ , i n f a >0}, and ~ + has the base K = { a ; a E ~ + , a , + a 2 = 1}. []

1.5, BANACH LATTICES

Consider an ordered Banach space (~, ~ + , I1 II) which is a lattice in the given ordering, i.e., each pair a, b ~ has a least upper bound a v b and a greatest lower bound a ^ b. If la [ ~< [b[ always implies IIa [1 ~< I[b II, where [a [ = a v - a denotes the modulus of a, then (~, ~ + , I1 II) is defined to be a Banach lattice, For example if ~ is a lattice and I111 is a Riesz norm then ~ is a Banach lattice. In particular C(X) and LP(X; dp)

240

CHARLES J. K. BATTY AND DEREK W. ROBINSON

are Banach lattices. Moreover if ~ is a lattice and either an order-unit space, or a base-norm space, then it is a Banach lattice, and can be identified with C(X) or LI(X;d/~) (see Theorems 1.5.1 and 1.5.2). Alternatively the self-adjoint-part of a C*-algebra is a lattice if, and only if, the algebra is commutative [11]. There is a very detailed theory of Banach lattices and an extenswe literature on this subject (see, for example, [75, 31, 82]. We mention only those aspects which are of interest in the sequel. In any Banach lattice the norm is a strong Riesz norm, e.g., since - [al ~
Ila+ II v Ila_ II ~<(illalll § Ilall)/2 = Ilall. The 1 +-normality can also be verified by a simple calculation, or deduced by duality from the 1 v-generation of ~ * . Next we describe the main representation theorems for lattices which are orderunit spaces, or base-norm spaces. First note that if (~, ~ + , fltl) is a lattice and an order-unit space then

Ila v bJI--Ilall

v I[bll

for all a, b e ~ + . Banach lattices which satisfy this latter property are called AMspaces and the following theorem gives a representation of such spaces. T H E O R E M 1.5.1. Let (~', ~ + , equivalent:

II II) be a Banach

lattice. The following conditions are

1. IIa II -- IIa+ II v 11a_ 11, a s ~ , 2. [[a v hi[ = Ilal[ v Ilbll, a, b E ~ + , 3. (M, ~ + , I['N) is isometrically order-isomorphic to a sublattice of (C(X), C(X)+, I1 II~ ) f o r some compact Hausdroff space X. Moreover the followin 9 conditions are also equivalent: 1'. (~, ~+, IIll) is an order-unit space, 2'. (~, ~ + , l[" II) is isometrically order-isomorphic to ( C( X), C( X) + , [t ' ft o~). Next consider base norm spaces. If (~, ~ + , space, then one can verify that

I[tl) is

a lattice and a base-norm

IIa + b]l = Ilal[ + Ilbll for all a, b ~ + .

Banach lattices with this property are called AL-spaces. The dual

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

241

of an AM-space is an AL-space, and vice-versa. The analogue of Theorem 1.5.1 for these dual spaces is the following. T H E O R E M 1.5.2. Let (~, ~ + , are equivalent:

I1 II) be

a Banach lattice. The followin# conditions

1. li a il = I1a + li + ii a_ it, a 2. Ila+bll =llall + Ilbll, a, b e ~ + , 3 /~, ~+, I111/is isometrically order-isomorphic to L'(X; dp) for some measure space ( X, dp). 4. {o~, ~ + , II" tl) is a base-norm space. It is now a simple task to strengthen the results of Section 1.4 when ~ is a lattice. COROLLARY 1.5.3. Let (~, ~ + , I1-11)be an ordered Banach space which is a lattice in the given order. 1. int ~ + ~ 0 ~ and only if, (~, ~ + , I[. It) is topologically order-isomorphic to (C(X), C(X)+, I['[[~)for some compact Hausdorff space X. 2..~+ has a base if, and only if, (~, ~ +, I[lt) is topolooically order-isomorphic to Ll(X ; dp) for some measure space (X, dp). Finally we examine two general properties closely related to the lattice property. An ordered vector space (~, ~ § is said to have the Riesz interpolation property if, at, a 2, b,, b z ~ and a i ~
[]

The following is an analogue of Corollary 1.5.3. (For the various definitions of Choquet simplexes see [2, 6].) T H E O R E M 1.5.5. Let ( ~ , : ~ + , I['[[) be an ordered Banach space with the Riesz interpolation property.

242

CHARLES J. K. BATTY AND DEREK W. ROBINSON

1. int ~'+ @ 0 /f, and only if, (~, ~ + ,

I111) is topologically order-isomorphic to

(h(g), a(g)+, I1"11~) for some Choquet simplex K. 2. ~ + has a base if, and only if, (~, ~ +, IIll) is topolooically order isomorphic to LI(X ; d # ) f o r some measure space (X, d#). Proof 1. This is a standard fact in C h o q u e t theory (see, for example, [6] T h e o r e m 2.7.1). 2. It suffices to assume that [].]] is a b a s e - n o r m and to show that ~ is a lattice. The result then follows from Corollary 1.5.3. Let a, b ~ + and c, a sequence in ~ such that a ~< e,, b ~< c , and I]c tt < ~ + 2-", where = inf{ IIc II, c ~ , a <<.c,b <~c}. Using the Riesz interpolation p r o p e r t y it m a y be assumed that c,+ 1 ~< c,. Then ][c - c , + l [ [ = [ ] c , l [ - ] [ c

+1[I < 2 - " "

Hence c, converges to a limit c such that a ~< c, b ~< c, and II c II -- ~ Next suppose that c ' e ~ ' , c' ~>a, and c' ~>b. By the Riesz interpolation property there exists c " ~ such that a ~< c" ~< c, b ~< c" ~< c'. Then

~= Itcll = IIc"ll + IIc- c"ll >~ + IIc- c"lt. Hence c = c" ~< c'. Thus c = a v b.

[]

16. HALF-NORMS

The asymmetric nature of the positive cone is reflected in m a n y properties of ordered Banach spaces. It is therefore useful to have an a s y m m e t r i c version of the norm. The a p p r o p r i a t e notion a p p e a r s to be a half-norm. A half-norm on a Banach space ~ is a continuous sublinear functional p; ~ - - ~ ~. In particular sublinearity implies 0 = p(0) ~< p(a) + p( - a). T h e continuity m e a n s that there is a constant k such that p(a) <~k II a II for all a E ~ , and hence by sublinearity Ip(a)l ~ 0 for all a~ ~.~\{0}. One can then associate with each proper half-norm p a n o r m IIlr~ on ,~ by the definition

I1~ = p(a) v p( - a), follows that IIa I1~ ~< k 41a II.

IIa

and it One can also associate with each (proper) half-norm p a (proper) closed convex cone

,~+ =

{a" a ~ ; ~ , p( - a) <<- 0}.

One then has la; a e M , p( - a) < 0} ~ int ~P.. by continuity of p, and the definition of ~P+.

POSITIVE O N E - P A R A M E T E R S E M I G R O U P S O N O R D E R E D B A N A C H SPACES

243

Conversely if (~, ~ + , IIll) is an ordered Banach space with a (proper) positive cone ~ + there is a (proper) canonical half-norm N on ~ given by S(a) = inf( 1[b I1; b e ~ , b >1a}.

One has 0 ~
}.

Hence N measures the distance of - a from ~ + . Since the dual space (~ , ~ + , ][. l[*) is an ordered Banach space, one can also define a canonical half-norm associated with ~*. This wilt be denoted by N*. Explicitly one has [

N*(~o)= inf{ [[r

,

;r162

~>o}

and it follows from weak*-compactness that the infimum is attained. The half-norms N and N* may be described by dual relations. For this one needs the following. LEMMA 1.6.1. Let o) be a linear functional on an ordered Banach space (.4~, ~ + , ]1"]1) and cte ff~+. The following conditions are equivalent:

1. o ~ . ~ * c ~ * , 2. o(a) <-%otN(a),

a~.

The proof is an elementary consequence of the definition of N and its properties mentioned above. PROPOSITION 1.6.2. The canonical half-norms N and N* satisfy N(a) = sup{to(a); t.o~*+ ~ } , N * ( o ) = sup { ~ a ) ; a e ~ + c~ ~ }. Proof The first statement follows from the Hahn-Banach theorem and Lemma

1.6.1. The second statement is obtained by setting 2 -- 0, p = 1, in Lemma 1.1.5 and rearranging (see the proof of Theorem l.J.a). [] Monotonicity of the norm is easily characterized by the canonical half-norms. The following result may be regarded as an extension of Theorem 1.2.3. T H E O R E M 1.6.3. The following conditions are equivalent: 1. [].]] is monotone on ~ , 2. N(a) = IIa II, a 6 ~ +, 3. N*(og) = inf{ H~ ]]*; ~ t>0, ~ i> o}, t ~ e ~ , 4. For each ~ * there exist ~, q e . ~ * with ~ = ~ - q and [[~ [[* = U*(~).

244

CHARLES J. K, BATTY AND DEREK W. ROBINSON

Moreover the followin 9 conditions are equivalent: 1". [1"1[*is monotone on ~ * ,

2". N*(~o)= I1,o11", 3*. N(a) = inf{ [Ib II; b/> 0, b/> a}, a 6 ~ , 4". For each a 6 ~ and ~ > 1 there exist b, c e ~ + with a = b - c and tJb II <~~N(a). Proof 1 o 2 . This follows immediately from the definitions. 1 =~ 3. This is a consequence of the definition of N* and Theorem 1.2.2. 3 =~ 4. This follows from weak*-compactness. 4 =~ 1. Since N*(og)~< II I1" the cone ~ * is dominating and the norm on ~ is monotone, by Theorem 1.2.2. The equivalence of the last four conditions is deduced in a similar fashion. [] The norm If'llN associated with the canonical half-norm is called the order-norm on ~. It can be re-expressed as IlallN-- N ( a ) v N ( - a ) =

inf{ lib [I v [Ic[I;c ~
and in this latter form it occurred already in Proposition 1.2.1. In particular the cone ~ + is l v-normal with respect to IIH . It also follows from Proposition 1.2.1 and the definition of %-normality that II'll~ and 11"11coincide if, and only if, ~ + is i vnormal with respect to II'H,in which case [1"11is said to be an order-norm. Alternatively II If~ and/l'[I are equivalent if, and only if, ~ + is normal. EXAMPLE 1.6.4 (Banach lattices). If ~ is a Banach lattice then N ( a ) = IIa+ II where a+ is the positive component in the canonical decomposition ofa. This follows because b >t a implies [b[/> a + and hence [Ib I[ ~> [1a + l["Alternatively it follows from monotonicity of the dual norm and Condition 3* of Theorem 1.6.3. [] EXAMPLE 1.6.5 (C*-algebras). Let ~ be the self-adjoint part ofa C*-algebra ordered by the positive elements. Each a e ~ has a canonical decomposition into positive and negative components a = a+ - a _ where a_+ = tlal-+ a)/2 and lal is the algebraic modulus of a. Again N ( a ) = IIa§ I1" Moreover the C*-norm satisfies 11a II = Ifa+ II v v I1a_ I] and hence it is an order-norm. [7] EXAMPLE 1.6.6 (Affine functions). Consider the space M = A(K) of affir, e fi)',ctions of Example 1.1.8. Then N(a) = sup {a(k) v 0; k e K } . The norm is an order-no m. [] EXAMPLE 1.6.7 (Two-dimensional spaces). If ~ = •2 and ~ + = ~2 tl;e norm is an order-norm if, and only if, the left derivative of the unit sphere is everywhere negative, e.g., [[(al,a2)ll--[all v 1a21. [] To conclude let us consider spaces with order-units and bases. First, if int M+ 4: 0, or if int ~'* 4: 0, there are natural generalizatic, ns ~,:' N, and N*, given by N-(a) = sup {~o(a); t o ~ * ,

Hm [[* = 1},

/V*(~o) = sup {o,'(a); a e , ~ + , IIa II = 1}.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

245

Thus it follows from Proposition 1.6.2 that N(a) = ~r(a) v O. But if a~int._~+ then a - ebeint ~ + for all be.~ 1, and a sufficiently s m a l l s 0, Therefore N( - a) ~< - e, i.e., N is strictly negative on int ~ + . Combining this result with the discussion at the beginning of the section one has int ~ + = {a; N ( -

a) < 0 } .

In fact N ' ( - a ) is minus the distance of a from ~ + \ i n t ~ + , whenever a e i n t ~'+. Similar observations are valid for N* and N*. Second, suppose ~ + is proper and ueint ,~+. There are two natural proper halfnorms associated with u:

N(a) = inf{).; ; t ~ + , a ~<),u}, -N.(a) = inf{2; 2 e ~ , a ~< 2u} and the associated norms coincide with the order-unit norm introduced in Section

1.4., i.e.,

IIa II. =

Nu(a) v N ( - a)

=/V,(a) v / V ( - a) -- inf{). > O; a e [ - 2u, 2u] }. Again N ( a ) = iVy(a) if either expression is strictly positive, but IV takes negative values a n d ' int ~ + = {a; N.( - a) < 0}. Both N and N have dual representations:

N,,(a) = sup{co(a); c o e ~ * , co(u) ~< 1}, ~r(a) = sup{co(a); c o e ~ * , co(u) = 1}. Moreover if { ~, ~ 4, t1'tl } is an order-unit space with t1 -- II II then N. = N, the canonical half-norm, and . ~ = N. This follows, for example, because

N(a) = inf{2; ).ER r , a ~<2b for some b ~

1}

and b ~ 1 is equivalent to b E [ - u, u]. Third, if~'+ is generating and has a base K there is a positive half-norm N x defined by

Nr(a ) = inf{2; 2 ~ R + , a ~<2b for some b~K}. Moreover, if 2 K is the corresponding order-unit of ~*, so that 2r(a) = 1 for a e K (see Proposition 1.4.2), one has

Nr(a) = sup{co(a); 0 ~
246

CHARLES J. K. BATTY AND DEREK W. ROBINSON

IIa

= inf{2; 2e R+, dE2 co(K u - K)}

= Nx(a ) + N~( - a) between the base-norm IIIIK associated with K (see Section 1.4) and the half-norm N x. Finally i f ~ has an order-unit u and K = {co; coe~'*+, co(u) = 1} the corresponding base of N * then NK(co) = sup{co(a); 0 ~< a ~< u}.

1.7, B O U N D E D OPERATORS

Let (~r d + , ll'H) and (~, ~ + , I1 II) be ordered Banach spaces, L# = ~(~r ~ ) the Banach space of bounded linear operators S; ~r ~ ' equipped with the operator norm

II'N,and ~+ = {S;SeL:,S-~r

c_~+}.

Since ~ + is a closed convex cone (2#, ~ +, I1 II)is an ordered Banach space. Operators Se L#+ will be referred to as positive operators. If .~r is weakly generating and ~ + is proper, then ~ + is proper. However s can be shown to be (weakly) generating only under very special circumstances (see, for example, [61, 78]). Indeed ifS 1, S2eL~' + and a t ~< a ~ a 2, then S t a t -

S 2a 2 ~<(S 1

-

S 2)a

~< S t a 2 -

S 2a t .

Thus the difference S = S 1 - S 2 of two positive operators is order-bounded, it maps order-intervals [a t , a : ] into order intervals. But there are many examples of bounded operators which are not order-bounded, even under fairly stringent conditions on .~r and ~ . One weak result in this direction is the following. P R O P O S I T I O N 1.7.1. If d + is normal and int ~ + :P 0 then every S r 1 6 2 order bounded, Proof. Using the notation of Proposition 1.4.3 one has

~ ) is

S(o(,~) ) ~_ S(b(.~') ) c_ btU#) ~_ o(~). Thus S is order-bounded.

[]

In particular the bounded operators on an order-unit space are order-bounded. Converse results can be obtained under rather more general conditions. P R O P O S I T I O N 1.7.2. If ~r is generating and ,~+ is normal then every orderbounded linear operator S; .~/ ~--->~ is bounded. Proof. If S is not bounded, there exist a.E~r 1 with IISa, it ~>4". Since sO+ is a vgenerating for some a, one has a. = a', -a': with a',, a~eM+ c ~ d . Replacing a, by - a. if necessary it may be assumed that IISa; II > 22"-'- Let a = X 2 - " a ; . If S is order-bounded S maps [0, a] into an interval [ b t , b 2 ] so that b t <~2-"Sa'<,Nb 2 for all n. But this contradicts normality o f ~ § []

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

247

In particular, by choosing ~ = R, one deduces that every order-bounded linear functional over ~r is bounded when ~t + is generating. Thus positive linear functionals over ~r are bounded. Next we discuss properties of the ordered space (Lr Ae+, I1 IJ). Throughout we assume ~r ~ ~ , ~ + ~ {0}. T H E O R E M 1.7.3. The cone ~ + is normal if, and only if, d + is generating and ~ + is normal. Proof Suppose ~ + is c%-normal. For o9e.at* and b e ~ let co| be the rank-one operator with action (09 | b)a = o9(a)b. If o9r

and b I ~
I ~
~-
2 and hence

II091]*1fbl1 = 11o9|

< ~(llo9|

II v 1109|

~110911*(11bl II v lib2 II),

i.e., ~ + is uv-normal. But if b e ~ + and 091 ~<09 ~< 092 in ~r ~< 092 | b and a similar calculation gives

then 091 |

~
~<

110911*11811 ~< ~llblltl109, II+ v 11092I1"). Thus .at* is av-normal and ~r is approximately a+-generating, by Theorem 1.1.4. Conversely suppose ~r is ct+-generating and ~ + is fly-normal. Consider S 1 ~<S ~< ~<S2 in ~ and ae.at. T h e n a = a 1 - a 2 where al, a2E~r and Ila, II + IIa2 11~ l l a l l . Now S~a i <~Saj <~ S2a j so

IISajll ~ fit IIs, a ill v IIs ~ j Iti ~lla~ll(llsl II v 115211), and consequently

IISa II -< IISa, II + IISa2 I[ ~<~/~llall(lls, II v IIs, II). Thus ~ + is (~fl)~-normal.

[]

If, for example, one chooses .at = ~, then the theorem states that the cone Z~a+(~) of positive bounded linear operators is normal, if and only if, ~ + is normal and generating. There is also a simple criterion for absolute monotonicity of the operator norm. T H E O R E M 1.7.4. The operator norm on L~' is absolutely monotone if, and only if, z~g+ is approximately absolutely dominating and the norm on ~ is absolutely monotone. Proof The proof of necessity is almost identical to the proof in Theorem 1.7.3 except that one now uses o92 = - o91, b2 = - bt and Theorem 1.3.1 replaces Theorem 1.1.4. Conversely suppose that ~r is approximately absolutely dominating and the

248

CHARLES J. K. BATTY AND DEREK W. ROBINSON

norm on ~ is absolutely monotone. Consider S, TEcta with _+ S ~< T. For a e ~ r and 0t > 1 there exist a 1 , a z e.~r + with a = a I - a 2 and IIa, + as II ~< 9 II a II" Therefore -- Ta I -- Ta 2 ~ Sa I -

S a 2 <~ T a 1 + T a 2 .

Hence ]]Sa ]] ~< ]] T(a, + az)Jl ~ 1. Thus the operator n o r m is absolutely monotone. [] C O R O L L A R Y 1.7.5. The operator norm on ~ ( ~ , ~ ) is absolutely monotone if, and only if, the norm on ~ is a Riesz norm. This follows by setting M = ~ in Theorem 1.7.4 and using the definition of a Riesz norm. The situation concerning monotonicity of the operator norm is not so clear. P R O P O S I T I O N 1.7.6. I f the operator norm on ~ ( ~ , ~ ) is monotone then .~ + is approximately dominating and the norm on ~ is monotone. Proof. The p r o o f is almost identical to the first part of the p r o o f of T h e o r e m 1.7.3 except that now to I = 0, b~ = 0, and T h e o r e m 1.2.2 replaces T h e o r e m 1.1.4.

[]

In particular if the operator norm on L~'(~, ~ ) is monotone, then both the norm IIll on and the dual norm IIll* on are m o n o t o n e But the converse, and hence the converse of Proposition 1.7.6, is false. E X A M P L E 1.7.7. Let ~ = R 2, ~ + = It~+, and

II(a,,a

)ll

= la, I v la21 v la, -

aa/2[.

Then ~'+ is dominating and the norm is monotone. Define S, and T, in ~ ( ~ , ~ ) by S(a,, a 2 ) = (a 2 , a, ), and T ( a , , a s ) = (a 2 , a, + a j 6 ) . Then 0 ~< S ~< T, [fS II = s/4, and II Tll = 7/6, so the operator norm is not monotone. M o r e generally if the norm on ~ is m o n o t o n e and the unit sphere in the first quadrant is symmetric about the line a 1 = a 2 then the operator n o r m is m o n o t o n e if, and only if, the unit sphere in the second quadrant is symmetric about the line a I = --a2.

[]

Monotonicity of the operator norm is related to a seemingly different property, positive attainment. T o introduce this concept it is convenient to define [[S[[ + = sup{ liSa H; a~.~tl c ~ r

}.

If at+ is weakly generating then [1"1[+ defines a norm on ~ ( ~ r ~ ) w i t h [[S [[+ ~ Us [[. Moreover if .~r is ~+-generating, then [[S I[ ~< ~ [[S 1[+ and the two norms [[. [[, [[" ][ +, are equivalent. If [[S [] + = [[S [[ for all S e s +, the operator norm will be said to be positively attained. PROPOSITION

1.7.8. I f either o f the following conditions is satisfied, 1. ~ + is approximately dominating and ~ + is 1 v-normal,

POSITIVE

ONE-PARAMETER

SEMIGROUPS

ON

ORDERED

BANACH

SPACES

249

2. d + is approximately absolutely dominating and the norm on ~ is absolutely monotone, then the operator norm on ff(..qr ~ ) is positively attained. Conversely, if the operator norm is positively attained, then ~ + is approximately dominating. Proof. We prove statement 1. The proof of statement 2 is identical except that a t = a 2.

Take S e ~ + , ac.~t, and at> 1. There exist a l , a 2 e . ~ + with - a 2 ~
IIsa II ~< IISa, 11 v IISa2 l[ ~
II--I[o~| + -- g*(~)ll b II by Proposition 1.6.2. So li e~ I1"= g*(,o) for all r162

and b e ~ +

IIo~11" IIb II- IIo,|

and ,~r

dominating by Theorems 1.2.2 and 1.6.3.

is approximately []

If the operator norm is absolutely monotone, then it is positively attained by Theorem 1.7.4 and Proposition 1.7.8. Conversely if the operator norm is positively attained, and the norm on ~ is monotone, then 0 ~<S ~< T implies ]1S l] = IIS ]1+ ~< Jt Ttl + -- rl T II so the operator norm is monotone. Moreover i f ~ = it~,then Z,e = ~r and the operator norm is positively attained if, and only if, it is monotone, by Theorem 1.2.3. It seems reasonable to expect that if the operator norm is monotone then it is positively attained. But this has only been established in two special cases, T H E O R E M 1.7.9. Suppose that the operator norm on L,e(~r either

i n t ~ + ~13

or

.;4 + has a base.

is monotone and

It follows that the operator norm is positively attained. Proof. The proofs of the two statements are very similar and are based on three lemmas which are wholly or partly independent of the assumptions of the theorem. LEMMA 1.7.10. Let SeZ#+,ae.~r Then

and let N be the canonical half-norm on ~r

N(a)( ti S IJ + IIs ti § )/> ti Sa It - ti s li + il a II Proof. If a ~
IJSa Jl ~< IISa' II + JIS(a" - a)tl

~
+ Ilsl[ §

But N(a) = inf{ Ila'll;a' >~a }.

+ Ilsil + I[o[I. []

25O

CHARLES J. K. BATTY AND DEREK W. ROBINSON

L E M M A 1.7.11. Suppose that .xr + is a p p r o x i m a t e l y dominating and the norm on :~ is monotone. I f SeoLP +, then IIS[I+=IIS*II+. Proof. First note that the n o r m on .~r is m o n o t o n e by T h e o r e m 1.2.2. N o w

Ilsll + = sup { ll aa [l ; a r , ~ l ,~ , ~ + }

= sup {~,(Sa); a r ~

~ d§

~o6~* ~ :~_ )

= sup { (s*~o)(a); a6~r ~.~r247o~6~* ~ ~ * } = sup{ I/s*~ll* ;~o6~* ~ *

) = IIs*ll+

where the second and fourth equalities use T h e o r e m 1.2.3.

[]

L E M M A 1.7.12. Suppose that the operator norm is monotone, S r L P + , IIs)l = l, and II s II + = 1 - 2r where r > O. T h e n f o r e > 0 and 0 < erz(1 - r) - 2 there exist o 9 6 . ~ * and b e :~ + such that II,o II * IIb II <~ and IIS + ,1, | b II > 1 + 0. Proof. For 0 < r ' < r there exists a 6 ~ r 1 with II Sa II > 1 - r'. Therefore N(a) >>> / ( 6 - r ' / 2 ) ( 1 - r ) - 1 , by L e m m a 1.7.10. Hence there exists an t o r ~ * c ~ M * with ~o(a) t> (r - 6')(1 - r ) - 1, by Proposition 1.6.2.

Next there exists an r/e:~* with q ( S a ) - - I l S a l l > l - r ' so I I s * ~ l l * > l - r ' . Therefore, applying a similar argument to S* and 7, instead of S and a, one deduces that there exists a b 6 : ~ c~ ~ + with r/(b)/> e(6 - r')(1 - r ) - 1. N o w IIs + o g |

II ~> r/((s + o | > 1 - r' + o(a)q(b)

> 1 -- r ' + e ( r - r')2(1 if r ' is sufficiently small.

--6)-2>

1 +0, []

N o w we retuln to the p r o o f of T h e o r e m 1.7.9. First assume int ~ + r 0 and let u r i n t ~r with II u II = 1. Therefore there is a fl > 0 such that b ~< u for all b e ~ p . N o w suppose the operator n o r m is not positively attained. Thus there exists an S r L ,e+ with IISII = 1 and IIsll+ = 1 - 2 r < 1. Then by L e m m a 1.7.12 there exist 0 > 0 , ~oe~r c~r and b e ~ + n ~ a r , with IIs+~o| = 1 + 0 . M o r e o v e r 0 ~< <~ b <~ ru. N o w let S 1 = S + &o | so

1151 II >/IIs + o~|

IIs, I1+ 411511+ + r =

= 1 + 0,

l-r.

Next choose

a 6 , ~ r 1 such that IISlall > 1 + 0 - r ' where 0 < r' < r. R e p l a c i n g a by a, if necessary, one m a y assume og(a) i> 0. N o w there exists r/e:~* such that r/(S 1 a) > > 1 + 0 - r ' and hence -

rio(a) >1 ro(a)rl(u ) = = rl((S l - S)a) > 0 - r'.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

251

But applying L e m m a 1.7.10 to S* and Proposition 1.7.6 and L e m m a 1.7.11 to S 1 one has N*( - ~/) i> (8 + 0 - 5')(2 + 0 - 5 ' ) - 1 > (8 - 8')/2. By Proposition

1.6.2 there exists b ' e ~ + c ~ e with ~ / ( b ' ) < - f l ( 5 - 8 ' ) / 2 .

IIs2 II >1~(S2a)

Let

- b') so O `< S <<.S 2 `< S 1. But

$2 = S 1 - 8 0 9 | b' = S + 5 0 9 |

= ~(sl a) - 809(a)rl(b') > 1 + o - 8' + (o - 8')fl(8 - 8 ' ) / 2

> l + O = l l s , ll for 5' sufficiently small. This contradicts the m o n o t o n i c i t y of the operator n o r m and hence proves the first statement of the theorem. N o w suppose ar + has a base. Therefore ar has an interior point p with [IP I[ * = 1, by Proposition 1.4.3. Hence there is a fl > 0 such that 09 `< p for all 09e,~/~. Again suppose the o p e r a t o r n o r m is not positively attained, and hence there is an ScaLa+ with [[SI[ = l a n d [[StI+ = 1 - 2 8 < 1. There also exist 0 > 0 , 0 9 e ~ * c~.~1~, and be~+n~ 1, with 1 1 S + 0 9 | Then 0--.<09--.<5p. Let S l = S + S p | so 11511t> 1+0, and 118111§ . < 1 - 8 . Next choose a e a r 1 such that I[S, all> > 1 + 0 - 8' where 0 < 8' < 8. There exists an r / e ~ * such that rl(Sla ) > 1 + 0 - 8', and we m a y assume that ~/(b) i> 0. N o w 8tl(b) >1 5p(a)~l(b) = ,l((s,

-

S)a) > 0 -

8'.

But applying L e m m a 1.7.10 to S 1 one obtains N( - a) > (8 - 8')/2. By Proposition 1.6.2 there exists 09'eag* n a r with 09'(a) < - fl(5 - 8')/2. Let S 2 = S 1 - 509' | = = S + 5(p - 09') | b so 0 `< S `< S 2 `< S 1 . But tl $2 II ~> r/(S2 a) = rl(S, a) - 809'(a)tl(b) > 1 + 0 - 6' + 3(5 - 5')(0 - 8')/2

> tl s, It, if 5' is sufficiently small. Again this contradicts the m o n o t o n i c i t y of the operator n o r m and hence proves the second statement of T h e o r e m 1.7.9. []

2.

Positive

Semigroups

2.0. I N T R O D U C T I O N

In this part we review the basic theory of positive one-parameter semigroups, i.e., semigroups of b o u n d e d linear operators which act on an ordered Banach space and respect the order. The first objective is an infinitesimal characterization of such

252

CHARLES J. K. BATTY AND DEREK W. ROBINSON

semigroups in terms of generators. Subsequently we discuss stricter notions of positivity, irreducibility criteria, and spectral properties. ~ft~, II. I[) is a Banach space then a family S = {S,},.>0 of bounded linear operators on M is defined to be a Co-semiorou p if it satisfies

1. SsS,=Ss+ ,,

s,t >~O,

2. S o = I , 3. lim [IS,a - a l l = o ,

a~.

Moreover if ~ is ordered by the positive cone :~+ then S is defined to be positive if it also has the property 4. S ~ + _ c ~ + ,

t>0.

Similarly if (.~*, II'll *) is a dual Banach space then a family T = { Tt },.>o of bounded linear operators on ~ * is defined to be a C~-semigroup if it satisfies properties 1 and 2 above together with the weak*-continuity conditions 3*. a. t >>.O~(T, co)(a) is continuous for all coe~* and a e ~ , b. ~e~*,-*(T~co)(a) is weak*-continuous for all t/> 0 and a e ~ . Again if :~* is ordered by the cone :~* then T is defined to be positive if one also has the property 4*. Tt:~*~@*+,

t>0.

These two types of semigroup are related by duality. If S = { S , } , . > o is a Co-semigroup on @ then the adjoint operators, S* = {S,*},~o on :~*, form a C*-semigroup. Conversely if T = { Tt }t>.o is a C~-semigroup on :~* then there exists a Co-semigroup T* = {T*}t>.o on ~ which is adjoint to T, i.e., (T,*)* = 7", for all t > 0. This duality also extends to the generators of the semigroups. The generator of a Co-semigrou p S on @ is defined as the linear operator H whose domain D(H) consists of those a~:~ for which there exists a b ~ such that lim H(I - S t ) a / t - b H = o t~O+

and the action of H is then defined by Ha = b. The generator of a C~-semigroup is defined similarly but with a weak*-derivative. Explicitly the generator K of the C~-semigroup T on 8 " has a domain D(K) consisting of those coe~* for which there is an ~ / ~ * such that lim ( ( I - Tt)t~)(a)/t = q(a) t~O+

for all a 6 ~ and then Kco = ~/. For example, if S is a Co-semigroup with generator H then the C~-semigroup S* has generator H*. The basic structural theorems of semigroup theory characterize those operators

POSITIVE ONE-PARAMETERSEMIGROUPS ON ORDERED BANACH SPACES

253

which generate C o- and Co-semigroups. The following statement incorporates both versions. Note that R(X) denotes the range of X. THE F E L L E R - M I Y A D E R A - P H I L L I P S THEOREM. Let '~ be a Banach space (with a predual ~ ,). The followin 9 conditions are equivalent: 1. (1"). H 9enerates a C o- (C~-) semiorou p, 2. (2*). H is a norm- (weak*-) densely defined norm- (weak*-) closed linear operator with R(I + fill) =

and

II
a II

(l -

r a II/M

for all 0 < ~ <~8, a~D(H") and n >~ 1, for some M >>-1, 7e~, fl > O, with ~ < 1. Moreover if these conditions are satisfied I[S, I[ ~< M exp {Tt}. The simpler and earlier version of this theorem for contraction semigroups, i.e., semigroups with IIs, II ~< 1 is as follows: THE H I L L E - Y O S I D A THEOREM. Let ~ be a Banach space (with a predual ~ , ). The followin9 conditions are equivalent: 1. (1"). H generates a C o- (C~-} contraction semigroup, (2*). H is a norm- (weak*-) densely defined norm- (weak*-) closed linear operator with R(I + fill) = ,~

and

II(#+ n)all

llall

for all 0 < ~ <~ ~ and all ae D(H),for some ~ > O.

In both these theorems the criterion for a generator ensures that R(I + ~H) = for all small ~ > 0 and the resolvents (I-I-~H)-i exist with suitable bounds, e.g.,

in the Feller-Miyadera-Phillips theorem II(I + ~H)-" I[ ~<M(1 - aT)-". Moreover, in all cases the semigroup S is constructible from the resolvents by a limit St = lira (I + tH/n)-" n~oo

in the strong, or pointwise weak*, topology. In Sections 2.2 and 2.3 we derive various versions of these theorems for positive semigroups on suitable ordered Banach spaces, e.g., spaces with a Riesz norm or spaces with ant ~ + 4=0. In all these variants inequalities of the type II(I + ~H)a I[ ~> I[a H

254

CHARLES J. K. BATTY AND DEREK W. ROBINSON

are replaced by analogous inequalities with respect to a half-norm. As a preliminary we examine these bounds in Section 2.1.

2.1. DISSIPATIVE O P E R A T O R S

Throughout this section H denotes a norm-densely defined linear operator on a real Banach space ~ with domain D(H). We are principally interested in operators which satisfy a dissipativity condition with respect to a half-norm p. There are a variety of equivalent definitions of this dissipativity, some expressed in terms of the sub-differentials of p, i.e., the sets of tangent functionals to p. The subdifferential dp(a) of the half-norm p at the point a e ~ is defined by dp(a) = {o; toeM*, to ~
(*)

for all t > 0. In fact since t~--~p(a + tb) is convex one need only consider this relation in the limit t --, 0 + . Although dp(a) may contain more than one functional it cannot be large except for a 'few' elements a e ~ ' . Indeed Mazur's theorem [41] shows that if ~ is separable then there is a norm-dense set of a e ~ at which dp(a) consists of a single functional. This fact makes the equivalence of Conditions 2 and 3 in the following theorem a little less surprising. T H E O R E M 2.1.1. Let H; D(H)~--,~ be a norm densely-defined linear operator on the real Banach space ~ and p a half-norm on ~ . The following conditions are equivalent: 1.

p((l + otn)a) >i p(a) for all (small) ~ > O, and all aeD(H),

2.

to(Ha) >10 for some toedp(a), and for all aeD(H),

3.

to(Ha) >10

for all toedp(a), and for all aeD(H). Proof. 1 r This equivalence follows from the above relation (*) with the choice b = Ha. 3 ~ 2. This is obvious. 1 ~ 3. For a, b e D(H) and t > 0

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

255

p(a - tHa) ~ p(a - tb) + tp(b - Ha)

~
Hence lim (p(a) - p(a - t H a ) ) / t ~ - p ( H a - b) - p(b - Ha). t~O§

Since D(H) is norm-dense and p is continuous the right-hand side may be made arbitrarily small. Therefore |im (p(a) - p(a - t H a ) ) / t >~O. t~O+

Now Condition 3 follows from (*), with b = Ha.

[]

A norm-densely defined linear operator H on the real Banach space ~ is defined to be p-dissipative if the equivalent conditions of Theorem 2.1.1 are satisfied. The term dissipative arises in the context of Co-contraction semigroups; dissipativity is an infinitesimal form of contractivity, Let S be a C0-semigrou p with generator H and assume that S is p-contractive in the sense p(S, a) <~p(a)

for all t/> 0 and a~M. Then if oJedp(a) one has og(Stb) <~p(Stb) <~ p(b)

for all b e ~ ' and ~o(S,a) ~10. t~0+

i.e., H is p-dissipative. Conversely ifH is p-dissipative, then by Condition I of Theorem 2.1.1, and the algorithm for S given in the introduction, p(S,a) = lim p ( ( l + t H / n ) - ~ a ) p(a)

for all a e ~ , i.e., S is p-contractive. In particular a Co-semigrou p is a contraction semigroup if, and only if, its generator is norm-dissipative. This is in fact part of the statement of the Hille-Yosida theorem because norm-dissipativity corresponds to the bounds

It
IIa II

256

CHARLES J. K. BATTY AND DEREK W. ROBINSON

for all a e D ( H ) and all small 9 > 0. Norm-dissipative operators are usually referred to simply as dissipative operators. Another special example of dissipativity is for the canonical half-norm N on a Banach lattice ~ . Then N(a) = IIa+ II by Example 1.6.4 and co ~< N is equivalent to o ) e ~ * n ~ * by Lemma 1.6.1. Therefore dN(a) = {r 096~*+ n ~ ' ,

~o(a)= Ila+ II}"

Thus H is N-dissipative if, and only if, for each a ~ D ( H ) there exists an o 9 ~ * n ~ with co(a)= IIa+ I[ and o ( H a ) >i O. Such operators were called dispersive by Phillips [62]. It is an interesting question whether dispersive operators H on a Banach lattice are automatically dissipative. More generally it is of interest whether N-dissipative operators on a space with a Riesz norm are automatically dissipative. A short argument shows that this is the case if I + c~H has a norm-dense range for all small ~ > 0, but in this case much more can be said as will be seen in the next section. Furthermore, if ~ has the property that N( _+ a) ~
p((l + ~H)a)/>(1 - ~F)p(a)

for all 9 > O, with 1 - ~y > O, and all a e D ( H ) . Proof. The proof is an immediate consequence of the identity p((l + c~H)a) = (1 - ~y)p((l + ~(1 - ~?)- t(H + 7I))a)

which is valid for all ct such that 1 - ~t~ > 0, and all a e D ( H ) .

[]

The next result shows that p-dissipative operators are well-behaved. T H E O R E M 2.1.3. Let H be a p-dissipative operator, where p is a proper half-norm on ~ . Then H is norm-closable and its closure I4 is p-dissipative, Proof. Suppose that a e D ( H ) , tla ll--)0, I[ H a , - b l l - - , 0 and b ' e D ( H ) . For t > 0 p(a, - tb) <<,p(a, - tb') + tp(b' - b) <<-p((l + t H ) ( a , - tb')) + tp(b' - b) <<.p(a,) + tp(b - b'} + tp(b" - b) + tp(Ha, - b) + t2p( - Hb').

It now follows from the continuity ofp that in the limit n --* zc tp( -- b) <~ tp(b - b') + tp(b' - b) + t2p( - Hb').

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

257

Dividing by t and taking the limit t ~ 0 then gives p( - b) <~p(b - b') + p(b' - b). But since D(H) is norm-dense and p is continuous the right-hand side may be made arbitrarily small by suitable choice of b'. Therefore p( - b) = 0 and similarly p(b) = O. Since p is proper it follows that b = 0 and H is closable. The final statement of the theorem follows from Condition 1 of Theorem 2.1.1. [] Theorem 2.1.3 has one simple but practical implication for norm-closed operators. It is only necessary to verify the p-dissipativity conditions on a core of the operator H. This simplifies, for example, the discussion of partial differential operators for which one can usually choose a core of smooth functions. There is a stronger version of Theorem 2.1.3. Suppose there exist 2 e ~ and e > 0 such that for each a e D ( H ) with p(a) = 1 there is some toedp(a) with Ito(Ha) - 21 > e,. Then H is norm-closable. A proof of this fact, in the case p(.) = ]Ill, may be found in [7 3 . We conclude this general discussion with some observations on order-unit spaces. Let (M,'~+, II'l[) be an ordered Banach space for which ~ + is proper and int M+ 4:13. Let H be a norm-densely defined linear operator on ~'. Hence there must exist a ueD(H) ~ int M+. Let N and ]V be the associated half-norms introduced in Section 1.6. Thus N~(a)= i n f { 2 ; 2 e ~ + , a ~<2u}, N,(a) = inf{2; 2 e R , a <~2u}. P R O P O S I T I O N 2.1.4. For each ueD(H)c~intM+ the followin 9 conditions are equivalent: 1. if aeD(H) and (I + ~ H ) a e M + then a e M + ,for all small ~ > O, 2. H + 7I is Nu-dissipative for some (or for all) ? >>-IV( - Hu), 3. if a e D ( H ) ~ M + , t o , M * , and to(a) = 0 then to(Ha) ~ O. Proof. 1 ~2.-Let ;~ t> N ( - Hu) then (I + ~H)u/>(1 - CtT)U.But N ((I + ctH)a) = inf{2;2 >>-0,(I + ~H)a <~2u} ~>inf{2; 2 ~>0,(I + ctH)a ~<2(I - ~7)- 1(I + ~H)u} l>inf{2;2/>0, a ~<2(1 - ct7)-~u} = (1 - ~7)N~ (a) and H + ?l is N,-dissipative by Proposition 2.1.2. 2 ~ 1. I f ( / + ~ H ) a e M + then O= N ( - (I + ctH)a) >i(1 - ~7)Nu(- a), by Proposition 2.1.2. Thus aeM+ provided 1 - ~, > 0. 2 ~ 3. It is easily checked that d N ( a ) = { o J ; t o e ~ * , to(u) ~< 1, to(a) = N (a)}.

258

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Hence if 69 ~ 0 satisfies the hypotheses of Condition 3, then m/co(u)~dN,(-a). Therefore co[(H + yl)( - a)) >i 0 by N -dissipativity and consequently co(Ha) <<,O. 3 ~ 2 . Let ,/>~N ( - H u ) , so H u > t - T u . If a e B and coedN(a)\{O} then b = = uN,(a)/~u) - a ~ + , coe~*+, and co(b) = 0. Hence

0 >>-co(Hb) >i - 7N,(a) - co(Ha) = - co((H + yI)a) Thus H + yl is Nu-dissipative.

[]

Condition 1 of Proposition 2.1.4 is a statement of positivity o f ( / + ~H)- 1, whenever this inverse operator exists, whilst Condition 3 states that H has 'negative off-diagonal elements'. For example if ~ = E", ~ + = E~_, and H = (H u) is an n x n-matrix, then Condition 3 is equivalent to H u ~<0 for i =~j. Hence we refer to Condition 3 as the

negative off-diaoonal property. Note that if N is the canonical half-norm and H is N-dissipative, then it has the negative off-diagonal property. This follows because dN(a) = {co; co6~* c ~ * , co(a) = N(a)} by Lemma 1.6.1. Hence if a e D(H) n ~ +, co9 :~* n ~ * , and co(a) = 0 then coe dN( - a) and co( - Ha) >/0. A similar conclusion is valid for /V-dissipative operators, where /q is the generalization of N given in Section 1.6. Of course these statements are empty if D(H) n :~ + = ~ but the assumption int ~ + 4= 0 is sufficient to ensure that D(H) contains positive elements. Next we consider N - and ~" -dissipative operators in more detail. Again [[.[[, denotes the order-unit norm associated with N , o r / ~ . COROLLARY 2.1.5. For each u ~ D ( H ) h i n t ~ + the followin# conditions are equivalent: 1. H is N,-dissipative,

2. H is [['[[-dissipative and has the negative off-diagonal property, 3. Hu >>-0 and H has the neoative off-diagonal property. Moreover the followin 9 are equivalent: 1. H is iV-dissipative, 2. H is H. ]l -dissipative and Hu <~O, 3. Hu = 0 and H has the negative off-diagonal property. Proof 1 r This is established in Proposition 2.1.4. 1 =~ 2. This follows from Proposition 2.1.4 and the fact that [Ia I[, = N ( a ) v N ( - a). 2 ~ 3 . If co6~*\{0} then co~co(u)is in the subdifferential of I["][, at u. Therefore if H is ]['[],-dissipative co(Hu) >- O. Hence Hu >10. The proof of the equivalence of i, 2, and 3 is similar. [] Note that in Corollary 2.1.5 the implication 1 ~ 2 does not depend upon the assumption that ueD(H). Similarly 2=:- 1 if ueR(l + otH), the range of I + ~tH, for all small ct > 0.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

259

E X A M P L E 2.1.6 (Matrices). Let ~ = ~ n , ~ + = 0~_, and H = ( H o ) a real n x n matrix. Ifu = (u,)eint ~ § then u i > 0 for i = 1, ..., n and Nu-dissipativity is equivalent to (Hu)i >i0 for i = 1. . . . . n and H,j ~<0 for i~j. A particularly interesting case is u = (1, 1.... ,1) and then N -dissipativity is equivalent to n

Hij ~ O, j # i,

Z Hij ~

and

0,

i = 1.... , n;

j=l

/q -dissipativity is equivalent to

Hij<<.O,j#i, and

~.Hii=0,

i = l .... ,n;

j=l

and I]'[]u-dissipativity is equivalent to n,-Yln,

l

>0,

i = 1 . . . . . n.

j§

Moreover in this case I1"11ocoincides with t h e / ~ - n o r m IIa = maxla,[. If, alternatively, ~ is equipped with the /l-norm I[all, = Xla, I, then it follows that I]'ll,dissipativity is equivalent to

Hi,- ~lnji[l>O,

i = l . . . . . n.

j~i

The corresponding/P-conditions, for 1 < p < oc, do not have any simple expression in terms of the matrix elements, but II'llp'dissipativity is implied by I['11-dissipativity together with I1' II -dissipativity. [] EXAMPLE 2.1.7 (Hilbert space). If M is a (real) Hilbert space, the subdifferential of the norm at each a e M with IIa II = 1 consists of the unique element a. Thus n is (norm-) dissipative if, and only if, H is positive definite, i.e.,

(a, Ha) >10, aeD(H). But this is equivalent to positivity of the spectrum of H. Thus in this special context dissipativity is a spectral condition. [] Many elliptic differential operators on a wide variety of function spaces satisfy dissipativity conditions. As a simple illustration we consider N-dissipativity of the Laplacian with classical boundary conditions on L2-spaces. E X A M P L E 2.1.8 (The Laplacian). Let ~ = L2(A; dVx) where A is a bounded open subset of ~v with a piecewise differentiable boundary OA and let ~'+ be the pointwise positive functions. Define H , by first specifying D(H~,) to consist of the functions f which are infinitely often differentiable in the interior of A and satisfy

?f /dn + af = 0 on c3A where

d/~n denotes the outward normal derivative and a e R, then specify the

260

CHARLES J. K. BATTY AND DEREK W. ROBINSON

action of H , by

~2f, , ~-/.2~x]= - (V2f)(x)

(H,,f)(x) = -

i= 10Xi

for f e D ( H , ) . Since ~ is a Banach lattice the canonical half-norm is given by N ( f ) = : IIf+ II where f + denotes the positive part of f , and d N ( f ) consists of the unique element 09 =f+/tl f+ II if f + 4: 0, and 0 e d N ( f ) i f f + = 0. Therefore ~

= - ( f + , V2f)/ll f + I[

for all f 6 D ( H o ) and all a / > 0. Thus H , is N-dissipative, and hence norm-dissipative, for all a / > O. [] Dissipativity of bounded operators on C*-algebras can be rephrased in an algebraic manner which is seemingly quite different to the original definition. Since discussion of this point is facilitated by the use of semigroup theory we postpone the details until the end of the next section.

2.2. C0-SEMIGROUPS In this section we examine versions of the Feller-Miyadera-Phillips theorem and the HiUe-Yosida theorem for positive Co-semigroups, and in the subsequent section we consider the analogous problem for C*-semigroups. Many of the results, and their proofs, are very similar in both cases, but there are substantial differences for semigroups on order-unit spaces. First, note that i f a 6 ~ + and a~ = e- 1

fo

d t Sta ,

then a e D ( H ) c~ ~ + . Moreover a~ --* a in norm as e -~ O. Therefore D(H) ~ ~ + is normdense in ~ + . Second, remark that (I + e l l ) - 1 =

foo

dt e-'S~,

and hence the resolvents (I + e l l ) - ~ are positive. Conversely, if the resolvents are positive, then the formulae

t Sta = ,lim ~o\ I + n H show that S is positive.

t -na

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

261

The next result is a version of the Feller-Miyadera-Phillips theorem in which the canonical half-norm partially replaces the norm. T H E O R E M 2.2.1. Let (~, ~ +, IIll) be an ordered Banach space for which the norm is monotone and the operator norm on .LP(~, ~ ) is positively attained. Furthermore let N be the canonical half-norm on ~, and M, [3, 7, real numbers with M >i 1, [3 > O, [37 < 1. The following conditions are equivalent: 1. H generates a positive Co-semigrou p S with

I/s, It <MeT' t>0, 2. H is a (norm-closed) norm-densely defined linear operator satisfying the range condition R(I + fiB) = ,~ and the dissipative conditions N((I + an)"a) >1(1 - aT)"N(a~/M for alta6D(H"),alln >t 1,andallO < a <<.[3. Proof 1 =:,2. First, the range condition R(1 + [3H)= ~ , the norm-density, and norm-closedness, follow from the Feller-Miyadera-Phillips theorem. Second, since S is positive N(Sta) = inf{ IIb II; b >I Sta } ~
IIS,c II; c/>

a}

~< M e et inf{ 1[c II;c >1a} = M e~tN(a). Thus by Laplace transformation, and sublinearity of N,

N((I + an)-"a) <~fO ~dt ~ t n- t

e-'N(S,,a)

<~M(1 - aT)-"N(a), and the dissipative conditions follow by rearrangement. 2 => 1. If (1 + [3H)a = 0, then

0 = N( + (I + [3H)a) >1(1 - [37)N( +_a)/M >10. Thus N( + a) = 0 and a = 0 because the norm is monotone on ~ and hence ~ + is proper. Therefore (I + fill) is invertible. Next i f a 6 ~ ' + , then

0 = IV( -- a) >~(I - flT)"N( -- (I + flH)-"a)/M and so (1 + [3H)-"ae~+, i.e., the operators (l + fill)-" are positive. Now since a 6 ~ + , and the norm is monotone on ~ + ,

I](l + [3H)-"a 1[= N((I + [3H)-"a) ~< M(1 - [37)-"N(o) = M(l - [37)-"11a ]],

262

CHARLES J. K. BATTY AND DEREK W. ROBINSON

by Theorem 1.6.3. But then 1[(I + fill)-" II "< MI1 - f l j - " , because the norm on ~a(M, M) is positively attained. Next a standard perturbation argument shows that R(I + ~H) = M, and the resolvents (I + ctH)-" exist, are positive, and satisfy

II(i +

-n II -< M(1 - ~7)-"

whenever ~ > 0 and 0 < ~ ~
IIs, II Me< by the Feller-Miyadera-Phillips theorem, and S is positive, because the resolvents (I + ~H)- 1 are positive. [] Note that neither of the assumptions on (M, M+, H' H) are used in the proof of 1 ~ 2 in the theorem. There is an immediate corollary for contraction semigroups, i.e., an analogue of the Hille-Yosida theorem. C O R O L L A R Y 2.2.2. Let (M, M+, I111) be an ordered Banach space for which the norm is monotone and the operator norm on ~(M, M) is positively attained. Then the following conditions are equivalent: 1. H generates a positive Co-semigrou p of contractions, 2. H is a (norm-closed) norm-densely defined, N-dissipative operator, and R(I + ~H) = M for some ~t > O. This result follows immediately from Theorem 2.2.1 with M = 1 and ~ = 0 when it is observed from Theorem 2.1.1 that N-dissipativity is equivalent to N((I + ctH)a) >>-N(a),

aeD(H),

and hence by iteration to N((I + ctH)"a) >1N(a),

aeD(H"), n >>-1.

In Theorem 2.2.1 and Corollary 2.2.2 the assumption of positive attainment is a somewhat implicit condition on M. One can, however, combine these results with Proposition 1.7.8 to obtain the following statement. COROLLARY 2.2.3~ If(M, M +, IIII)

is a n

ordered Banach space for which

either

lilt is

or

M+ is 1v-normal and approximately dominating,

a

Riesz norm,

then the two conditions of Theorem 2.2.1 (resp. Corollary 2.2.2) are equivalent. The first option of this corollary, the Riesz norm, covers Banach lattices, C*-

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

263

algebras, and their duals. The second option is equivalent to the norm on ~ being an order-norm and the dual-norm being monotone. Under weaker conditions on ,~ it is possible to obtain the following weaker version of Theorem 2.2.1. T H E O R E M 2.2.4. Let ( ~ , ~ + , IIl]) be an ordered Banach space for which ~+ is approximately dominating and IIlf is monotone. Furthermore, let N be the canonical half-norm on .~, and M, fl, 7, real numbers with M >>-1, fl > O, fly < 1. The following conditions are equivalent: 1. H generates a positive Co-semigrou p with llStll+ ~<MC',

t>0,

2. H is a norm-densely defined linear operator satisfying the range condition R(I + f i n ) = and the dissipative conditions N((I + ~H)na) >>-(1 - ~7)nN(a)/m for all ae D(Hn), all n >1 1, and all O < ~ <~ft. Proof. 1 ~ 2. Since ~ + is approximately dominating N(a) = inf{ I]b ll; b/> a, b >/0}, The proof is now identical to that given in Theorem 2.2.1. 2 ~ 1. Let II'lIN be the order-norm, ]1a IIN = N(a) v N(

- a).

Since ~ + is normal III1~ and till are equivalent. But

II(/§ ~n)"a I1~/> (1 - ~)" IIa II~/M. Therefore H generates a C0-semigrou p S with

IIS,a I1,, ~ M e~' IIa H,,, by the Feller-Miyadera Phillips theorem. Moreover S is positive, as in Theorem 2.2.1. But since ]l'[I is monotone/I o Ir~ = IIa II for all a t . ~ + by Theorem 1.6.3. Therefore

IdS,a II = IIS,a II~ -< M for a ~ + .

e ~' II a II~ = M e ~' II a

Thus [IS, II+ ~< M exp {Tt }.

II []

Theorems 2.2.1 and 2.2.4 are not independent. In view of Proposition 1.7.8, Theorem 2.2.1 follows from 2.2.4. Conversely Theorem 2.2.4 can be deduced by applying 2.2.1 to (~, ~'+, I[" I[~/Note also that in Theorem 2.2.4 the assumption of approximate domination is only used in the proof 1 ~ 2 and norm-monotonicity is only used in the proof of 2 ~ 1. Note also that if it is only assumed that ~ + is normal then, because II-IIN and

264

CHARLES J. K. BATTY AND DEREK W. ROBINSON

I111 are

equivalent, the above argument shows that Condition 2 of Theorem 2.2.4 implies that H generates a positive C0-semigrou p S for which IIs, I[ ~ M' exp {~t} for some M' >i M. Again there is an analogous result for contraction semigroups. COROLLARY 2.2.5. Let (~, ~ + , I111) be an ordered Banach space for which ~+ is approximately dominating and I1 II is monotone. Then the following conditions are equivalent: 1. H generates a positive Co-semigroup S satisfying

IIs, ll+ ~ 1, 2. H is a norm-densely defined, N-dissipative operator, and R(I + otH) = ~ for some ~>0. The following two-dimensional example shows the necessity of norm-monotonicity for the implication 2 ~ 1 and domination for 1 ~ 2. EXAMPLE 2.2.6. Let ~ = ~2, ~ + = ~2+, and H(a I , a2) = (a I , 0). Then exp{ - tH} is positive. Moreover, if II(a,, a 2) I1 = Ia, I v l a, - 2a 2 [, then N((a,, a2)) = a, v a 2 v 0 and H is N-dissipative with R(I + a l l ) = ~ . Nevertheless IIe-in It = II e-roll + = = 2 - e-'. In this case ~ + is dominating but IIII is not monotone. If II(a,,a2)ll = ta, I " lal + 2a21, then N((al,a2)) = a~ v a 2 v (a 1 + 2a2) v 0 and IIe - ' " II+ = 1 But H is not N-dissipative and IIe - ' " II = 2 - e-'. In this case I1 II is monotone but ~ + is not dominating. [] If ~ + is normal and has interior points the characterization of generators can be considerably simplified. The following result shows that in this setting H generates a positive Co-semigrou p if, and only if, the resolvents (! + ~H)- 1 exist as positive operators for all small g > 0. T H E O R E M 2.2.7. Let (~, ~ + , I111) be an ordered Banach space with ~+ normal and int ~ + =fi0. The following conditions are equivalent: 1. H generates a positive Co-semigroup, 2. H is a norm-densely defined linear operator satisfying the range condition R(I + f i B ) = and the positivity condition, aeD(H) and (I + ~ H ) a e ~ + imply a e ~ ' + , for all 0 < 9 <<,fl, for some fl > O. REMARK. Proposition 2.1.4 establishes that the positivity requirement of Condition 2 is equivalent to a dissipativity condition, or the negative off-diagonal property discussed in Section 2.1. Proof 1 ~ 2. If H generates a positive Co-semigrou p, then the resolvents (I + ~H)exist as positive bounded operators and so Condition 2 is satisfied. 2 ~ 1. Choose ueD(H)c~int ~+ then by Proposition 2.1.4 there is a V > 0 such

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

265

that H + 7I is N -dissipative. Thus Nu((I + otH)a) >1(1 -

~)N.(a)

for ot > O, ~t? < 1, and all aeD(H). Hence II(I + ~H)a II, I> (i - ct7) IIa lib, under the same restrictions, where

4111. denotes

the order-unit norm. By iteration

II(l + ~H)"all" t>(1 -atr)" IIa II" for ct > 0, at7 < 1, and all aeD(H"), n/> 1. It then follows from the Feller-MiyaderaPhillips theorem that H generates a Co-semigroup on (2, I111.1 satisfying IIs, II. exp{n}, t > 0. But I1"I1~is equivalent to II il, because 2 + is normal, and hence S is a Co-semigrou p on (2, I1"11) with IIs, II ~ M exp{rt} for some M/> 1. Finally, positivity of the semigroup follows from positivity of the resolvents (I + ~tH)- 1. [] The next corollary gives a variant of this result which stresses the N -dissipativity. COROLLARY 2.2.8. Assume 2 + is normal and int 2 + ~ 0. Let N u and ,~, denote the half-norms associated with a u e int ~' +. Then the following conditions are equivalent: 1. H generates a positive Co-semigrou p S with S,u <~u (respectively S,u = u) for all t > O, 2. H is norm-densely defined, R(I + ~tH) = ~ for some ~t > O, and H is N-dissipative (respectively IV-dissipative), and these conditions imply 11S, II ~<M for some M >1 1 and all t >i O. Proof. 1 =} 2. If H generates a positive Co-semigrou p with S~u <~u then (I + uH)- 1 is positive for all ~t > 0 and (I + otH)- l a <~N ,(a)(l + ~tH)- lu <~N ,(a)u. Therefore N,((I + ~H)- ~a) <~N (a) and H is N -dissipative. 2 = 1. If n is N -dissipative then n is t]-]l -dissipative and the range condition ensures that H generates a positive Co-semigrou p of contractions on (2, ~ + , I111.), Moreover (I + ~H)- lu ~
\

l+nH

u~
The bound on IIs, II follows because I l L and IIII are equivalent, by normality of 2+.

The proof of the .~ -dissipative case is similar.

[]

It is interesting to note that positive Co-semigroups automatically satisfy a stronger positivity condition, if int 2 + =/=0. P R O P O S I T I O N 2.2.9. Let S be a positive Co-semigrou p on an ordered Banach space

266

CHARLES J. K. BATTY AND DEREK W. ROBINSON

(~, ~ + , I1"It) with generator H. Then S,(int ~ + ) ~ int :~+,

(I + ctH)- l(int ~ + ) ~ int :~+,

(I + :~H)- t(qu.int :~+) ___qu.int ~ + ,

for all t >>-0 and all (small) o~>i O. Proof. We first show St(int ~ +) G int ~ +. If int ~ + ~ 0, there is nothing to show. Otherwise choose ur ~ . then by continuity there is an e > 0 such that S,ur ~+ for 0 ~ 0 and 2Sfu <~Sy. Thus Sfv~ ~2intg~+ + ~ + G int:~+ whenever O<~t<~e. Finally, the semigroup property S, -- (S,/,)" applied for n > tie shows that Stint ~ + ) ___int :~+ for all t/> 0. Since int ~ + = 0 or int 9~+ = qu.int :$§ it now suffices to prove that (I + ~H)- t(qu.int ~ § _~ qu.int ~ + . If a e q u . i n t ~ + and o~e~*\{0}, then oJ(a)> 0 and to(S,a)>i 0 for all t > 0. Since t ~ o ( S , a ) is continuous it follows that

m( (I + eI-I)- l a) =

dt e-~e)(S,ra) > 0 o

and hence (I + a H ) - t a e q u . i n t ~ + .

[]

It is not, however, necessarily true that S maps quasi-interior points into quasiinterior points. EXAMPLE 2.2.10. Let :~ = { f ; f E C [ O , oo >,f(0) = limx~oo f(x) = 0} equipped with the supremum norm and let ~ + be the set of pointwise positive functions in ~. Then

qu.int~+={f;f(x)>O

for

x>0}.

Define the positive Co-semigroup S of right translations by

(S,f)(x)=O

if0~<x~
=f(x-t)

ift~<x

then S ~ + c~qu.int ~ + = O for t > 0.

[]

Theorem 2.2.7 establishes that if ~ § is normal with non-empty interior, then the generator property for H is equivalent to existence and positivity of the resolvents (I + ~H)- t for all small ~ > 0. The next example shows that the condition int ~'+ q: 0 cannot be omitted, nor does it suffice that int ~ * :# 0. EXAMPLE 2.2.11. Let ~---L~(R), and let ~ + be the cone of pointwise positive functions in ~. Furthermore let v(x) = 2-"

ifn-2-"~x<~n,n>~2

= 1 otherwise. For ~t > 0, t e ~ , one has

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

If

dx--

<. e-X/~ .(x) ff

dx e- '~/~+

O~e - t/a +

E

~f,,, - 2

267

dx 2" e- ~/~ .

e( 1 - n)/,z

( Now define H by D(/-/)= { f e ~ : f v is absolutely continuous, and (fv)'/veN}, I-If= = (fv)'/v. Suppose that (1 + e H ) f = O. Then e(fv)' + .Iv = O, so f(x) = c e-X/~/v(x) a.e. This contradicts the integrability off, unlessf = O. For g e ~ , let

k,(x) = ~

_ dt g(t)v(t) e- ~-'1/~.

Then

fo~ dxlk~/x~l~<-l f ~ _ ~

~

dt f f dx v(t)e-~-o/~lg(t)]

_ ~

~<( 1 -t

v(x)

e2/~

~tel,~_

~))ltgll.

Thus k ~ . Furthermore k~,~.D(H) and (I + aH)ko, = g. This shows that (I + all) is invertible and (I + 0tH)- l is positive. If g is a Cl-function of compact support, f -- g/v, and ft(x) = g(x - t)/v(x), then fo = f , f t e D ( H ) and d/dt(ft ) = - Hft. Hence D(H) is norm-dense in ~ ; and if H generates a C0-semigrou p S, then S t f = f, [ 17], Theorem 1.7. But if g, is a C 1-function with g,(x)=l =0

ifn

l

2- "-%<x~
i f x ~ < n - $ -1 2

1-n

o r i f x ~ > n - ~ -I + 2 -",

and f , = g,/v, then ]1f , I1 ~< 3 2 - " but ]151/2f" H ~ 1 (n >>-2). This contradicts the fact that 51/2 is bounded. [] A similar example may be constructed with ~ = {feC(R):limx_.• } [8]. So it does not seem possible to extend Theorem 2.2.6 to a larger class of ordered Banach spaces. Instead one may impose further conditions on the generator, and therefore on the semigroup. One example is the lower bounds 11(I +~tH)-laH

~>c~llall, a ~ + ,

for some c~ > 0. The resolvent identity

([3 - ~t)(I + atn)- 1(1 + fiB)- 1 = fl(I + fiB)- 1 _ ~(I + orB)- 1 shows that this condition is independent of ~t. P R O P O S I T I O N 2.2.12. Let H be the generator of a positive Co-semigrou p on an

268

C H A R L E S J. K. B A T T Y A N D

DEREK

W. ROBINSON

ordered Banach space (~, ~ + , I1'11) satisfying [ISt II <~M exp {Tt}, t >10. Let s > O, > O, a7 < 1 and consider the following conditions: 1. there is a c~ > 0 such that

[l(l +~n)-~all ~>c, llall,

ate+,

2. there is a 2 s > 0 such that

IlSsall I> Lllall, ate'+. Then 1 ~ 2 and if ~ + has a base 2 ~ 1. Proof. Let ~(t) = inf{ tl Sta II; a t . ~ + ,

I1a Ir = l}

= sup {~/> 0; IIS,a II >/~ IIa II for all

ae ~ +

}.

Then go is upper semi-continuous and the semigroup property S i l t = S s +t shows that

go(s)go(t) ~ go(s + t) <, IIss II go(t). Hence Condition 2 is independent ofs. 1 ~ 2. Suppose Condition 2 is false. Then by the above discussion there exists,

for any s > 0, e > 0, an a e ~'+ with IIa II = 1 and IISsa II ~<~. N o w ll S,a lI <~M e y'

ifO~
[IS,alP <<.~Me~"-~'

ifs<~t.

Hence

IIu + ~H)-la

H=

f o ~ dt e - tS ta fs/a

f

o

s/~

<~MS/~ + eM e-S/U(1 - ~7). But since ~ and s are arbitrarily small, this shows that Condition 1 is false. 2=, 1. Suppose ~ + has a base, so that there is a fl > 0 such that

fl i=~--1a i ~

i=1~'~

11ai 11

for all n i> 1 and all a i t ~ + . Hence for a e ~ + one can use a Riemann approximation to establish that II(I + ~ H ) - l a tl =

fo %

>1f l - '

dt e - ' S , a

dt e-t~o(Tt)t1 a [1.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

But Condition 2 implies that tp(s) > 0 for all s and hence Condition 1 is valid.

269

[]

In general Condition 2 of Proposition 2.1.12 does not imply Condition 1. Nor does the existence of a base ensure that the conditions are satisfied. E X A M P L E 2.2.13. Let :~ = C(T), the continuous functions on the circle, ordered by the pointwise positive functions :~§ and with the supremum norm. Define the positive Co-semigrou p of rotations S on :~ by (S, f j ( s ) = f ( s - t).

Then S satisfies Condition 2 of Proposition 2.2.12 with 2 = 1, but ((I + e/-/)- l f ) ( s ) =

dt

e-'f(s

- ~tl

and Condition 1 is not satisfied.

[]

EXAMPLE 2.2.14. Let ~ = L'(I/~+ ;dx) with :~+ the pointwise positive functions in :~. Define a positive semigroup S on ~ by ( S , f ) ( x ) = f ( x + t).

Although ~ has a base the conditions of Proposition 2.2.12 are not valid for S.

[]

Despite this last example there are many semigroups on base spaces which satisfy the conditions of Proposition 2.2.12. These semigroups can be characterized in various ways. Typically their adjoints must map the interior of the dual cone into itself. This is clearly not the case in Example 2.2.14 because the adjoint semigroup on L~176 ; dx) has the action ( S , f ) ( x ) = f ( x - t)

=0

t < x, O <~x <~t.

We will return to a more detailed discussion of this point in the next section. But we next demonstrate that the bounds

II(I+~n)-'all ~>c~llal[,

ae~'+,

provide sufficient extra information to ensure that H is a generator. T H E O R E M 2.2.15. L e t ( ~ , ~ §

I111)

be an ordered Banach space f o r which ~ + is normal and generating. L e t H be a norm-densely defined linear operator satisfying 1.

R(I + fiB) = ~,

2. ifO < ct <<,fl and (I + ~ t H ) a e ~ + , then a e : ~ + ,

3.

I1(/+/~H)-'all ~>cllall,

f o r some fl > 0 and c > O.

ae~+,

270

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Then H generates a positive Co-semigrou p satisfying bounds

lls, ll<Me'l~,

IIS,atl~,llall, a ~ + ,

for some M >t 1 and 2 t > O. P r o o f The resolvent (I + f i l l ) - 1 exists and is positive, hence bounded, by Proposition 1.7.2. Let

IIa II' = inf{ 11(I + f i l l ) - l a I I[ + ]l (I + fill)-Xa 2 [I;a = a 1 - a 2, a I , a 2 ~ + } . Therefore [1a II' t> c IIa111 + c I[as II/> e IIa II by Condition 3 and the triangle inequality. But if :~ + is 2 +-generating, there is a decomposition a = a 1 - a 2 with IIal II + IIa2 II "< ~ IIa II. Hence IIa I1' ~ ~ II(I + •n)- 11111a II. Thus IIII' and flll are equivalent norms. Next, by perturbation theory (I + ctH)- 1 must exist for 9 in an open neighbourhood of fl and by Condition 2 (I + ~ H ) - 1 must be positive. Suppose 0 < 9 < fl then the resolvent identity gives (fl - ~)(I + f i l l ) - 1(/. + g n ) - i

=

fl(/. + f i l l ) - '

- ~(/. + g H ) - '

<~ fl(I + f i n ) - '

and hence by iteration (fl - ~)"(I + f i B ) - 1(1 + ~ H ) - " <~ fin(/. + f i n ) - 1.

Now if (/. + ~H)'a = a 1 - a s with a l , a 2 e ~ + , and if II II is #-monotone, then

(fl - ~r IIa II' ~< (fl -

a)n{

II(/. +

fill)-1(/. + o~H)-na, ]l +

+ 11(/. + f i n ) - 1 ( 1 + o:H)-"a 2 ]]}

~/r{

II(I

+ f i B ) - ' a,

II § II(I

+ f l U ) - ' a s It }.

Hence /t-1(1 -

~fl-l)n 11a I]' .< [l(/+ ~n)na 11'.

It now follows by a standard perturbation argument and the F e l l e r - M i y a d e r a Phillips theorem that H generates a Co-semigrou p S on ~ with the bounds IIS, II' "< ~ e'/a

and hence

[1St II ~ Me'/P

for some M / > 1. Finally, positivity of S follows from positivity of the resolvents and the lower bounds IISta II/> 4, IIa II, a~+, follow from Condition 3 and Proposition 2.2.12. [] We conclude this section with two examples. The first is a c o m m e n t on dissipativity in an algebraic setting. E X A M P L E 2.2.16 (Dissipations on C*-algebras). Let ~ be the self-adjoint part of a C*-algebra with an identity {, ordered by the positive elements :~+. Let H be a bounded linear operator on ~ with the negative off-diagonal property and define H' by H'(a) = n(a) - {aH(~) + n('O)a}/2.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

271

I f a e ~ + , coE~*, and co(a) = 0, then co(ab) = 0 for all b e ~ by the Cauchy-Schwarz inequality. Hence, with b = H0), one concludes that H' has the negative off-diagonal property and therefore generates a positive Co-semigrou p S on ~. Moreover H'(* ) = 0 and so S,(~) = ~ for all t >/0. But an inequality of Kadison [44] then gives

St(a 2) >1 St(a) 2 for all a~@ and t >I O. Differentiating at t = 0 one obtains H'(a 2) ~<art'(a) + H'(a)a or, equivalently, H(a 2) + aH(~)a <~all(a) + H(a)a,

a~.

(*)

Conversely, suppose H satisfies (*) and let a ~ + , co~M*, with co(a)= 0. It then follows from the Cauchy-Schwarz inequality that co(al/2b) = 0 for all bEM and hence applying (*), with a replaced by a ~/2, one finds co(H(a)) <~O. Thus H has the negative off-diagonal property. In conclusion, the negative off-diagonal property for H is equivalent to the algebraic dissipation condition (*). [] The final example partially motivates the study of Co-semigroups. EXAMPLE 2.2.17. Let ~ = U ~(X; d#) and ~ + the cone of pointwise positive functions in ~'. It can be shown that any positive Co-semigrou p on ~ is automatically uniformly continuous [50]. But ~ is the dual of ~ , = L~(X;d/O so it is natural to study Co-semigroups on ~ , e.g., translations are a C*-semigroup on L~(~; dx). [] 2.3. C*-SEMIGROUPS

In this section we discuss positive C~-semigroups and their generators. Throughout the section (~, ~ + , I]" I]) is an ordered Banach space, which is the dual of another ordered Banach space ( ~ , , ~ , + , ll'll,), and H denotes a weak*-densely defined, weak*-closed, linear operator on ~. Moreover H* denotes the norm-closed, normdensely defined operator on ~ , which is adjoint to H. If H generates a C~-semigroup S, then positivity of S is again equivalent to positivity of the resolvents (I + ~tH)- ~, and if S is positive, then D(H)c~ ~+ is weak*-dense in ~ + . The first result is a C~-version of Theorem 2,2.1. T H E O R E M 2.3.1. Suppose that I111 is monotone and the operator norm on ~ ( ~ , ~ ) is positively attained. Let N be the canonical half-norm on ~ and M, fl, and 7, real numbers with M >1 1, fl > O, and fl), < 1. The following conditions are equivalent: 1. H generates a C'~-semigroup S satisfying

II s,[I ~ M e~', 2.

R(I +/~H) =

t~>O,

272

CHARLES J. K. BATTY AND DEREK W. ROBINSON and N((I + ~H)"a) >i (1 - ~7)"N(a)/M

for all aED(H"), all n >1 1, and 0 < 9 <. 8. In particular these conditions are equivalent if

either

I111 is

or

~ + is 1 +-generating and I1"11is monotone

a

Riesz norm

The proof of equivalence of the two conditions is identical to the proof of Theorem 2.2.1, but one uses the Cg'-version of the Feller-Miyadera-Phillips theorem. In fact it is sufficient that II" I] is monotone and the operator norm is positively attained for positive weak*-continuous operators. This happens if, and only if, g + is dominating and the operator norm on &P(~., ~ , ) is positively attained. In this case Theorem 2.3.1 could also be deduced from the C0-version, Theorem 2.2.1, applied to the adjoint H , of H on g . . Moreover, the foregoing conditions are ensured if I1"11 is a Riesz norm or ~ + is 14-generating and I1"I[ is monotone. These statements all follow from Proposition 1.7.8, Lemma 1.7.11, and the earlier duality results. There is also a C*-version of Theorem 2.2.4. T H E O R E M 2.3.2. Suppose ~ + is dominating and I111 is monotone. Then Conditions I and 2 of Theorem 2.3.1 are equivalent, but with the modified bound II s, II + ~< M exp {~t} in Condition 1. The proof is very similar to that of Theorem 2.2.4. Alternatively one may deduce the result by applying Theorem 2.2.4 to the adjoint H* of H on ~', and then using the identity IISt II + = tl s,* II + of Lemma 1.7.11. So far the results in this section have been in almost exact parallel with Section 2.2. But now we discuss the special case int ~ + 6 0 and a number of differences occur. Let ~' = L~(R+ ;dx) with ~ + the pointwise positive functions in ~ and consider the C~-semigroup S defined by ( S , f ) ( x ) = f ( x - t),

=0,

t~<x

O<~x
(This is the adjoint of the semigroup considered in Example 2.2.14.) Let H denote the generator of S. Although int .~+ =# 0 and D ( H ) n ~ + is weak*-dense in ~ + one has D(H) n i n t ~ + = 0. The C*-analogue of Theorem 2.2.7 also fails in general. The adjoint of the operator H of Example 2.2.11 is a counterexample. Nevertheless it is possible to characterize positive C*-semigroups whose generators satisfy D(H) n i n t ~ + ~ 0 and then to characterize the generators of such semigroups. P R O P O S I T I O N 2.3.3. Suppose that int ~ + @ 0. Let S be a positive C~-semigroup on ~ satisfying bounds ]l S, ]l ~< M exp {Tt} for all t >10. Let s and ct be strictly positive numbers, with ~7 < 1, and let u6int ~ + .

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

273

The following conditions are equivalent:

1.

D(H)c~int ~ + ~ 0 ,

2. (I + ~tH)- tuEint :~+, 3.

Ssueint ~ + ,

4. there is a c~ > 0 such that

IlU§

c 110911,,

5. there is a ~s > 0 such that

§

IIs '09 II, 2 II09 I1,,

Proof. 1 ~ 2 . Let v ~ D ( H ) n i n t ~ + . Since u s i n t ~ + there exists 2 > 0 such that (l + ~H)v <~2u. Hence v ~< 2(I + ~H)- lu and so (l + ~H)- lu~int M+. 2 ~ 1. Clearly (I + ~ H ) - ~u ~ D ( H ) c~ int ~ +. 2.~4. Let K = {09; o9~ ~ , +, 09(u) = 1}. Then K is a base of ~ , + and

int ~ + = { a ; a s ~ + , inf 09(a) > 0} ~r

by Proposition t.4.2. Hence Condition 2 is equivalent to inf 09((I + ~H)- lu) > 0. co~K

Since there are constants ~ > 0, fl > 0, such that ~ I[09 II, ~ 09(u) 09sM,+, this is equivalent to Condition 4. 3 <=~5. The argument is similar to the above. 4 , ~ 5. Since ~ , + has a base, this follows from Proposition 2.2.12.

I109I[,,

for all

[]

Now one can deduce a version of Theorem 2.2.7 for a restricted class of C*-semigroups. T H E O R E M 2.3.4. Suppose ~ + is normal and int ~ + :# 0. The following conditions are equivalent: 1. H generates a positive C~-semigroup S such that S,(int ~ + ) _~ int.~+, 2. a. b.

t~>0,

D ( H ) n i n t ~ + :/:0, R(I + fin) = ~ ,

c. ifO < o~ <<,fl and (I + o ~ H ) a ~ + then a e ~ + , for some fl > O. Proof. 1 ~ 2. This follows from Proposition 2.3.3 and general semigroup theory. 2 ~ 1. Choose u ~ D(H) n i n t ~'+ and let y = / q ( - Hu). It follows from the argument used to prove 1 ~ 2 in Proposition 2.1.4 that N ((I + ~tH)a) >/(1 - ctT)N (a )

274

CHARLES J. K. BATTY AND DEREK W. ROBINSON

for all aeD(H) and hence [I(I + ctH)na [[u ~ (1 - ~7)n IIa Ilu

for all ~ > 0, ~7 < 1, and all aeD(Hn). Thus H generates a Co-semigrou p S satisfying Ilstllu exp( t} by the C0*-version of the Feller-Miyadera-Phillips theorem. Positivity of S follows from Condition 2c and St(int M+ )c_ int ~ + by Proposition 2.3.3. [] Theorem 2.3.4 can also be proved by applying Theorem 2.2.15 to the adjoint H* of H on ~', and taking note of the equivalence 1 ~,4 in Proposition 2.3,3. One can also derive a Co*-version of Theorem 2.2.15. The proof is almost identical once it is observed that the implication 1 =>2 in Proposition 2.2.12 is valid for C~semigroups. T H E O R E M 2.3.5. Suppose that ~ + is normal and generating and there exist fl > 0 and c > 0 such that 1.

R (I + fill) = ~ ,

2. ifO < ot <~fl and (I + ~ H ) a e ~ + then a e ~ +

3.

Iltl+/m)-'all

>cllall,

Then H generates a positive CZ-semigrou p S satisfying 11St tl ~ M exp {t/fl} for some M >1 1 and

IIS,a II t> ,11 a II for all a e ~ + and some 2 t > O.

For ordered spaces (~', :~ +, I1' ]l) with a predual ( ~ , , M, +, I1[I,) there is a weaker notion of interior point which differs from the quasi-interior point introduced in Section 1.4. A point a e ~ + is said to be an N-interior point of M+ if ~o(a) > 0 for all o~e~,+\{0}. The set of N-interior points is denoted by N.int~§ and one has in general int ~ + ~ qu.int ~ + ~ N.int ~'+. If H is the generator of a positive C*-semigroup S then the argument used at the end of the proof of Proposition 2.2.9 shows that (I + ~H)- ~(N.int ~ + ) ___N.int ~ + . Moreover if a e N . i n t ~ + , ~ o e ~ , + , t > 0 , and ~o(Sta)=0, then S*o9=0. Hence if int ~ + ~ 0 and S tint ~ + _ int ~ + , then S,(N.int ~ + ) _ N.int ~ + . But this last inclusion is possible even if S does not map the interior of M+ into itself. EXAMPLE 2.3.6. Let ~ = L~(R+ ;dx) and ~ + the pointwise positive functions in ~ . Then int~+=qu.int~+={f;fe~,f(x)~>Ka.e, N.int ~ + = { f ; f e ~ , f ( x ) > 0

for some K > 0} a.e.}.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

275

Now define a positive C*-semigroup S by S t f ( x ) = f ( x - t) =0

t <~x O<~x
This is the adjoint of the Co-semigrou p of Example 2.2.14 and ((I + ~H)- l f ) ( x ) =

f

xla

dt e - ' f ( x - at).

dO

So S,(int ~ + ) ~g N.int ,~+ and (I + ~H)- 1tint ~ + ) ~ int M+. Alternatively define the Co*-semigroup T on ~' by ( T J ) ( x ) = e-'/X f(x). Then S,(N.int M+ ) _~ N.int ~ + but S,(int M+ ) ~ int M+. In fact S,(M+ )c~int ~ + = 0 for all t > 0. [] Von Neumann algebras provide one setting in which the theory of C*-semigroups is of relevance. A v o n Neumann algebra can be characterized either abstractly as a C*-algebra with a predual, or concretely as a weakly closed C*-algebra ~//acting on a Hilbert space oW. In this second framework there is an interplay between C osemigroups on Jg and C~-semigroups on Jr E X A M P L E 2.3.7 (von Neumann algebras). Let ~ be the self-adjoint part of a von Neumann algebra on a complex Hilbert space 9re, ordered by the positive elements ~ + . Let U be a Co-semigrou p on oW with generator K and suppose U* ~ U t ~for all t i> 0. Then one can define a positive C 0-semlgroup * ' S on ~ by S,a = U* aU,. I f H denotes the generator of S, one can establish that aeD(H) if, and only if, aD(K) ~_ ~_ D(K*) and r + K * a ~ is a bounded operator from D(K) into ~ ; then Ha is the continuous extension of this operator to ocg( [11] Proposition 3.2.55). []

2.4. SEMIGROUP TYPE A N D SPECTRAL BONDS

In this section we examine a number of relations between the spectrum a(St) of a semigroup S and the spectrum tr(H) of its generator H. We consider both C 0- and Co*-semigroups, and in the latter case we implicitly assume that the space has a predual. In the context of positive semigroups we further assume that the space and its predual have dual orderings. If H is bounded then St = exp { - tH} and the spectral mapping theorem gives ~r(S,) = {e-tZ; zeo(H)}. In particular the spectral radius p(S t) of S t is exp { - t m H } where m H = inf{Re z; zea(H)}.

276

CHARLES J. K, BATTY AND DEREK W. ROBINSON

If H is u n b o u n d e d the spectral m a p p i n g t h e o r e m is no longer valid but one can conclude that a(S,) m_ {e-'~; z e a ( H ) }

and hence p(S,) >1exp { - tm H }

(see, for example, [17] T h e o r e m 2.16). F u r t h e r m o r e p(S z) = exp { t Ys }

where 7s = lim t -1 log [IS t [I t~o0

= inf{7; ][Stl [ < . M e : , t >~0, for some M} so that - ~ ~< Vs < ~ [17], T h e o r e m 1.22. Thus 7s >I - ran. The n u m b e r s 7s and m n are k n o w n as the type of S and the spectral bound of H, respectively. In the absence of positivity Vs m a y be strictly larger than - m n even in such special cases as a Hilbert space [86] or a C*-algebra [37]. In the sequel we examine conditions which ensure that Vs = - m n for a positive semigroup. Clearly 7s = Vs. and m n = mn. if S is a Co-semigrou p so it m a k e s no difference whether we consider C o- or C~-semigroups. Note that if 2 > 7s, then the resolvent (2I + H ) - 1 is given by the Laplace transform

(2t

+ H)

-l=fl ~dte-~t

St ,

where the integral is norm-convergent. F u r t h e r m o r e dt e - a, I1S,a II ~<

dt e - ~' M e : I1a I1 < oo,

where Vs < V < 2. The following l e m m a gives a converse. L E M M A 2,4.1. Let S be a C o- or C~-semigrou p and 2 a real number. 1. If for each a e

:o

~

<

then 2 >1)'s" 2. lffor each a ~

and c o e ~ * (or o g e ~ , ifS is a C*-semigroup)

d t e -at Io~(Sta )l < oo 0

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

277

then 2 > - m H. Moreover if 2' > 2 then (2'I + H ) - 1 =

dt

e-Z"S,

where the integral is norm-convergent. Proof. 1. Suppose that 2 < 7s. Then IIS, II exp { -. o0 and, by the uniform boundedness theorem, there exists an a e ~ and a sequence of integers n i --* oo such that IIS , a II e x p { - 2hi} >/1. Thus, if K

= sup{e- 'll s, II ;0

1},

then

e- ,ll S, oll

K-'

for t~[nl - 1, ni] and

o: dt e-a'll Stall = oo. 2. In order to use spectral arguments it is appropriate to introduce a complexification of ~ and to extend operators by linearity. There is a large class of equivalent norms that can be used for this complexification, but this ambiguity does not affect the following spectral argument, and in special cases, such as LP-spaces or C*algebras, there is usually a natural choice of norm. We will make no notational distinction between the real and complex structures. Suppose t ~ - ~ o ( S t a ) e x p { - 2 t } is integrable for all a e ~ and oge~* (or o ~ , in the Co*-case). Define L, by L t (z) =

;o

ds e - zsS

for complex z. Then two applications of the uniform boundedness theorem show that { L,(2); t/> 0} is uniformly bounded. Moreover if Re z > 2, the formula

L~(z) = e-~Z- ~'L~(2) + (z - 2)

;o

ds e - ~ - alSL (2)

shows that L~(z) converges in norm, as t --, oo, to a limit L(z) which is an analytic function of z. But if Re z > 7s, then L(z) = (zI + H)- 1 and hence, by the uniqueness of analytic functions - zCa(ft) and L(z) = (zl + H)- 1 for Re z > 2. Finally the estimate

[~((zl + H ) - l a ) l =

dte-Zto(Sta) <<.

dte-a'lo~(S,a)l

for Re z > 2 and two applications of the uniform boundedness theorem show that {(zl + H ) - 1; Rez > 2} is uniformly bounded so m n > - 2 by perturbation theory. []

278

CHARLES J. K. aATTY AND DEREK W. ROBINSON

Part 1 of L e m m a 2.4.1 can be i m p r o v e d to show that 2 > Vs. Next consider a real n • n-matrix H acting on ~", ordered by g~_. Then exp { - t i l l is a positive semigroup if, and only if, H has negative off-diagonal matrix elements. In this case 2I - H has positive matrix elements for sufficiently large positive ;l and it follows from the P e r r o n - F r o b e n i u s t h e o r e m that n n = sup {Re z; z~tr(M - H)} is an eigenvalue of 21 - H with an eigenvector which m a y be chosen to be positive, Therefore m H is an eigenvalue of H, with positive eigenvector. The following result is a partial infinite-dimensional analogue of these facts. A further extension is given in T h e o r e m 2.4.6. T H E O R E M 2.4.2. Let S be a positive C o- or C~-semigroup on the ordered Banach space (,~, ~ +, II" II) and suppose ~ + is normal and generating. Let H denote the generator of S. It follows that 1. if a(H) ~ 0 then m n ~ a ( H ) and

IIa II =

0 = inf{ [I ( m n I - H ) a

1}

2. if 2 > - m n then (2I+H)-'=f2dte-~'S

~

where the integral is norm-convergent, and in particular, (2I + H ) - 1 is positive. Proof. Suppose mnq~a(H), so there exists a ,~ < - m n such that e(H) does not intersect the real interval ( - oo, - 2]. F o r a e ~ + and ~ o e ~ * (or ~ o e ~ , + in the C~-case) the Laplace transform of the positive function t~-*oJ(Sta) exists for Rez > 7s and has an analytic extension to a region containing [ 2 , ~ ) given by z~--* ~-*o~((zI + H ) - la). By the P r i n g s h e i m - L a n d a u t h e o r e m [-83] the Laplace transform exists for Re z/> 2. In particular t~--~oa(Sra) exp { - 2t} is integrable over R+ for a e ~ + and c o e ~ ' * , and hence for all a e ~ and ~oe ~ , because ~ § and ~ * are generating. It then follows from L e m m a 2.5.1 that - m u < 2 which is a contradiction. The a b o v e a r g u m e n t shows that t~--*~o(S,a)exp{-)~t} is integrable over ~ + for 2 > - m H and hence the second statement of the t h e o r e m follows from L e m m a 2.4.1. Finally, suppose 2 n < m n but 2 n ~ m u as n---, oo. Therefore I]( 2 h i - H ) - ~ [[ ~ oo and one can choose a h e m such that [[ a n [[--, 0 but [1( 2 n i - H ) - ' a , [[ = 1. M o r e o v e r since ~ + is generating one can assume a n e ~ + . Therefore setting b. = (2 n I - H ) - i an one has b , ~ + by Statement 2 of the t h e o r e m and t[ bn ]I = 1 But I](m,I -

H)b. l[ < ~ ( m .

- ,~.)+

IIa. II-~0

[]

C O R O L L A R Y 2.4.3. If H generates a positive Co-, or C*-, group on an ordered Banach space for which ~ + is normal and generating then a(H) --fiO.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

279

Proof. Suppose tr(H} = 0. Since _+ H generate positive C o- or C~-semigroups, it

follows from Theorem 2.4.2 that ( _+ H)- 1 are both positive. But this is impossible since ~ + is proper and ~ + ~ {0}. If S is of type - ~ then a(H) = 0. This is, for example, the case if ~ = LI(0, 1) and (S,f)(x)=f(x-

if x - te[0, 1] otherwise.

t)

= 0

But o(H) can be empty even for positive Co-semigroups of finite type. This will be demonstrated in Example 2.4.8. T H E O R E M 2.4.4. Let S be a positive C o- or C~-semigroup on the ordered Banach space (~, ~ + , tlll) and suppose ~ + is generating and has a base. Let H denote the generator o f S. It follows that m n = - 7s. Proof. If ~. > - m n then (2l+H)-la=

dte-atSta,

where the integral is norm-convergent, by Theorem 2.4.2. Now I111 is e-additive for some e/> 1, by Proposition 1.4.2, so by the use ofRiemann approximants one deduces that

dte-X'llS, all <~

;o:dte-~'S,a

=~ll(2I + n)-'all < § o~, at least for a in the set 6e= {a;a~+,lim

tlS, a - a l l

=0}.

t+O

l f S is a Co-semigrou p, 6P = ~ + which spans ~ and Ys ~<2 by Lemma 2.4.1. Hence Ys <~ - rnn and the proof is complete since the reverse inequality is always true. If S is a C~-semigroup then a e ~ + is the weak*-limit of the bounded sequence a 9 a where a =n

f

l/n

dt S ta.

dO

Therefore

dte-X'llS, all -N
dte-a'llS, a. II

n--* ot3

~<~ II(~I + H)- '11 lim infil a. I[ < Again the result follows from Lemma 2.4.1.

+ oe.

[]

280

CHARLES J. K. BATTY AND DEREK W. ROBINSON

COROLLARY 2.4.5. I f H generates a positive C o- or C~-semigroup on an ordered Banach space for which ~ + is normal and e-directed, then m , = - 7s. Proof. Since M* (or ~ , § in the C~-case) is generating and has a base, by Proposition 1.4.2 and the subsequent remarks, this result follows by applying Theorem 2.4.4 to S*. [] It follows from Theorem 2.4.4 and Corollary 2.4.5 that m n = - ~ s for positive semigroups on L 1- or L~-spaces. A completely different argument [57] establishes that this is also the case on L2-spaces, but the result appears to be unknown for general LP-spaces. Theorem 2.4.4 established that if M has a predual ~ , and M+ is generating with a base K then m n = - 7s for all positive C~-semigroups. But if K is weak*-compact, which is equivalent to int M, § r 0 by Proposition 1.4.2, then m n is in fact an eigenvalue of H. T H E O R E M 2.4.6. Let S be a positive C*-semigroup on an ordered Banach space IItl) with an ordered predual. Suppose ~ + is generating and has a weak*compact base K. Then there exists an a e K such that Sta

=

ers'a, t >10.

Proof. Let H denote the generator of S. By Theorems 2.4.2 and 2.4.4 one has

- 7sea(H) and inf{ ]](Ts I + H)a ] I ; a ~ D ( H ) n ~'+, I]a]l = l} = 0. Next note that for each a E ~ + there is a Ax(a) such that a E 2 x ( a ) g and e Ilal] ~ <<-At(a) <<"fl ]la]I for some 0 < e ~
t>10.

[]

C O R O L L A R Y 2.4.7. Let S be a positive Co-semigroup on an ordered Banach space for which ~ + is normal and has an interior point u, and let H denote the generator of S. The following conditions are equivalent: 1. For each tge~*\{0} there exists a t > 0 such that to(Stu) < co(u), 2. For each o ~ * and a e ~ , a~(Sta) ~ 0 as t --, ~ , 3.

IIs, II- 0

4.

?'s
ast-

,

5. There exists a r e D ( H ) n i n t ~ + and a 2 > 0 such that H v >12v. Proof. 1 =~ 4. This follows from Theorem 2.4.6. 4 ~ 3 ~ 2 ~ 1. These implications are obvious.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

281

4 ~ 5. Take 0 < 2 < - ~'s then v = (H - 2I)- lu 9 D(H) ~ int ~ + by the proof of Proposition 2.2.9. But Hv - 2v = u >t O. 5 ~ 3. Since Hv >12v one has (I + tHin)- tv ~ (1 + t2/n)- iv and hence, by iteration S , v < . . e x p { - 2 t } v . Therefore for all a e ~ ' where []'llv denotes the order-unit norm defined by v. But II'llo and I[" II are equivalent, because + is normal, so IIS, II < M e x p { - 2t} for some M >/1. []

IIS,allo<expf-2t}llallv

Note that the equivalence of Conditions 4 and 5 in Corollary 2.4.7 establishes that if S is a positive Co-semigrou p with generator H on a space for which ~ + is normal and int ~ + 6 t3, then mn = - Ys = sup {2; 2 9 R, Hu >i 2u for some u 9

i nt ~ + }.

We conclude the section with a number of illustrative examples. EXAMPLE 2.4.8. Let

~={f;feC(R+),

lim f(x)--- 0,

x~c~

fo dxe~2[f(x)[<+~}

and let N§ be the pointwise positive functions in ~. Moreover define the norm by

Ilf[I = I1f I[, + 11f 11.~ where

II f I1~ =

f:

dx eX21f(x)],

IIf t1~ = sup Iftx)l. xeR +

Then ~' is a Banach lattice and there is a positive Co-semigrou p of lattice homomorphisms on ~ defined by

( S , f ) ( x ) = f ( x + t). Moreover 1[S, I1 = 1 and ~s = 0. Now for real 2

ds -

~ca

dse'X+"~lf(x +s)l~
where c a = sup {exp( - 2s - s2); s t> 0}, and

If:

ds e- a~S~f

II f: fo ~<

ds e - a~

dy e ~r- ~1 f(y)]

~<

ds e- as-~2 ][f ][,.

282

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Thus the operators L,(2) =

;o

ds e - ~'S~

are uniformly bounded, for all t / > 0 , and it follows as in part 2 of L e m m a 2.4.1 that a ( H ) n {z; Re z < - 2} = 0. Since 2 is arbitrary a(H) = 0. This example can be modified in several ways. T a k i n g H = LP(N+ ;e px2 dx) n Lq(~+ ;dx)

with 1 < p < q < oc one can arrange that H is reflexive, 7s = 0, but ~z(H) = 0. Alternatively taking H=

f;feC(N+),

limf(x)=0,

dxeXlf(x)[< ~c []

one can arrange that ~'s = 0 but m n = 1.

E X A M P L E 2.4.9 (von N e u m a n n Algebras). Consider E x a m p l e 2.3.7. One has US, I] = []S,~ [[ = [[ U*U,[[ = I1U,H 2 where ~ is the identity in H. Therefore ys = 2y v. M o r e o v e r by Corollary 2.4.5 one has m u = - Y s - M o r e specifically the following conditions are equivalent: 1.

mn >0,

2.

yv<0,

3. For each b s H + there exists an a s D ( H ) n H + 4. There exists an a s H + such that H a = 4, 5. For all q~s~f' one has

such that H a = b,

f o ~ dt ll U t(-P 112< 0%

6. F o r all r ~bsJf ~ and a s h

one has

o: dtl(q,, (S,a)O)[ < o0. The equivalence 1 *:,2 follows from the above discussion; 1 ~ 3 by T h e o r e m 2.4.2; 3 ~ 4 is trivial; 4 ~ 5 by the estimate

;o

ds II gr

II5 =

So

ds(qh (SsHa)q))

= (qL (a - Sta)q)) <~(~o, aq0);

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

283

5 => 6 by the estimate

i;oOdt(tp, ,s.,

~< IIa

II

= IIa II

foodt(tp, (S,~)tp) fo at I1g, o II2

and polarization. Finally, ~ , + consists of infinite runs of functionals a~(~o, atp), q~c Yf, and by a uniform boundedness argument Condition 6 implies

O~dtleJ(S, ajl < oo for all c o ~ , so m n > Oby Lemma 2.4.1.

[]

2.5. IRREDUCIBILITY AND STRICT POSITIVITY Theorems 2.4.2 and 2.4.6 give infinite-dimensional analogues of the simplest features of the Perron-Frobenius spectral theory of positive matrices and one could expect to derive other analogues by further extension of the matrix theory. The purpose of the present section is to pursue this point. Recall that the matrix semigroup S c = exp { - tH} acting on ~ = ~n, ordered by ~ + = II~., is positive if, and only if, the matrix A -- IIn I1t - n is positive, i.e., has positive entries. Thus spectral properties of S can be derived from application of the Perron-Frobenius theory either directly to the S, or to A. This theory states that the spectral radius of a positive matrix is an eigenvalue with a positive eigenvector, and strictly positive, or positive 'irreducible', matrices have even stronger spectral properties, e.g., the spectral radius is a simple eigenvalue with a strictly positive eigenvector. The first of these points was generalized in Theorem 2.4.2 and 2.4.6 and we now examine extensions of the second. The initial problem is to find a suitable irreducibility criterion. There are various equivalent definitions of irreducibility for a positive matrix and we begin our discussion by investigating the extent to which these definitions remain equivalent in infinite dimensions. Let (~, ~ + , I111) be an ordered Banach space. A subcone rg of ~ + is said to be hereditary if 0 ~ a ~
284

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Note that if :T is a semigroup, i.e., if SP~ _ ~ , then the smallest ~-invariant hereditary subcone o f ~ + containing a is given by

{b; b ~

+ , b <~ i 2iT~a for some 2i >~O, T~eSe }. i=l

Moreover, if 5e is a general subset of 5e(~, ~)+ and 5e* = {T*; TeSe}, then strict positivity of 5g and *-strict positivity of 5p* are each equivalent to the condition, if toE~*\{0} and a e ~ + \ { 0 } then to(Ta) > 0 for all T~Se.

(.)

Finally, if 5~ = {T} contains the unique operator T, we describe T as norm-irreducible instead of {T}, etc. The various notions of irreducibility, ergodicity, and strict positivity, are generally not equivalent, as we will subsequently see. But first we examine the interrelationships between these properties for continuous semigroups. For this purpose it is useful to introduce various notions of sharpness of the cone ~ + . First, for ~r ~ ~ + define .~r177by .~r = {09; toe,@*, to(a) = 0 for all a ~ d } and for .~1 _ ~ * define ~r177by .~1" = {a; a e ~ + , to(a) = 0 for all to~z,r Now ~r property) if ~•

is defined to satisfy the positive bipolar property (positive *-bipolar

= @

for each hereditary subcone cs of ~ + ( ~ * ) where the bar denotes norm- (weak*-) closure. Less stringently ~ + ( ~ * ) is defined to be sharp (*-sharp) if each hereditary subcone ~ o f ~ + ( ~ * ) for which ~• = {0} is norm- (weak*-) dense in ~+(~'*). Finally M+ ( ~ * ) is defined to be n-sharp (w*-sharp) if there is no proper norm- (weak*-) closed hereditary subcone ~ of ~ + ( ~ * ) for which ~1 = {0}. If ~ + ( ~ * ) satisfies the positive bipolar (*-bipolar) property, then it is sharp (*-sharp), and if it is sharp (*-sharp), then it is n-sharp (w*-sharp). Conversely, if ~r (.~*) is n-sharp (w*-sharp) and the norm-closure (weak*-closure) of evei-y hereditary cone in ~r (~*) is hereditary, then ~ + (~*) is sharp (*-sharp). After these preliminaries we return to the examination of irreducibility criteria for semigroups. Strict positivity is generally stronger than irreducibility, but this latter property is usually equivalent to ergodicity, at least with some sharpness assumption. T H E O R E M 2.5.1. Let (~, ~ + , I1 II) be an ordered Banach space with ~ + proper and weakly generating. Let S be a positive Co-semigroup of type ~ on ~ with generator H, and let a > 0 satisfy ~t]:< 1. Consider the following conditions: 1. S is norm-ergodic, 1". S* is weak*-ergodic,

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

285

2. S is norm-irreducible, 2*. S* is weak*-irreducible, 3. (I + otH)- 1 is norm-irreducible, 3*. (I + gH*)- 1 is weak*-irreducible, 4. (I + ~H)- 1 is strictly positive, 4*. (I + ~H*)- 1 is *-strictly positive, 5. for each a ~ + \ { 0 } and o ~ * \ { 0 } there is a t > 0 such that m(S,a) > O. It follows that 1 ~ 2 ~ 3 ~ 4 r and 1 " ~ 2 " r 1 6 2 Moreover, if:8+ is n-sharp 5 ~ 2 " / f ~ ' § is sharp 5 ~ 1 ; / f ~ ' * is w*-sharp 5 ~ 2 " ; and if ~ * is *-sharp 5~1". Proof. The proofs of 1 =~ 2 =~ 5, 1" ~ 2* =~ 5, and the converse statements under sharpness conditions are all elementary. 4~5r This follows from the formulae to((l + ~H)- la) = ((I + ~H*)- l~o)(a) =

fo

dt e-'m(S~ta).

3=~2. Any S-invariant norm-closed (hereditary) subcone is invariant under (I + a l l ) - 1 because of the relation (I + ~tH)- 1 =

fo

dt e - ~S~,.

2 =~ 3. Let ~ be a norm-closed hereditary subcone of ~ + which is invariant under (I + ~tH)- 1. If ~t(2 - ~7)- ~ < fl ~
1 .>~o

P

/

show that ~ is invariant under (I +/3H)- 1. Iteration of the argument establishes that is invariant under (I + / 3 H ) - 1 whenever 0
Sta=lim

I+

H

a

it follows that ~ is S-invariant. 2* o 3 " . The proof is analogous to the above.

[]

Theorem 2.5.1 demonstrates a disparity between strict positivity of a Co-semigrou p S and strict positivity of the resolvents (l + =tH)- t. If ~ § is n-sharp strict positivity of (I + 0tH)- ~ is equivalent to norm-irreducibility of S, but this is generally a weaker property than strict positivity of S, e.g., the semigroup S of rotations described in Example 2.2.13 is norm-irreducible but not strictly positive. Although spaces exist for which the cone ~ + is not sharp this property does occur in many important cases, as the subsequent examples show. In the first we use the following criterion: if r# is a (norm-closed) hereditary subcone of ~ + then ~ + is (n-) sharp if, and only if, ~ is norm-dense in M+ whenever W - ,~+ is norm-dense in

286

CHARLES J. K. BATTY AND DEREK W. ROBINSON

~. This follows from the bipolar theorem, Theorem A3 of the appendix. A similar criterion is valid for *-sharpness. EXAMPLE 2.5.2 (Order-unit spaces). Let (8, 8 + , II II) be an ordered Banach space with int 8 + =fi0. Then ~ + is sharp, but ~ + does not necessarily have the positive bipolar property even for ~ finite-dimensional. To prove sharpness suppose u~ ~int 8 + , so {a; Iiu - a II < ~} c i n t ~ + for some e > 0. Moreover let cg be a hereditary subcone of ~ + such that cg _ 8 + is norm-dense in ~. Then for a e ~ § there exist be~ and cECg such that II a § u § b - c II < ~. Therefore c - a - b ~ + so 0 ~< ~
{(x,y,z);z = 1,(x,y)~(K+ voK_ voK)} where K+ = {(x,y);x 2 + ( y § 1)2 ~< 1},K = {Ix, y), Ixl v lyl ~ 1}, then 8 + does not have the positive bipolar property, e.g., oK• 4 cg for the closed hereditary cone cg = = {(x,x,x);x ~>0}. In fact cgl " = { (x, y, x); lyl <<.x}. [] EXAMPLE 2.5.3 (Banach lattices). Let (8, 8 + , 11"II) be a Banach lattice then ~ § has the positive bipolar property. To deduce this suppose cg is an hereditary subcone o f ~ + . Since ~g c_ cg• it suffices to prove that ifcoe~* and co(cg) = 0, then co(of•177= 0. But this follows because (___o9 v 0)(of)= 0, by the formula quoted in the proof of Theorem 1.5.4, and hence coer -L- cg• It can also be shown that the dual cone ~ + has the positive *-bipolar property. EXAMPLE 2.5.4 (C*-algebras). Let ( ~ , ~ + , ll'll) be the self-adjoint part of a C*-algebra 92 ordered by the positive elements. The (norm-closed) hereditary subcones of 8 § are the sets of the form 8 § c~L where L is a (norm-closed) left ideal in 93. Furthermore 8 + has the positive bipolar property and 8 " is w*-sharp, but not necessarily *-sharp [23, 60]. If S is strongly positive in the sense that IIS, tl S,(a* a) >t S,(a)* S,(a) for all a~92, where S is extended linearly to 92, then L is S-invariant if, and only if, 8 § c~ L is S-invariant. Hence each of the conditions of Theorem 2.5.1 is satisfied if, and only if, there are no proper norm-closed S-invariant left ideals in 9.1. [] EXAMPLE 2.5.5 (von Neumann algebras). Let ( ~ , M + , I11t) be the self-adjoint part of a v o n Neumann algebra J / . The weak*-closed hereditary subcones of ~ § are the sets of the form ~ + n L where L is a weak*-closed left ideal in J / , or, equivalently, the sets of the form {x; x e ~ § xp = 0} where p is a projection in ~ . Furthermore ~ + has the positive *-bipolar property and 8 . . , the positive cone of the predual 8 , , has the positive bipolar property [23,60]. Hence a positive C* semigroup on Jr' is weak*-irreducible, or weak*-ergodic, if, and only if, there is no non-trivial projection p ~ at/with S, (p)(l - p) = 0 for all t. [] After these positive examples we give two examples for which sharpness fails.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

287

EXAMPLE 2.5.6. Let ~r be the space of P-sequences a = {a.}.>.l, equipped with the/1-norm llall = Z l a [ , and ordered by the cone ~r of positive sequences in .~r Moreover, let g be the one-dimensional subspace spanned by the sequence { ( - 2)-"}..> 1 and ~ = .~r the quotient space, equipped with the quotient norm, and ordered by the image of 8+ under the quotient map. One can establish that ~ + is generating with a base, but ~ + is not sharp. [] EXAMPLE 2.5.7. Let :~ be the space of U-sequences a = {a}..> 1 such that a ~ 0 as n--. 7: with the /a-norm, []a[t = suPla 1. Then ~ * is isomorphic to the space of P-sequences t o = {to.}.~l with the norm Ilto[[* = Z [ t o 1. The duality is given by to(a) = Yto.a . Let F={toe~*-to,=l,

to ..->0ifn..->3, Z nto. ~<1, E to = 0 } n~>3

X=ItoE~*;to~=l,

n~>2

to, /> 0 if n1> 2, Z to ~.<1} n~>2

and let K be the convex hull of F w X. Define M* as the cone with the base K. Then ~ * is generating with a weak*-compact base, but ~'* is not *-sharp. [] The theory of positive semigroups in finite dimensions is particularly simple because strict positivity and norm-irreducibility coincide. The next example shows that this simplification also occurs for norm-continuous semigroups on C(X) i.e., on a commutative C*-algebra. EXAMPLE 2.5.8 (Continuous functions). If ~ = C(X), ordered by the pointwise positive functions ~ + , then the (norm-closed) hereditary subcones of M+ are of the form ~E = { f ; f >10, f(x) = 0 for xeE} for (closed) subsets E of X. Hence each of the nine conditions of Theorem 2.5.1 is satisfied if, and only if, for each proper closed E there exists an f e M and t > 0 such that f is supported by E but S,f is not. IfS is uniformly continuous and positive, its generator n is bounded and [IH[ll - H is positive, [17] Theorem 7.21. The expansion

$, = e - ' JIu jj Z ( II H ]l ! - H)" t"/n ! n>~O

shows that ifS is norm-irreducibie then (ll H II1 - H) is norm-irreducible. Converseiy, if ([[Hill- H)is norm-irreducible, then for each toE~*\{0} and f 6 ~ ' + \ { 0 } one has co(( II H 1[I - H)"f) > 0 for some n I> 0 so to(S,f) > 0. Thus S is strictly positive. This establishes equivalence of the following conditions 1. S is norm-irreducible, 2. S is strictly positive, 3. I]H 1[I - H is norm-irreducible. []

288

CHARLES J. K. BATTY AND DEREK W. ROBINSON

The equivalence of strict positivity and norm-irreducibility extends to a large class of positive Co-semigroups on the classical function spaces. The key features of this extension are the Riesz interpolation p r o p e r t y for the space and an analyticity property of the semigroup. A Co-semigrou p on the Banach space M is holomorphic if for some 0 > 0 there exists an extension of S to a h o l o m o r p h i c family {S z ; z ~ C , larg z[ < 0} of b o u n d e d linear operators on the complexification of ~ such that SzSz2 = Sz, § and

HSza-al[=O

lim z--*O [argzl
for all a e ~ . For example all uniformly continuous Co-semigroups are holomorphic. T H E O R E M 2.5.9. Let (~, ~ + , 11-11) be an ordered Banach space with the Riesz interpolation property for which ~ + is normal and generating. Furthermore, let S be a positive holomorphic semigroup on ~ .

The followin 9 conditions are equivalent: 1. S is strictly positive, 2. S is norm-irreducible, 3. S is norm-ergodic, 4. for each a ~ +\{0} and e ~ * \{0} there is a t > 0 such that o~(S,a)>O. The p r o o f relies upon two lemmas. LEMMA

2.5.10. Let (~, ~ + , [1"[I) be an ordered Banach space with the Riesz inter-

polation property and suppose ~ § is a-monotone and fl-dominating. Suppose a, a e ~ § and E [[a - a, [[ < + oo. Then there exists b e ~ § such that b <. a , n >t 1, and ]la-bl[ ~Zlla-a.

ll.

Proof. There exist c . ~ § such that c > ~ a - a , and IIc.H ~ / 3 1 1 a - a . ll. N o w a - c 1 ~ a 1 , a - c 1 -%
IIb -b211 < llc ll

a ll,

Iteration of this a r g u m e n t gives a sequence b e ~ + such that

b <~b ~ <~a,

b.<~a.,

I l b . - b . _ i l l <~ctfllla-a,l I.

Hence, as n --* oo, b, converges to a limit b with the required properties.

[]

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

289

LEMMA 2.5.11. Let (~, .~ +, ]I'll) be an ordered Banach space with the Riesz interpolation property and suppose ~ + is normal and 9eneratino. Let S be a positive holomorphic semigroup on ~ . l f a e ~ + , t o e S * then either

to(S,a) = 0 for all t > 0

or

co(Sta) > 0 for all t > O.

Proof. Suppose to(Stoa) = 0 for some t o > 0. Let t, be a sequence of positive numbers decreasing to 0 such that Z IIS , a - a 1[ < 0o. By Lemma 2.5.10 there is a sequence ame;~ + such that a,, ~<S , a for m ~ m. Thus the zeros of the analytic function t~--~to(Sta,,) have a limit point at t = t o , so to(St a m) = 0 for all t. Therefore to(S t a) = 0 for all t, by continuity. [] Now the proof of Theorem 2.5.9 is immediate.

Proof of 2.5.9. 1 ~ 4 . This follows from Lemma 2.5.11. 2r r Since 8 h a s the Riesz interpolation property, 8 + has the positive bipolar property by the argument used in Example 2.5.3. The required equivalence then follows from Theorem 2.5.1. [] Under the conditions of Theorem 2.5.9 strict positivity of S is also equivalent to weak*-irreducibility of the adjoint semigroup. This follows from Theorem 2.5.1 because the Riesz interpolation property implies that the dual cone 8 " is w*-sharp. If ( 8 , 8 + , I1"[I) does not have the Riesz interpolation property, the conclusion of Theorem 2.5.9 can fail, see Example 2.5.14 below. E X A M P L E 2.5.12 (LP-spaces) Let ~ = LP(X;d/z), where 1 ~

0 such that f vanishes almost everywhere in E but S t f does not, even if 8 is nonseparable. Now suppose S is a positive holomorphic semigroup on 8 so that the nine conditions of Theorem 2.5.1 are equivalent to strict positivity of S, by Theorem 2.5.9. If f ~ 8 and c o ~ 8 " = Lq(X;d#), where p-1 + q - , = 1 , then f = h l f [ , ~ = k l t o l , for some h, k E L ~ ( X ; d ~ ) with Ihl = Ikl = 1 and

Itol(s, lf I) -- to(kS,(hf)).

290

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Hence, if St is strictly positive, there is no proper closed subspace of ~ which is invariant under both S and the action of multiplication by L ~ (X; do). Conversely, suppose S is not strictly positive, so oo(Stf ) = 0 for some, and hence all, t > 0 and for some f e ~ + \ { 0 } , ~oe~*+ \{0}. But if o~L~(X;dla), then loS,f[ <~ <~IIoII S t f and hence o~(9Stf ) = 0 . Moreover, ISs(oS,f)l <~I[Oll| so that S(9S, f ) = h S + , f for some h~L*(X;dp). Thus the closed linear span of {oS, f; t > O, oEL| dk*)} is a proper subspace invariant under both S and the action of L ~ (X; do). Thus S is strictly positive if, and only if, there are no proper subspaces invariant under S and multiplication by L ~176 (X; do). If ~ = L~ (X; d/~) ordered by the cone of pointwise positive functions in ~ , then any positive Co-semigroup is uniformly continuous, Example 2.2.17, and therefore holomorphic. Thus the nine conditions of Theorem 2.5.1 are equivalent to strict positivity of S (see Example 2.5.8). Irreducibility criteria for Co-semigroups are given by the above discussion of Co-semigroups on the predual L 1(X; do) (see also Example

2.5.5).

[]

Finally we examine analogues of the second part of the Perron-Frobenius theory of positive matrices, the spectral properties of positive irreducible matrices. Frobenius' theorem states that if A is a positive irreducible n x n matrix, there is an ruth root of unity 0, for some m~[1, n], such that 1.

= {p0';1

2. p0" is a simple eigenvalue of A, 1 ~
lfm n + iy~tr(H)then m H + iny~tr(H), n~Y.

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

291

It is not known whether the growth condition on the resolvents can be omitted in this theorem, but it is automatically satisfied if m n = - Ys" These conclusions fail, however, for non-commutative C*-algebras. E X A M P L E 2.5.14. Let ~ be the space of hermitian 2 x 2 matrices and ~ + the cone of positive definite matrices in ~ . Define a positive Co-semigrou p S on by

[]

and a(H) = {0, i, - i}.

For irreducible semigroups on Banach lattices and C*-algebras one can often say something about the peripheral point spectrum. T H E O R E M 2.5.15. Let H be the generator o f a norm-irreducible positive Co-semigroup on a Banach lattice ~ . Suppose that the peripheral point spectrum o f H is nonempty and that m n is an eigenvalue o f H* with a positive eigenvector. It follows that 1. m n is an eigenvalue o f H with an eigenveetor in qu.int .~+, 2. m n is the only eigenvalue o f H with a positive eigenveetor, 3. if m n + iy 1 and m n + iy z are eigenvalues o f H, then m n + i(y 1 - Y2 ) is also an eigenvalue, 4. if m n + iy is an eigenvalue of H, then a(H) + iy = a(H). The condition that m u is an eigenvalue of H* with a positive eigenvector is automatically satisfied if H satisfies the other hypotheses of Theorem 2.5.15 and also satisfies the bound sup (mn - 2)II (2I - H)-

< +

~.

2<m H

T H E O R E M 2.5.16 [36]. Let H be the generator o f a norm-irreducible Co-semigrou p S on the (self-adjoint) part o f a C*-algebra 9I with identity 4. Suppose that s , ( u = 4, S,(a*a) >~St(a)*S,(a),

a~gA, t >~0.

Then statements 2, 3 and 4 o f Theorem 2.5.15 are valid (with m n = 0).

In comparing the last two theorems, note that under the hypotheses of Theorem

292

CHARLES J. K. BATTY AND DEREK W. ROBINSON

2.5.16, ~s = -- mn and m n is an eigenvalue of H* with a positive eigenvector. This follows from T h e o r e m 2.4.4 and 2.4.6.

Appendix: Hahn-Banach Theorems In this appendix, we state the various forms of the H a h n - B a n a c h T h e o r e m used in the preceding review. Let E be a real vector space. A functional p: E ~ ( - ~ , ~ ] is sublinear, if p(2a) = 2p(a),

a c E , 2e11~+,

p(a + b) <~p(a) + p(b),

a, b e E .

T H E O R E M A1. ( H a h n - B a n a c h Theorem). Let p: E ~ ~ be a finite-valued sublinear functional, and ae E. There is a linear functional 09: E ~ R with 09(a) = p(a) and 09(b) <~ <~p(b) for all be E. Furthermore, for c e E and 2e ~, there exists a linear functional 09: E ~ R with 09(a) = p(a), 09(c) = 2, and 09(b) <~p(b) for all b e E if, and only if,

p(a) - p(a - tc) <<.2 <<.p(a + tc) - p(a) t t

t >10.

N o w let pj (1 ~<j ~< n) be sublinear functionals on E, and 09 be a linear functional o n E w i t h 0 9 ~ < p i . If X"i=lai = O, then

~Pi(a,)>~ Z w ( a , ) : o 3 ( ~ . a i ) i=1

i=1

=0.

\i=l

The following is a converse to this. A2 (Multiple H a h n - B a n a c h Theorem). Let Pi : E ~ ( - ~ , ~ ] be sublinear functionals (1 <~i <<.n) with P l finite-valued, and suppose that

THEOREM

a, eE,

~ ai=O=*. ~. p,(a,)>~O. i=I

i=1

Then there is a linear functional 09: E --* ~ with 09 <~Pi, f ~ 1 <~i <~n. Proof. If E~'= t al = a, then Pi(ai) >~pa(al -- a ) - P s ( - a) + Z Pi(ai) >~ i=1

-

-

P l ( - a).

i=2

Thus, if

n p(a) = inf

}

pi(ai); ~ a i = a , i=1

i=1

then p is a finite-valued sublinear functional with - Pl ( - a) <<.p(a) <~pi(a), 1 <~ i ~< n. By T h e o r e m A1, there is a linear functional w with 09 ~

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

293

The H a h n - B a n a c h Separation Theorem appears in several forms, which are summarised in Theorem A3 below. I f 2 is a Banach space, the theorem may be applied either with E = 2 in the norm topology, or with E = 2 " in the weak*-topology so that E* = 2 . Let E be a real locally convex space, and E* be the dual of E. For a subset F of E, let F ~ be the polar o f F in E*, so that F ~ = {co~E*; co(a) ~< 1 for all a e F } . Let F ~176 be the bipolar ofF, that is, the polar o f F ~ in E, so F ~176 = { a c E ; co(a) ~< 1 for all c o e F ~

THEOREM A3 (Hahn-Banach Separation Theorem). Let E be a real locally convex space. (i) Let C be a convex subset of E with non-empty interior int C. For aeE\int C, there exists co ~ E* such that co(a) <<,co(c)for all c e C. (ii) Let C be a closed convex subset of E not containin 9 0 . There exists c o e ~ * such that co(c) >>-l for all c e C . (iii) For any subset F of E, F ~176 is the closed convex hull o f F w {0} in E. N o t e s and R e m a r k s Part I. w The abstract theory of ordered topological vector spaces originated in the 1930s in the work of Kantorovich, M. Krein, F. Riesz and their collaborators. Monographs on the subject include [42, 58, 61, 84], all of which emphasise topological, rather than metric, properties. A close approximation to our approach is adopted in [6], Chapter 2. w A duality between normality and generation was first discovered by Grosberg and Krein [38], who showed 1 o 2 in Theorem 1.1.4. The reverse duality 1 ' o 2 ' (without regard to the constant ~) was proved in [3]; the invariance of a was established in [27]. Extended introductions to the theory of C*algebras (Example 1.1.7) may be found in [11, 60, 81], and to compact convex sets (Example 1.1.8) in [2]. Example 1.1.9 appears in [6]. w Proposition 1.2.1 can be found in [13] - see also [58]. Theorems 1.2.2 and 1.2.3 were proved in [71]. w Theorem 1.3.1 and Proposition 1.3.2 are both mainly due to Davies [16]. There is a detailed discussion of absolute domination and Riesz norms in [84]. Proposition 1.3.2 in its full generality appears in [67]. w Order-unit spaces were introduced by Kadison [43] who subsequently completed the proof of the equivalence 1 r in Theorem 1.4.1 [45] - see also [77]. Base-norm spaces were introduced by Edwards [21] and Ellis [27], and they showed 1 r and 1',:-2' in Theorem 1.4.1. Further details may be found in [2] and [6]. Quasi-interior points in a topological vector lattice were introduced independently by Fullerton [32] and Schaefer [74] using a definition which is equivalent to ours in their context, but differs in general. w A comprehensive account of the theory of Banach lattices may be found in [75]. [31] and [82] consider more general types of vector lattices. Detailed information about AL- and AM-spaces may be found in [75, 18, 78 and 33]. Theorem 1.5.1 was discovered independently by Kakutani [47, 9] and (in part) by M. and S. Krein [51]. A similar result was obtained by Stone [80]. Theorem 1.5.2 is also due to Kakutani [46]. The decomposition and separation properties were introduced by F. Riesz [64, 65], who also proved the implication 1 ~ 2 of Theorem 1.5.4. The converse was obtained by And6 [3]. Choquet simplexes were originally introduced in [14]. A common definition o f a Choquet simplex is a compact convex set K for which AI K}* is a lattice, and this definition together with Theorem 1.5.4 and Theorem 1.4. l reduces Statement 1 of Theorem 1.5.5 to a tautology. But the Choquet-Meyer theorem [15] permits simplexes to be defined

294

CHARLES J. K. BATTY AND DEREK W. ROBINSON

alternatively in terms of uniqueness of representing measures. Many other characterizations of simplexes may be found in [2.6]. Part 1 of Theorem 1.5.5 was obtained independently by Edwards [22], Linderstrauss [53] and Semadeni [77] without reference to Theorem 1.5.4. Effros [24-26] studied in detail 'simplex spaces', those ordered Banach spaces whose duals are AL-spaces. w Half-norms were explicitly introduced by Arendt et al. [4], but the canonical half-norm, defined as in Proposition 1.6.2, was used by Calvert [13] to prove a version of Theorem 2.2.4. Half-norms have been studied in detail by Robinson and Yamamuro [69 71, 85]. Proposition 1 6 2 and Theorem 1.6.3 originated in [71]. ~1.7. An account of the ordgr properties of continuous linear mappings between ordered topological vector spaces is given in [61]. They were first studied by Kantorovich, who showed that Lr ~ ) is a lattice if .~t+ is normal, generating and has the Riesz separation property and ~ is an order-complete topological vector lattice [48]. For positive operators, Proposition 1.7.2 was stated by Nachbin [56] see also [58, 75] ; for order-bounded operators, it appeared in [10]. Theorem 1,7.3 was proved in an abstract form in [73], and in this form in [10], Corollary 1.7.5 appears in [85]. The notion of positive attainment was introduced by Robinson, and Proposition 1.7.8 arises from [66 67]. Another sufficient condition (of LP-type) for positive attainment has been given by Yamamuro [85]. Part 2. w There are numerous books on one-parameter semigroups of operators, for example [I2, 17, 40], The Hille-Yosida theorem was proved in 1948 and the Feller-Miyadera-Phillips theorem in 1952, and both are named after their originators who worked independently. Original references are given in the books mentioned above. w In the case when p = I1"II, the equivalence 2 o 3 of Theorem 2.1.1 was proved in [7]; in the more general form, it appeared in [4]. The history of the equivalence 1 .=-2 is obscure. Norm-dissipative operators were introduced by Lumer and Phillips [54], who proved Theorem 2.1.3 for p = I1"II- The general version of Theorem 2.1.3, as well as Proposition 2.1.4, were given in [4]. Dispersive operators on Banach lattices were introduced by Phillips [62] see also [39, 72]. The negative off-diagonal property as a criterion for positivity of uniformly continuous semigroups was discussed by Evans and Hanche-Olsen [29]. A version of Corollary 2.1.5 occurs in [ 4 ] w Theorem 2.2.1 originated in [66], where it was stated for Riesz norms (Corollary 2.2.3). Theorem 2.2.4 was proved in [67]~ Theorem Z2.7 was proved in [4], and was further discussed in [10], which also included Proposition 2.2.9 and Example 2.2.i0. An example similar to 2.Zli, but on the 8anach space C0(~ ), was given in [8]. The algebraic characterization of bounded positive generators on C*-algebras given in Example 2.2.16 is due to Evans and Hanche-Olsen [29]. The absence of positive C0-semigroups on L| d#)(Example 2.2.17) was discovered by Kishimoto and Robinson [50]. w Theorems 2.3.1 (for Riesz norms) and 2.3.2 appeared in [64] and [65], respectively. Proposition 2.3.3, Theorem 2.3.4 and Example 2.36 were all given in [10]. The ideas underlying Example 2.3.7 are discussed in detail in [11]. w The Perron-Frobenius theory of matrices is summarized in [75], and is included in many books on matrices. Part 2 of Lemma 2.4.1 is due to Greiner et al. [35], who also proved Theorem 2.4.2 and Corollary 2.4.3. Derndinger [19] proved Theorem 2.4.4 for C0-semigroups on AL-spaces and AM-spaces with unit, and the Co-version of Corollary 2.4.5 appeared in [8]. Theorem 2.4.6 is a semigroup version of a celebrated result of Krein and Rutman [52]. This version and Corollary 2.4.7 (for C*-algebras with identity), as well as Example 24.9, appeared in [37]. The phenomenon of Example 2.4.8 was exhibited in [35]. Further discussion of the equality Ys = - m n may.be found in [57]. w The general relationship between irreducibility, strict positivity and the positive bipolar property, was discussed in [10]. The latter property is related to Kadison's notion of 'Archimedean' order ideals [43] see also [2, 70]. Irreducibility had previously been considered separately for Banach lattices [75] and for C*-algebras [28]. Example 2,5,6 originated in [5]. Theorem 2.5.9 is the end of a chain of results through [79, 49, 55]. The criterion for strict positivity given in Example 2.5.12 developed from the case of self-adjoint semigroups on L2(X; d/t) (see [49, 63] and the references cited therein) to its present form in [50]. Schaefer [76] has surveyed the theory of positive semigroups on Banach lattices up to 1980. Theorems 25.13 and 2.5.15 are analogues (due to Greiner) of older results for single operators [75]. Further spectral information may be found in [19, 20, 34, 35]. Theorem 2.5.16 is a semigroup version of a result in [36], which itself extended a finite-dimensional result in [20]. Another theorem of Perron-Frobenius type for operator algebras may be found in [1],

POSITIVE ONE-PARAMETER SEMIGROUPS ON ORDERED BANACH SPACES

295

References 1. 2. 3. 4. 5. 6.

Albeverio, S. and H~egh-Krohn, R. : Commun. Math. Phys. 64 (1978), 83 94. Alfsen, E. M. : Compact Convex Sets and Boundary Integrals, Springer-Verlag, Berlin, 1971. And6, T. :Pacif. J. Math. 12 (1962), 1163-1169. Arendt, W., Chernoff, P. R. and Kato, T.: J. Operator Theory 8 (1982), 167-180. Asimow, L. : Pacif. J. Math. 35 (1970), 11 21. Asimow, L. and Ellis, A. J. : Convexity Theory and Its Applications in Functional Analysis, Academic Press, London, 1980. 7. Batty, C. J. K.: J. Lond. Math. Soc. 18 (1978), 527-533. 8. Batty, C. J. K. and Davies, E. B.: 'Positive semigroups and resolvents'. J. Operator Theory 10 (1983), 357-363. 9. Bohnenblust, F. and Kakutani, S. : Ann. o]'Math. 42 (1941), 1025-1028. 10. Bratteli, O., Digernes, T. and Robinson, D. W.: J. Operator Theory 9 (1983), 371~100. I 1. Bratteli, O. and Robinson, D. W.: Operator Algebras and Quantum Statistical Mechanics, vol. I, Springer-Verlag, Berlin, 1979. 12~ Butzer, P. L. and Berens, H.: Semigroups of Operators and Approximation, Springer-Verlag, Berlin, 1967. 13. Calvert, B. D. : J. Math. Soc. Japan, 23 ( 1971 ), 311 - 319. 14. Choquet, G.: "Existence des representations int6grales au moyen des points extr6maux dans les c6nes convexes', Sere. Bourbaki, 139 (1956). 15. Choquet, G. and Meyer, P. A. : Ann. Inst. Fourier (Grenoble), 13 (1963), 139-154. 16. Davies, E. B.: Trans. Amer. Math. Soc. 131 (1968), 544-555. 17. Davies, E. B.: One-parameter Semigroups, Academic Press, London, 1980. 18. Day, M. M. : Normed Linear Spaces, Springer-Verlag, Berlin, 1973. 19. Derndinger, R.: Math. Z. 172 (1980), 281-293. 20. Derndinger, R. and Nagel, R. : Math. Ann. 245 (1979), 159-177. 21. Edwards, D. A. : Proc. Lond. Math. Soc. 14 (1964), 399-414. 22. Edwards, D. A.: C.R. Acad. Sci. Paris, 261 (1965), 2798-2800. 23. Effros, E. G. : Duke Math. J. 30 (1963), 391-412. 24. Effros, E. G. : Acta Math. 117 (1967), 103-121. 25. Effros, E. G.: J. Funct. Anal. 1 (1967), 361 391. 26. Effros, E. G. and Gleit, A.: Trans. Amer. Math. Soc. 142 (1969), 355-379. 27. Ellis, A. J. : J. Lond. Math. Soc. 39 (1964), 730 744. 28. Enomoto, M. and Watatani, S.: Math. Japon. 24(1979), 53 63. 29. Evans, D. E. and Hanche-Olsen, H.: J. Funct. Anal. 32 (1979), 207-212. 30. Evans, D. E. and Heegh-Krohn, R.: J. Lond. Math. Soc. 17 (1978), 345-355. 31. Fremlin, D. H : Topological Riesz Spaces and Measure Theory, Cambridge University Press, Cambridge, 1974. 32. Fullerton, R. E.: Quasi-interior Points of Cones in a Linear Space, ASTIA Doc. No. AD-120406 (1957). 33. Goullet de Rugy, A. : J. Math. Pures Appl. 51 (1972), 331-373. 34. Greiner, G. : Math. Z. 177 (1981), 401-423. 35. Greiner, G., Voigt, J. and Wolff, M. : J. Operator Theory, 5 (1981), 245-256. 36. Groh, U.: Math. Z. 176(1981), 311-318. 37. Groh, U. and Neubrander, F. : Math. Ann. 256 (1981), 509-516. 38. Grosberg, J. and Krein, M. G.: C.R. DokL Acad. Sci. URSS, 25 (1939), 723-726. 39. Hasegawa, M. : J. Math. Soc. Japan, 15 (1966), 290-302. 40. Hille, E. and Phillips, R. S.: Amer. Math. Soc. Coll. Publ. 31 (1957), Providence, R. I. 41. Holmes, R. B. : Geometric Functional Analysis and Its Applications, Springer-Verlag, Berlin, 1975. 42. Jameson, G. J. O. : "Ordered linear spaces', Lecture Notes in Math., vol. 141, Springer-Verlag, Berlin, 1970. 43. Kadison, R. V. : Mere. Amer. Math. Soc. 7 (1951). 44. Kadison, R. V. : Ann. of Math. 56 (1952), 494-503. 45. Kadison, R. V. : Topology, 3 (1965), 177-198.

296 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. 81. 82. 83. 84. 85. 86.

CHARLES J. K. BATTY AND DEREK W. ROBINSON

Kakutani, S.: Ann. of Math. 42 (1941), 523-537. Kakutani, S.: Ann. of Math. 42 (1941), 994-1024. Kantorovich, L. V. : Dokl. Akad. Nauk. SSSR, 1 (1936), 271-276. Kishimoto, A. and Robinson, D. W.: Commun. Math. Phys. 75 (1980), 85-101. Kishimoto, A. and Robinson, D. W.: J. Austral. Math. Soc. (Series A), 31 (1981), 59-76. Krein, M. G. and Krein, S. : C.R. Dokl. Acad. Sci. URSS, 27 (1940), 427-430. Krein, M. G. and Rutman, M. A.: U~peki Mat. Nauk. 3 (1948), 3-95; Amer. Math. Soc. Transl. 10 (1950), 199-325. Lindenstrauss, J., Mere. Amer. Math. Soc. 48 (1964). Lumer, G. and Phillips, R. S.: Pacif. J. Math. 11 (1961), 697-698. Majewski, A. and Robinson, D. W.: 'Strictly positive and strongly positive semigroups', J. Austral. Math. Soc. (Series B). (To appear). Nachbin, L. : Proc. International Congress of Mathematicians 1950, vol. I, Amer, Math. Soc., Providence, R. I., 1952, pp. 464-465. Nagel, R.: 'Zur Characterisierung stabiler Operatorhalbgruppen', Semesterbericht Funktionanalysis, Tiibingen, 1981/82, pp. 99-119. Namioka, I.: Mere. Amer. Math. Soc. 24 (1957). Ogasawara, T.: J. Sci. Hiroshima Univ. 18 (1955), 307 309. Pedersen, G. K.: C*-algebras and their Automorphism Groups, Academic Press, London, 1979. Peressini, A. L. : Ordered Topological Vector Spaces, Harper and Row, New York, 1967. Phillips, R. S. : Czech. Math. J. 12 (1962), 294-313. Reed, M. and Simon, B. : Methods of Modern Mathematical Physics IV: Analysis of Operators, Academic Press, New York, 1978. Riesz, F. : Atti. det Congresso Bologna, 3 (1928), 143-148. Riesz, F.: Ann. Of Math. 41 (1940), 174-206. Robinson, D. W.: 'Continuous semigroups on ordered Banach spaces', J. Funct. Anal. (To appear). Robinson, D. W. : 'On Positive Semigroups', Publ. RIMS, Kyoto. Univ. (To appear). Robinson, D. W. and Yamamuro, S. : J. Austral. Math. Soc., Series A Robinson, D. W. and Yamamuro, S.: 'The Jordan decomposition and half-norms', Pac. J. Math. 110 (1984), 345 353. Robinson, D. W. and Yamamuro, S. : 'Hereditary cones, order ideals and half-norms', Pac. J. Math. 110 (1984), 335 343. Robinson, D. W. and Yamamuro, S.: 'The canonical half-norms and monotonic norms', T6hoku Math. J. 35 (1983), 375-386. Sato, K. J. Math. Soc. Japan, 20 (1968), 423-436. Schaefer H. H.: Math. Ann. 138(1959), 259-286. Schaefer H. H.: Math. Ann. 141 (I960), 113 142. Schaefer H. H.: Banach Lattices and Positive Operators, Springer-Verlag, Berlin, 1974. Schaefer H. H. : Jber. Dr. Math. Ver. 82 (1980), 33-50. Semadeni Z.: Bull. Acad. Sci. Pol. 13 (1965), 141 146. Semadeni Z. : Banach spaces of continuous functions, Polish Scientific Publ. Warsaw. 1971. Simon, B. J. Funct. Anal. 12 (1973), 335-339. Stone, M. H.: Proc. Nat. Acad. Sci. USA, 27 (1941), 83-87. Takesaki, M. : Theory of Operator Algebras I, Springer-Verlag, Berlin, 1979. Vulikh, B. C. : Introduction to the Theory of Partially Ordered Spaces, Wolters-Noordhoff, Groningen, 1967. Widder, D. V.: The Laplace Transform, Princeton Univ. Press, Princeton, NJ, 1946. Wong, Y. C. and Ng, K. F. : Partially Ordered Topological Vector Spaces, Clarendon Press, Oxford, 1973. Yamamuro, S.: ~Onlinear operators on ordered Banachspaces',Preprint, 1982. Zabczyk, J. : Bull. Acad. Pol. Sci. 23 (1975), 895-898.