Dec 25, 1979 - if and only if $\mathfrak{a}$ is $\alpha$ -simple (i.e. $\mathfrak{a}$ does not have any non-trivial a-invariant ideals) and $\tilde{\Gamma}(\alpha ...
YOKOHAMA MATHEMATICAL JOURNAL VOL. 28, 1980
SIMPLE CROSSED PRODUCTS OF -ALGEBRAS BY LOCALLY COMPACT ABELIAN GROUPS $C^{*}$
By
AKITAKA KISHIMOTO (Received Dec. 25, 1979)
ABSTRACT: We introduce a new invariant , a closed subsemigroup of the dual of , of a $c*$ -dynamical system where is a -algebra, and is a locally compact abelian group with an action on . We show that the crossed product $a\times.G$ is simple $\tilde{\Gamma}(\alpha)$
$G$
$(\mathfrak{a}, G, \alpha)$
$\alpha$
$\mathfrak{a}$
$C^{*}$
$G$
$\mathfrak{a}$
if and only if is -simple (i.e. does not have any non-trivial a-invariant ideals) and equals the dual of $G$ . We discuss some cases where coincides with the Connes spectrum . Finally we give examples of simple crossed products of Cuntz algebras by locally compact abelian groups. $\mathfrak{a}$
$\alpha$
$\tilde{\Gamma}(\alpha)$
$\mathfrak{a}$
$\tilde{\Gamma}(\alpha)$
$\Gamma(\alpha)$
\S 1. Introduction In a paper [7] by D. Olesen and G. K. Pedersen the Connes spectrum [6] of a -dynamical system , with a locally compact abelian group $G$ , plays an important role in characterizing primeness of the crossed product . We introduoe a new invariant , which is a closed subsemigroup of , and show that is relevant in characterizing simplicity of . After being introduced, our results and methods are quite similar to the prime case above-mentioned. By using a characterization of in terms of ideals of the crossed product and the dual action on it, we show that coincides with in some cases, in particular, when is discrete and a is -simple. Unfortunately seems to be hard to compute, at least, directly from its definition. Hence our examples of simple crossed products could be given independently of the above-mentioned general theory. We show that the crossed product of a Cuntz algebra $O_{n}[3]$ by a so-called quasi-free automorphism group [4] corresponding to a unitary representation , on the n-dimensional Hilbert space, of a locally compact abelian group , is simple if and only if the closed subsemigroup generated by Sp and $-p$ equals the dual of , for any $p\in Spu$ if $ n\neq e_{1}$
$e(\Omega_{1})$
$q$
$\Omega_{1}$
$[\pi(\mathfrak{a})e(\Omega_{1})\ovalbox{\tt\small REJECT}_{\pi}]=\ovalbox{\tt\small REJECT}_{\pi}$
sinoe the projection onto the left hand side is in
$\pi(\mathfrak{a})^{\prime}\cap u(G)^{\prime}$
.
Since
$e[\pi(\mathfrak{a})e(\Omega_{1})\ovalbox{\tt\small REJECT}_{\pi}]=[\pi(B)e(\Omega_{1})\ovalbox{\tt\small REJECT}_{\pi}]$
$[\pi(B^{\alpha}(\Omega))e(\Omega_{1})\ovalbox{\tt\small REJECT}_{\pi}]=(0)$
for any compact neighbourhood
$\Omega_{1}$
of , we can easily conclude that Sp ue$ $p+q$ . $q$
$q.e.d$
.
Remark 2.3. The intersection over the covariant representations can be restricted to the irreducible covariant representations $(\pi, u)$ , i.e. the ones with , in the above proposition. $\pi(a)^{\prime}\cap$
$u(G)^{\prime}=C\cdot 1$
, it follows easily that Remark 2.4. If is not simple (c.f. [9]). We may consider the invariant in von Neumann algebra case corresponding $F$ to , but it turns out to be the Connes spectrum. Hence $F$ can be considered as another version of the Connes spectrum (originally defined for von Neumann $ F(\alpha)\neq\Gamma$
algebras).
$\mathfrak{a}\times_{\alpha}G$
AKITAKA KISHIMOTO
72
\S 3. Simple crossed products -dynamical system with a locally compact abelian group Let be a $G$ . Let $K\equiv C(L^{2}(G))$ be the algebra of all compact operators on $L^{2}(G)$ and the regular representation of on $L^{2}(G)$ . Let and an action of $C^{*}$
$(\mathfrak{a}, G, \alpha)$
$\lambda$
$G$
$\tilde{\alpha}=\alpha\otimes Ad\lambda$
$\tilde{\mathfrak{a}}=\mathfrak{a}\otimes K$
on .
$G$
$\tilde{\mathfrak{a}}$
Lemma 3.1.
$F(\tilde{\alpha})=\tilde{\Gamma}(\alpha)$
.
. Then there are a covariant representation $(\pi, u)$ Proof. Suppose and such that Sp $ue\ni O$ and Sp (the where is the identity of $ue\ni O$ assumption Sp is always achieved by multiplying by some character of ). We construct a covariant representation of by simply tensoring $K,$ , Ad ), e.g. the identity representation of ( $p\not\in F(\alpha)$
$B\in\ovalbox{\tt\small REJECT}^{\alpha}(\mathfrak{a})$
$ue\Rightarrow p$
$\overline{\pi(B})^{w}$
$e$
$G$
$u$
$(\tilde{\pi},\tilde{u})$
$G$
$(\tilde{\mathfrak{a}}, G,\tilde{\alpha})$
$\lambda$
$\tilde{u}(t)=u(t)\otimes\lambda(t)$
,
.
$t\in G$
Let be a compact neighbourhood of such that $p-\Omega\subset(Spue)^{c}$ and let be the spectral projection of corresponding to . Set $D=e_{1}Ke_{1}$ . Then is the identity of and and . We have that Sp since $0$
$\Omega$
$e_{1}$
$\ovalbox{\tt\small REJECT}^{Ad\lambda}(K)$
$ D\in$
$\Omega$
$\lambda$
$B\otimes D\in\ovalbox{\tt\small REJECT}^{\delta}(\tilde{\mathfrak{a}})$
$\overline{\tilde{\pi}(B\otimes D})^{w}$
$e\otimes e_{1}$
$\tilde{u}\cdot(e\otimes e_{1})Sp$
Sp $\tilde{u}\cdot(e\otimes e_{1})\subset Spue+Sp\lambda e_{1}=Spue+\Omega$ . , we can conclude that Sinoe Sp . Suppose . Then there are a covariant representation $(\pi, u)$ of and such that Sp $ue\ni O$ and Sp where is the identity of . $B\supset C^{*}(G)BC^{*}(G)$ , where First we assert that can be chosen to satisfy that $C^{*}(G)$ is identified with in . Set $\tilde{\Gamma}(\tilde{\alpha})Sp$
$\tilde{u}\cdot(e\otimes e_{1})\ni 0$
$p\not\in F(\tilde{\alpha})$
$(\tilde{\mathfrak{a}}, G,\tilde{\alpha})$
$ue\Rightarrow p$
$B\in\ovalbox{\tt\small REJECT}^{\partial}(\tilde{a})$
$\overline{\pi(B})^{w}$
$e$
$B$
$1\otimes C^{*}(G)$
$L=$
where $B$
.
{
$x\in\tilde{\mathfrak{a}}:\pi(x)u(f)=0;\forall f\in L^{1}(G)$
$u(f)=\int f(t)u(t)dt$
Since
$M(\tilde{\mathfrak{a}})$
,
supp $ f\cap Spue=\phi$ },
. Then is an -invariant closed left ideal of containing , we have that . Set . Then $L$
$\tilde{\alpha}$
$\tilde{\mathfrak{a}}$
$LC^{*}(G)\subset L$
$\overline{\pi}(C^{*}(G))\subset u(G)^{\prime}$
$B_{1}=L\cap L^{*}$
satisfies the above assertion. Now we assume that $B\supset C^{*}(G)BC^{*}(G)$ . Hence . Let be a compact neighbourhood of such that $p+\Omega-\Omega\subset(Spue)^{c}$ . Let $e(q)$ be the spectral , in particular projection of $\lambdarresponding$ to . Since the supremum of e$(q),$ is l, $thereisq_{0}\in\Gamma satisfyingSpue\overline{\pi}(e(q_{0}))\ni 0$ . Let and now we restrict the representation to with the representation space . $B_{1}\in\ovalbox{\tt\small REJECT}^{\partial}(\tilde{\mathfrak{a}})$
and
$B_{1}$
$e\in\overline{\pi}(C^{*}(G))^{\prime}$
$\Omega$
$0$
$ q-\Omega$
$q\in\Gamma,$
$e(q)\in M(\tilde{\mathfrak{a}})$
$inM(\tilde{\mathfrak{a}})$
$D=e(q_{0})Ke(q_{0})\in\ovalbox{\tt\small REJECT}^{Ad\lambda}(K)$
$\mathfrak{a}\otimes D\in\ovalbox{\tt\small REJECT}^{\partial}(\tilde{\mathfrak{a}})$
$ e(q_{0})\tilde{\mathfrak{a}}e(q_{0})\simeq$
$\mathcal{K}\equiv\overline{\pi}(e(q_{0}))\ovalbox{\tt\small REJECT}_{\pi}$
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
-ALGEBRAS
We define the following unitary representation \^u on
\^u(t)=u Then \^u commutes with
Sp
$\overline{\pi}(D)$
$(t)\overline{\pi}(\lambda(-t))\langle t, q_{0}\rangle$
, Ad
$\hat{\text{{\it \^{u}}}}e\cap\Omega\neq\phi$
,
$\mathcal{K}$
$t\in G$
for
$\hat{\text{{\it \^{u}}}}(t)(\overline{\pi}(a))=\overline{\pi}\circ\alpha_{t}(a)$
73
:
.
$a\in \mathfrak{a}$
, and
,
Sp $\theta e\subset Spue-Sp\lambda e(q_{0})+q_{0}\subset Spue+\Omega\subset(p+\Omega)^{c}$ .
Set $L=$
{
$x\in \mathfrak{a}\otimes D:$
\mbox{\boldmath $\pi$}(x)\^u(f)=0,
$\forall f\in L^{1}$
supp
,
$ f\subset p+\Omega$
}
Then is an containing $e(q_{0})Be(q_{0})$ . .-invariant closed left ideal of Further $LD\subset L$ . Hence is of the form is an -invariant closed where left ideal of . Set , and let . Then Sp be the identity of , i.e. and Sp . Thus . for Now we consider the dual system and characterize $G(a)$ , similarly to Lemma 3.2 in [7]; $L$
$\alpha\otimes id$
$\mathfrak{a}\otimes D$
$L$
$L_{1}\otimes D$
$B_{1}=L_{1}\cap L_{1}^{*}$
$\mathfrak{a}$
$(p+\Omega)^{c}$
$L_{1}$
$\overline{\pi}(B_{1})$
$e_{1}$
$\text{{\it \^{u}}} e_{1}\cap\Omega\neq\phi$
$\alpha$
$ a_{e_{1}}\subset$
$p\not\in F(\alpha)$
$ q\in Sp\theta e_{1}\cap\Omega$
$p\not\in Sp\text{{\it \^{u}}} e_{1}-q$
$(\mathfrak{a}\times_{\alpha}G, \Gamma, \theta)$
Lemma 3.2. $G(\theta)=$
Proof. Let
$(\Omega_{\iota})$
{
$t\in G:\alpha_{t}(I)\subset I$
for any ideal
$I$
of }. $\mathfrak{a}$
Let be an ideal of and let $t\in G$ . Suppose that be a net of compact neighbourhoods of such that $I$
$\alpha_{t}(I)\zeta I$
$\mathfrak{a}$
$0$
$I_{\Omega}=\bigcap_{se\Omega}\alpha_{s}(I)$
We assert that elements and $e_{n}$
$\cap\Omega_{\iota}=(0)$
.
Let
.
is dense in . For let $x\in I$ be positive and find positive in the -subalgebra generated by such that $I$
$\bigcup_{\iota}I_{\Omega}$
$x_{n}$
.
$C^{*}$
$x$
$e_{n}x_{n}=x_{n}$
,
$\Vert x-x_{n}\Vert\leq 1/n$
.
Then by Lemma 3.2 in [7] there is . Thus such that for . Hence the closure of contains . Suppose that is also dense in for any . Since , a contradiction. Thus there is such that this would imply that $\alpha_{s}(x_{n})\in I$
$\Omega_{\iota}$
$I_{\Omega\iota}$
$ x_{n}\in$
$x$
$\bigcup_{\iota}I_{\Omega}$
$I_{\Omega-\Omega}\subset\alpha_{-t}(I_{\Omega})$
$\cup I_{\Omega-\Omega}$
$\ell$
$I\subset\alpha_{-t}(I)$
$\propto\alpha_{-t}(I_{\Omega})$
$s\in-\Omega_{\iota}$
$I$
,
$I_{\Omega-\Omega}$
$t$
.
Let contained in
$J=I_{\Omega_{\ell}-\Omega}$
$I_{\Omega}$
,
. Then since the ideal
$V_{s\in\Omega\iota}\alpha_{s}(J)$
we have that $J\not\subset_{s\in}v_{\Omega}\alpha_{s-\ell}(J)$
.
generated by
$\alpha_{s}(J)$
,
se
$\Omega_{\iota}$
is
74
AKITAKA KISHIMOTO
Let linear span of
and let
$B=\overline{J\cdot \mathfrak{a}\times_{\alpha}G\cdot J}\in\ovalbox{\tt\small REJECT}^{\hat{\alpha}}(\mathfrak{a}\times_{\alpha}G)$
$x\lambda(f)y$
,
$x,$
$y\in J$
,
$\Omega=\Omega_{\iota}$
.
Then
supp
with
$f\in L^{1}\cap L^{2}$
$B^{\theta}(t-\Omega)$
is the closed
.
$ f\subset t-\Omega$
Hence the $hereditary*$ -algebra generated by elements of the form is dense in $B(t-\Omega)$ . is -integrable, i.e. there is a positive $I(a)$ in (in fact in ) such that
$y^{*}\lambda(f)^{*}x^{*}x\lambda(f)y$
$a\equiv y^{*}\lambda(f)^{*}x^{*}x\lambda(f)y$
$\theta$
$M(\mathfrak{a}\times_{\alpha}G)$
$\mathfrak{a}\subset M(\mathfrak{a}\times_{\alpha}G)$
$\phi(I(a))=\int_{\Gamma}\phi(\theta_{p}(a))dp$
for every
$\phi\in(\mathfrak{a}\times_{\alpha}G)^{*}$
.
Explicitly
$ I(a)=\int|f(s)|^{2}y^{*}\alpha_{-s}(x^{*}x)yds\in J\cdot V\alpha_{s-t}(J)\equiv J_{1}s\in\Omega$
Since $B(t-\Omega)$ is -invariant, it follows that $I(a)\in B(t-\Omega)^{**}$ . Hence the hereditary -algebra generated by elements of the form $I(a)$ is contained in $B(t-\Omega)$ and of course is dense in $B(t-\Omega)$ . Hence $\theta$
$*$
$B(t-\Omega)\subset J_{1}\cdot \mathfrak{a}x_{\alpha}G\cdot J_{1}$
.
$B(t-\Omega)\neq B$ , i.e. Since . $G(a)$ Suppose that dg . Then there are a covariant representation $(\pi, u)$ of and such that Sp $ue\ni O$ and Sp $ue\geq t$ where is the identity of . Let be a compact neighbourhood of $O\in G$ such that . Then for any $x\in B$ and , $t\not\in G(\theta)$
$J_{1}\subset\neq J,$
$t$
$(\mathfrak{a}\times_{\alpha}G, \Gamma, \theta)$
$B\in\ovalbox{\tt\small REJECT}^{\theta}(\mathfrak{a}\times_{\alpha}G)$
$\overline{\pi(B)}^{w}$
$e$
$\Omega$
$ t+\Omega-\Omega$
$\subset(Spue)^{c}$
$ s\in\Omega$
$\pi(x)\overline{\pi}(\lambda(s))u(f)=0$
,
Let be the left ideal of with lation, the left ideal generated by $L$
with
$f\in L^{1}(\Gamma)$
$\mathfrak{a}\times_{\alpha}G$
$B=L\cap L^{*}$
$suppf\subset t+\Omega$
.
. Then from the
above calcu-
$L_{1}$
$\cup L\lambda(f),$
satisfies that for
$x\in L_{1}$
$f\in L^{1}(G)$
supp
with
$ f\subset\Omega$
,
,
$\pi(x)u(f)=0,$
Set and Sp . positive The cone of
$B_{1}=L_{1}\cap L_{1}^{*}\in\ovalbox{\tt\small REJECT}^{\theta}(\mathfrak{a}\times_{\alpha}G)$
$f\in L^{1}(\Gamma)$
and let
$e_{1}$
with supp
$ f\subset t+\Omega$
be the identity of
.
$\overline{\pi(B_{1})}^{w}$
$(*)$
.
Then Sp
$ue_{1}\ni 0$
$ue_{1}\ni t$
$a=\lambda(f)^{*}x^{*}x\lambda(f),$
$x\in B,$
ated by elements
$I(a)$
$B_{1}$
has a total set of -integrable elements of the form with supp . Let be the ideal of gener$\theta$
$f\in L^{1}\cap L^{2}$
with all such
$ f\subset\Omega$
$a$
.
Then
$J$
$B_{1}\subset\overline{J\cdot \mathfrak{a}\times_{\alpha}G\cdot J}$
$\mathfrak{a}$
. Sinoe
$\overline{J\cdot \mathfrak{a}\times_{l}G\cdot J}$
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
-ALGEBRAS
75
is generated by elements of the form $x_{1}I(a_{1})yI(a_{2})x_{2}$ with since $I(a_{1})yI(a_{2})\in B_{1}$ , we have that G. Set . Then satisfies $(*)$ sinoe mutes with . Henoe there is a compact neighbourhood of such that $x_{i}\in \mathfrak{a},$
$y\in \mathfrak{a}\times_{\alpha}G$
and
$J=\overline{JB_{1}J.}$
$\overline{J\cdot \mathfrak{a}\times_{\alpha}}$
$B_{2}=\overline{J\cdot \mathfrak{a}\times_{\alpha}G\cdot J}\in\ovalbox{\tt\small REJECT}^{\&}(\mathfrak{a}\times_{\alpha}G)$
$x\in B_{2}$
$\overline{\pi}(\mathfrak{a})$
$u(\Gamma)$
$\neq B_{2}$
$t$
$\Omega_{1}$
com-
$B_{2}(\Omega_{1})$
.
Since
is the closed linear span of
$B_{1}^{\text{{\it \^{a}}}}(\Omega_{1})$
$x\lambda(f)y,$
$x,$
$y\in J,$ $f\in L^{1}\cap L^{2}$
similarly to the first part of the proof, ated by elements of the form
$B_{2}(\Omega_{1})$
supp
with
,
$f\subset\Omega_{1}$
is the hereditary
$I(y^{*}\lambda(f)^{*}x^{*}x\lambda(f)y)=\int|f(s)|^{2}y^{*}\alpha_{-s}(x^{*}x)yds$
$C^{*}$
-subalgebra gener-
.
$q.e.d$ . Henoe , which implies that . G. Here we give a comment. Our referenoe on -integrability[2.4, 7] contains an error in the definition of . The correct form should be the one given in the above proof (otherwise Lemma 2.6 in [7] would fail), i.e. $a\in M(B)_{+}$ is -integrable if there is a (neoessarily unique) $I(a)\in M(B)$ such that $\alpha_{-t}(J)J$
$B_{2}(\Omega_{1})\supset\alpha_{-t}(J)J\cdot \mathfrak{a}\times_{a}$
$J\zeta\alpha_{-t}(J)$
$\theta$
$I$
$\beta$
$\phi(I(a))=\int_{\Gamma}\phi\circ\beta_{p}(a)dp$
, where for every is conand $\beta=a$ in this case. Here tinuous. To prove that the -integrable elements are hereditary, we adopt an argument similar to the one in [2.4, 7] by using, e.g., Lemma 2.1 in [1], although this fact is not quite necessary in the above proof, because we have considered only elements of (or ) as integrable elethe form if $a_{p}(y)=y,$ ments, which is justified by Proposition 2.8 in [7]. $\phi\in B^{*}$
$p\rightarrow\phi\circ\beta_{p}(a)$
$B=\mathfrak{a}\times_{\alpha}\backslash G$
$\beta$
$y^{*}\lambda(f)^{*}x^{*}x\lambda(f)y$
$\lambda(f)^{*}x^{*}x\lambda(f)$
Lemma 3.3 [10]. The isomorphic to .
$C^{*}$
$ p\in\Gamma$
-dynamical system
$(\mathfrak{a}\times_{\alpha}G\times a^{\Gamma}’ G,\hat{\theta})$
is covariantly
$(\tilde{\mathfrak{a}}, G,\tilde{\alpha})$
Lemma 3.4. $F(\alpha)=$
{
$p\in\Gamma:\theta_{p}(I)\subset I$
for any ideal
$I$
of
$\mathfrak{a}\times_{\alpha}G$
}
Proof. $ItfollowsfromLemmas3.2and3.3$ . By the above lemma and Lemma 3.1 in [7] we have Theorem3.5.
lent:
Let
$(\mathfrak{a}, G, \alpha)$
be as above.
Thefollowing conditions are equiva-
AKITAKA KISHIMOTO
76
is simple; is -simple and . As a corollary to Lemma 3.4 we give
(i) (ii)
$\mathfrak{a}\times_{\alpha}G$
$\mathfrak{a}$
$ F(\alpha)=\Gamma$
$\alpha$
Proposition 3.6. Let be as above. Suppose that there is another $C^{*}- dynamic\dot{a}l$ system $(B, G, \beta)$ which is exteriorly equivalent to $(a, G, \alpha)$ . Then $(\mathfrak{a}, G, \alpha)$
.
$F(\alpha)=F(\beta)$
Proof.
$(\mathfrak{a}\times_{\alpha}G, \Gamma, a)$
is covariantly isomorphic to
$(B\times\beta G, \Gamma,\hat{\beta})$
.
It seems more difficult to compute than in most of cases. times coincides with . We shall show some of these cases. The following lemma can be found, e.g. in [11, Lemma 22]: $F(\alpha)$
$F(\alpha)$
$\Gamma(\alpha)$
$q.e.d$
.
But some-
$\Gamma(\alpha)$
Lemma 3.7. Suppose that primitive ideal I of , where
is
$a$
$\alpha$
-simple and that
$G/G_{I}$
is compact
for any
$\mathfrak{a}$
$G_{I}=\{t\in G:\alpha_{t}(I)=I\}$
.
Then the primitive ideal space of with the transposed action of is isomorphic to $G/G_{0}$ with the action of by translations, where $G_{0}=G_{I}$ for any primitive ideal . $G$
$\mathfrak{a}$
$G$
$I$
Proof. Let be a primitive ideal, and let hoods of $0\in G/G_{I}$ such that . Sinoe same image in $G/G_{I}$ , we can define $I$
be a net of compact neighbourif and in have the
$(\Omega_{\iota})$
$\cap\Omega_{\iota}=(0)$
$\alpha_{t}(I)=\alpha_{s}(I)$
$t$
$G$
$s$
$f=\dot{s}$
.
$I(f+\Omega_{\iota})=\bigcap_{S\in\Omega}\alpha_{\ell+s}(I)$
There is a finite set
$S_{\iota}$
of
$G/G_{I}$
such that
$\bigcup_{S\in S}(\dot{s}+\Omega_{\iota})=G/G_{I}$
Sinoe
$\mathfrak{a}$
is -simple, we have $\alpha$
$\bigcap_{\dot{s}\in S}I(\dot{s}+\Omega_{\iota})=(0)$
Let
.
$J$
be a primitive ideal.
Sinoe
.
$\bigcap_{\dot{s}\in S_{\iota}}I(\dot{s}+\Omega_{\iota})\subset J$
, there is
an
$\dot{s}_{\iota}\in S_{\iota}$
such
that $I(\dot{s}_{\iota}+\Omega_{\iota})\subset J$
Sinoe $\dot{s}+\Omega_{\iota}\ni\dot{s}_{j}$
.
is compact, we may suppose that for sufficiently large . Henoe $G/G_{I}$
$ j\geq\ell$
$\dot{s}_{\iota}$
converges, say to . Then which implies
$\dot{s}+\Omega_{\iota}+\Omega_{\iota}\supset\dot{s}_{j}+\Omega_{j}$
$I(\dot{s}+\Omega.+\Omega.)\subset J$
.
$\dot{s}$
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
-ALGEBRAS
77
We have that , sinoe , as shown from is dense in the first part of the proof of Lemma 3.2 and the fact that the quotient map is open. Similarly we get that $\alpha_{t}(J)\subset Iforsomet\in G$ , i.e. $\alpha_{s}(I)\subset J$
$\cup I(\dot{s}+\Omega+\Omega_{\iota})$
$\alpha_{s}(I)$
$G\rightarrow G/G_{I}$
$\alpha_{s+t}(J)\subset\alpha_{s}(I)\subset J$
.
Sinoe $G/G_{J}$ is compact, we can conclude that $\alpha_{s+c}(J)=J$ . Thus . Hence the set of primitive ideals is , i.e. there is a correspondenoe between the primitive ideal space and $G/G_{I}$ , by choosing one primitive ideal of , which obviously preserves the actions of . For any subset of $G/G_{I}$ , we have $\alpha_{s}(I)=J$
$one- 0\acute{n}e$
$\{\alpha_{t}(I):t\in G/G_{I}\}$
$I$
$G$
$\mathfrak{a}$
$\bigcap_{\dot{s}\in S}\alpha_{s}(I)=\bigcap_{\dot{s}\in S}\alpha_{s}(I)$
$S$
.
By the same argument as above, $\bigcap_{l\in S}\alpha_{s}(I)\subset\alpha_{t}(I)$
implies that
$i\in\overline{S}$
.
Henoe the closure operations coincide through the correspond-
ence.
$q.e.d$
Proposition 3.8.
Let $ abeliangroupand\mathfrak{a}is\alpha$ -simple.
$(\mathfrak{a}, G, \alpha)$
be a Then
$C^{*}$
-dynamical system where
$\Gamma(\alpha)=F(\alpha)$
$G$
.
is a discrete
.
Proof. We apply Lemma 3.7 to the dual system , where now is compact, and use the formula for in Lemma 3.4 and the one for in Corollary 5.4 in [7].
$\Gamma$
$(\mathfrak{a}\times_{\alpha}c, \tau, a)$
$ff(\alpha)$
$\Gamma(\alpha)$
Proposition 3.9. Let be a separable -dynamical system (i.e. both and are separable). Suppose that is discrete for any primitive ideal I of a where $(a, G, \alpha)$
$G$
$a$
$C^{*}$
$G_{l}$
$G_{I}=\{t\in G:\alpha_{t}(I)=I\}$
If is of of
.
-simple, then the primitive ideal space of with the transposed action is isomorphic to (with action of ) for some closed subgroup $H$ of $G$ such that is compact, in particular $F(\alpha)=\Gamma(\alpha)(=H)$ . $a$
$\alpha$
$a$
$\mathfrak{a}\times_{\alpha}G$
$\Gamma$
$\Gamma/H$
$\Gamma$
$\Gamma/H$
Proof. (c.f. [8, Theorem 3.1]) By [5, Corollary 3.2], for any primitive ideal is compact. Apply Lemma 3.7. For the last statement, see the proof of Proposition 3.8. For applications of the above proposition we refer the reader to [8]. $I,$
$\Gamma/\Gamma_{I}$
AKITAKA KISHIMOTO
78
\S 4. Crossed products of
$O_{n}$
Let be an n-dimensional Hilbert spaoe $(2\leq n\leq\infty)$ , and let be the $O(f)$ . For each Fock Hilbert spaoe over is a bounded operator defined by $F(\ovalbox{\tt\small REJECT}_{n})$
$\ovalbox{\tt\small REJECT}_{n}$
$f\in\ovalbox{\tt\small REJECT}_{n},$
$\ovalbox{\tt\small REJECT}_{n}$
$O(f)g_{1}\otimes\cdots\otimes g_{n}=f\otimes g_{I}\otimes\cdots\otimes g_{n}$
$O(f)\Omega=f$
$O(f)$ is an isometry. . If where is the vacuum vector in We de-algebra generated by $O(f),$ . the note by If is finite, the Cuntz algebra $O_{n}[3]$ is isomorphic to the quotient of by the compact operator algebra on and if $n=\infty,$ . is isomorphic to induces an automorphism of through that of Each unitary on defined by $\Omega$
$\Vert f\Vert=1,$
$F(\ovalbox{\tt\small REJECT}_{n})$
$C^{*}$
$O(\ovalbox{\tt\small REJECT}_{n})$
$f\in\ovalbox{\tt\small REJECT}_{n}$
$n$
$O(\ovalbox{\tt\small REJECT}_{n})$
$O_{n}$
$F(\ovalbox{\tt\small REJECT}_{n})$
$u$
$O(\ovalbox{\tt\small REJECT}_{n})$
$O_{n}$
$\ovalbox{\tt\small REJECT}_{n}$
$O(f)\rightarrow 0(uf)$
,
$f\in\ovalbox{\tt\small REJECT}_{n}$
$O(\ovalbox{\tt\small REJECT}_{n})$
.
We call quasi-free those automorphisms of obtained in this way. See, for the detail, Evanoe [4]. From now on we assume that is finite. Let be a locally compact abelian group with its dual , as before, and let be a continuous unitary representation of $G$ on . By thinking of elements of the form $O_{n}$
$n$
$G$
$\Gamma$
$u$
$\ovalbox{\tt\small REJECT}_{n}$
$O(f_{1})\cdots O(f_{n})O(g_{1})^{*}\cdots O(g_{m})^{*}$
it is clear that Sp is the closed subgroup of $\alpha$
Lemma 4.1. Proof. $withp_{i}\in\Gamma$
Let
.
Let
$(O_{n}, G, \alpha)$
$(\phi_{i})_{i=1}^{n}$
be as above.
$\Gamma$
generated by Sp
Then
$\Gamma(\alpha)=Sp\alpha$
be an orthonormal system in
$LetS_{\ell}betheimageofO(\phi_{i})intoO_{n}$
Set for each
,
$X_{n}$
$u$
.
.
such that
$u_{t}\phi_{i}=\langle t, p_{i}\rangle\phi_{i}$
.
$ k=1,2,\ldots$
$S_{i}^{1k)}=\sum_{\mu:\ell\langle\mu)=k}S_{\mu}S_{i}S_{\mu}^{*}$
,
where the summation is taken over all the words of 1, , with length $l(\mu)=k$ , (c.f. [3]). All are isometries and satisfy that , and $x]\Vert=0$ for any is the algebra of fixed points under the gauge where ; automorphism group , i.e. the quasi-free automorphism group induced by { $\mu$
$S_{i^{k)}}^{t}$
$S_{\{\ell_{1},\ldots.i_{k}\}}=S_{i_{1}}\cdots S_{i_{k}}$
$x\in F^{n}\subset O_{n}$
$\gamma$
$|z|=1\}$
on
$\ovalbox{\tt\small REJECT}_{n}$
.
$\{$
$\ldots$
$n\}$
$\lim\Vert[S_{\ell}^{tk)}$
$F^{n}$
$z\cdot 1$
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
-ALGEBRAS
79
be an infinite aperiodic sequenoe of letters 1, , (c.f. Lemma 1.8 in [3]) $andletv_{m}$ be the restriction ofv to the firstm letters. Set
Let
$v$
$\ldots$
$Q_{m}=\sum_{\mu,l\langle\mu)=m}S_{\mu}S_{v_{m}}S_{v_{m}}^{*}St$
Then
$n\}$
$\{$
$\{Q_{m}\}$
are
$\gamma-$
.
and -invariant projections and satisfy $\alpha$
$\lim\Vert Q_{m}\epsilon(x)Q_{m}-Q_{m}xQ_{m}\Vert=0$ $\lim$
I
$ Q_{m}xQ_{m}\Vert=\Vert\epsilon(x)\Vert$
where is the projection of Then for any positive , $\epsilon(x)=\int\gamma_{t}(x)dt$
$0_{n}$
onto
$F^{n}$
.
Proposition 1.7 in [3]).
( $c.f$
$x\in O_{n}$
$\lim_{m}\lim_{k}\Vert Q_{m}xQ_{m}S_{i}^{1k)}x\Vert=\lim$ $\lim\Vert S_{i}^{(k)}Q_{m}\epsilon(x)Q_{m}x\Vert$
.
$=\lim_{m}\Vert Q_{m}\epsilon(x)Q_{m}x\Vert\geq\Vert\epsilon(x)\Vert^{2}$
Let zero positive
and with
$B\in\ovalbox{\tt\small REJECT}^{\alpha}(O_{n})$
$x\in B$
$\Omega$
a compact neighbourhood of
$Sp_{\alpha}(x)\subset\Omega$
.
$aremandksuchthatxQ_{m}S_{i}^{(k)}x\neq 0$
.
.
Then there is a nonIt follows from the above calculation that there This implies that $0$
Sp $\alpha|B\cap(p_{i}+\Omega+\Omega)\neq\phi$
Sinoe and are arbitrary, we can conclude that . Thus sinoe is a closed subgroup [6]. We denote by the extension of the gauge action to an action on . This is possible because commutes with . In the following we denote by $H$ the intersection of the closed subsemigroups of generated by Sp and $-p$ , with $B$
$\Omega$
$\Gamma(\alpha)=Sp\alpha$
$\Gamma(\alpha)\ni p_{i}$
$\Gamma(\alpha)$
$\overline{\gamma}$
$O_{n}\times_{\alpha}G$
$\gamma$
$\alpha$
$\gamma$
$\Gamma$
$p\in Spu$
.
Lemma4.2. Let
$(O_{n}, G, \alpha)$
Proof.
be as above.
We construct certain $ k=1,2,\ldots$ , set
$\alpha$
.
$ThenH\supset F(\alpha)$
-invariant states of
$P_{i}^{(k)}=S_{\ell}^{k}S_{i}^{*k}$
$O_{n}$
.
For
$i=1,\ldots,$
$\{P_{i}^{1k)}\}_{k=1,2},\ldots$
$\gamma$
$\phi_{i}(x)=\phi_{\ell}(P_{i}^{\langle k)}xP_{\ell}^{(k)})$
Then it is shown that
$\phi_{i}$
,
$x\in O_{n}$
$n$
and
.
is a decreasing sequenoe of -invariant projections. -invariant state satisfying
Then $\gamma$
$u$
,
$ k=1,2,\ldots$
Let
$\phi_{\ell}$
be a
.
is -invariant (and in fact unique) and that the continuous $\alpha$
AKITAKA KISHIMOTO
80
functions on ated by characters
for and
$G\ni t\rightarrow\phi(x\alpha_{t}(y))$
$p_{1},\ldots,$
$p_{n}$
$x,$
$y\in O_{n}$
$-p_{\ell}$
are contained in the closed algebra gener-
, e.g.
$\phi_{i}(x\alpha_{t}(S_{\mu}S_{v}^{*}))=\langle t, p_{j_{1}}+\cdots+p_{j_{m}}-p_{k_{1}}-\cdots-p_{k_{n}}\rangle\phi_{i}(xS_{\mu}S_{v}^{*})$
, where . This implies is non-zero only if that in the GNS representation associated with , the canonical representation $U$ of defined by $\mu=\{j_{1},\ldots, j_{m}\}$
$v\equiv\{k_{1},\ldots, k_{n}\}=\{i,\ldots, i\}$
$\phi_{i}$
$G$
$U_{t}\pi_{\phi_{i}}(x)\Omega_{\phi_{\ell}}=\pi_{\phi_{i}}\circ\alpha_{t}(x)\Omega_{\phi_{i}}$
has spectrum in the closed subsemigroup . Proposition 2.2 we have that
$H_{i}$
,
$x\in O_{n}$
generated by
$p_{1},\ldots,$
$p_{m}$
and
$-p_{i}$
. By
$\tilde{\Gamma}(\alpha)\subset H_{l}$
Lemma 4.3. Let , it follows that
$(O_{n}, G, \alpha)$
$O_{n}\times_{\alpha}G$
Proof.
Let
$a_{p}(I)\subset I$
for
$p\in H$
$\overline{\gamma}$
be a representation of or be of the form , we have
$O_{n}\times_{\alpha}G$
$\rho$
of
.
$x\in O_{n}^{\gamma}\times_{\alpha}G\equiv(O_{n}\times_{\alpha}G)^{\overline{\gamma}}$
sinoe
Then for any -invariant ideal I
be as above.
whose kemel is -invariant. Let with . Then $\overline{\gamma}$
$\sum a_{\iota}\otimes f_{i}$
$a_{i}\in O_{n}^{\gamma},$
$f_{i}\in C^{*}(G)$
$\lim\Vert S_{\ell}^{(k)*}xS_{i}^{(k)}-\theta_{p\ell}(x)\Vert=0$
$\lim_{k}\Vert\rho(S_{i}^{(t)*}xS_{i}^{(k)})\Vert=\Vert\rho\circ\theta_{p\ell}(x)\Vert$
.
The left hand side equals $\lim_{k}\Vert\rho(x)\rho(S_{i}^{1k)}S_{i}^{1k)*})\Vert$
sinoe tions and
$S_{i}^{(k)}S_{i}^{(k)*}$
asymptotically commutes with , we have
$x$
.
Further sinoe
$S_{i}^{(k)}S_{i}^{(k)*}$
are projec-
$\sum_{i}S_{t^{k)}}^{t}S^{(k)*}=1$
$|1\rho(x)\Vert\geq\Vert\rho\circ a_{p\iota}(x)\Vert$
$(*)$
$\Vert\rho(x)\Vert=\max_{i}\Vert\rho\circ\theta_{p\ell}(x)\Vert$
For a fixed
$x\in O_{n}^{\gamma}\times_{\alpha}G$
we can find an infinite sequence
$\{i_{k}\}$
of 1, $\{$
$\ldots$
,
$n\}$
such
that $(**)$
$\Vert\rho(x)\Vert=\Vert\rho\circ a_{p\iota_{1}+\cdots+p\ell_{k}}(x)\Vert$
for all $\{i_{k}\}$
.
.
There is an For such an we have $ k=1,2,\ldots$
$i\in\{1,2,\ldots, n\}$
which infinitely often appears in
$i$
$\Vert\rho(x)\Vert=\Vert\rho\circ a_{np\ell}(x)\Vert$
for
$ n=1,2,\ldots$
, sinoe for any subset
$J$
of 1, $\{$
$\ldots$
,
$k\},$
$(**)$
is less than or equal to
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
$\Vert\rho\circ\theta_{(\sum_{j\in J^{p\ell_{j}}})}(x)\Vert\leq\Vert\rho(x)\Vert$
Let ated by
$p\in H$
-ALGEBRAS
81
.
. By the assumption there is a sequenoe in the subsemigroup generwhich converges to , i.e. there is a sequenoe
$\{p_{1},\ldots, p_{n}, -p_{i}\}$
$p$
$q_{l}=\sum_{k}n_{k}^{1l)}p_{k}-m^{(l)}p_{i}-p,$
which converges to zero in
$\Gamma$
.
$n_{k}^{(l)}\geq 0,$
$m^{(\ell)}\geq 0$
Then
$\Vert x-a_{q_{i}}(x)\Vert\geq\Vert\rho\circ\theta_{m^{(i)}p\ell}(x)-\rho\circ\alpha_{(\Sigma n_{k}^{(l)}p\kappa^{-p)}}(x)\Vert$
$\geq\Vert\rho(x)\Vert-\Vert\rho\circ\theta_{-p}(x)\Vert$
which implies that
$\Vert\rho\circ a_{-p}(x)\Vert\geq\Vert\rho(x)\Vert$
. Henoe
$\theta_{p}(I)\cap O_{n}^{\gamma}\times_{\alpha}G\subseteq I\cap O_{n}^{\gamma}\times_{\alpha}G$
where that
$I$
is the kernel of
$a_{p}(I)\subset I$
$\rho$
.
Since
$I$
is generated by
$I\cap O_{n}^{\gamma}\times_{a}G$
,
we can conclude
.
$q.e.d$
Theorem 4.4. Let be as above. The crossed product simple if and only if the closed subsemigroup of generated by Sp and itselffor any $p\in Spu$ . $(O_{n}, G, \alpha)$
$O_{n}\times_{\alpha}G$
$\Gamma$
Proof.
Sinoe
$H\supset 5(\alpha)byLemma4.2,$
$ifH\neq\Gamma,$
$u$
$O_{n}\times_{a}$
$-p$
is
.
is $\Gamma$
Gisnot simple by Theo-
rem 3.5.
a-
Suppose $ H=\Gamma$ . Then Lemma 4.3 implies that any -invariant ideal is invariant. Sinoe is simple [3], there are not any non-trivial -invariant ideals of . Thus is -simple. Sinoe is prime by Lemma 4.1 and [7, Theorem 5.8], it follows from [7, Lemma 6.4] (or Lemma 3.7) that is simple. $\overline{\gamma}$
$O_{n}$
$O_{n}\times_{\alpha}G$
$O_{n}\times_{\alpha}G$
$\theta$
$O_{n}\times_{\alpha}G$
$\overline{\gamma}$
$O_{n}\times_{a}G$
Proposition 4.5. Let be as above and suppose that contains the gauge automorphism group . Then is the intersection of the closed subsemigroups of generated by Sp and $-p$ , with $p\in Spu$ . $(O_{n}, G, \alpha)$
$\alpha(G)$
$\tilde{\Gamma}(\alpha)$
$\gamma$
$\Gamma$
Sinoe is inner under the above assumption, any ideal of -invariant. The rest of the proof follows from Lemmas 4.2, 4.3 and 3.4. Proof.
$\overline{\gamma}$
$u$
$\overline{\gamma}$
\S 5. Crossed products of
$O_{n}\times_{\alpha}G$
is
$q.e.d$
.
$O_{\infty}$
In this section we consider the case $ n=\infty$ . As in Section 4, let be a weakly continuous unitary representation of a locally compact group $G$ on a separable infinite-dimensional Hilbert spaoe and let be the corresponding quasi-free $u$
$\ovalbox{\tt\small REJECT}$
$\alpha$
AKITAKA KISHIMOTO
82
action on by Sp . Let
$O_{\infty}=O(\ovalbox{\tt\small REJECT})$
.
It is immediate that Sp
$\alpha$
is the closed subgroup generated
$u$
$O_{\infty}$
on
be the Fock spaoe and the Fock representation of be the canonical representation of on the Fock spaoe, i.e.
$F=F(\ovalbox{\tt\small REJECT})=\sum_{0}^{\infty\ovalbox{\tt\small REJECT}\otimes n}$
$F[4]$
.
Let
$U_{F}$
$\pi_{F}$
$G$
$U_{F}(t)|\ovalbox{\tt\small REJECT}\otimes n=u_{t}\otimes\cdots\otimes u_{t}(n- tuples)\equiv u_{t}^{\otimes n}$
.
is the closed subsemigroup $H$ generated by Sp . The It is clear that Sp of in an obvious way. If gives a representation pair is not simple (c.f. [9]). is not faithful, in particular $U_{F}$
$u$
$(\pi_{F}, U_{F})$
$H\neq\Gamma,$
$\pi_{F}\times U_{F}$
$O_{\infty}\times_{\alpha}G$
$0_{\infty}\times_{\alpha}G$
$\pi_{F}\times U_{F}$
be as above. The crossed product Theorem 5.1. Let simple if and only if the closed subsemigroup $H$ generated by Sp is $(0_{\infty}, G, \alpha)$
$\Gamma$
$u$
$O_{\infty}\times_{\alpha}G$
is
.
, then is not simple. Henoe we Proof. We have shown that if $ H=\Gamma$ . now assume that is faithful. Sinoe is irreducible, First we want to show that is prime. this in particular implies that onto For each $ n=1,2,\ldots$ , there is a natural unitary map $W$ from , such that where with and if . Note that $ H\neq\Gamma$
$O_{\infty}\times_{\alpha}G$
$\pi_{F}\times U_{F}$
$\pi_{F}\times U_{F}$
$0_{\infty}\times_{\alpha}G$
$F\otimes\ovalbox{\tt\small REJECT}^{\otimes n}$
$ W_{n}(\psi\otimes\phi)=\sum$
$\sum_{n}^{\infty}\ovalbox{\tt\small REJECT}^{\otimes k}cF$
$\psi_{k}\otimes\phi$
$\psi=\sum_{0}^{\infty}\psi_{k}$
$\psi_{k}\in\ovalbox{\tt\small REJECT}\otimes k$
$\psi_{k}\otimes\phi\in\ovalbox{\tt\small REJECT}^{\otimes k+n}$
$W_{n}\cdot U_{F}(t)\otimes u_{t}^{\otimes n}=U_{F}(t)W_{n}$
.
In the following, however, we omit $W$ . be a decreasing sequenoe of compact neighbourhoods of in such. that Let Sp and with such that . There are tends to zero weakly. and due to the assumption, there are positive . Then, sinoe Sp Let cp-p, with such that Sp . integers $m$ and where are monomials (i.e. of the type Let $0$
$(\Omega_{\iota})$
$\cap\Omega_{\iota}=(0)$
$u$
$ p_{\iota}\in$
$\phi_{\iota}\in\ovalbox{\tt\small REJECT}$
$\Vert\phi_{\iota}\Vert=1$
$\Gamma$
$Sp_{u}\phi_{\iota}\subset p_{\iota}+\Omega_{\iota}$
$\phi_{\iota}$
$ U_{F}=\Gamma$
$ p\in\Gamma$
.
$\Vert\psi_{\iota}\Vert=1$
$\psi_{\iota}\in\ovalbox{\tt\small REJECT}\otimes m$
$x=\sum a_{k}\otimes f_{k}\in O_{\infty}\times_{\alpha}G$
and Note that for any
$O(f_{\ell})O^{*}(g_{1})\cdots O^{*}(g_{j}))$
$f_{k}\in L^{1}(G)$
$\psi\in F$
$U_{F}\psi_{\iota}$
$+\Omega_{\iota}$
$ O(f_{1})\cdots$
$a_{k}$
.
,
$\lim\Vert\int f_{k}(t)U_{F}(t)(\psi\otimes\phi_{\iota}\otimes\psi_{\iota})dt-\int f_{k}(t)\langle t, p\rangle(U_{F}(t)\psi)\otimes\phi_{\iota}\otimes\psi_{\iota}dt\Vert=0$
$\lim\Vert\pi_{F}(a_{k})(\psi\otimes\phi_{\iota}\otimes\psi_{\iota})-(\pi_{F}(a_{k})\psi)\otimes\phi_{\iota}\otimes\psi_{\iota}\Vert=0$
.
Henoe we have that $\lim\Vert(\pi_{F}\times U_{F})(x)(\psi\otimes\phi_{\iota}\otimes\psi_{\iota})-((\pi_{F}xU_{F})\circ(\theta_{p}(x)\psi))\otimes\phi_{\iota}\otimes\psi_{\iota}\Vert=0$
Since
$\psi\in F$
is arbitrary, we have that
$\Vert\pi_{F}\times U_{F}(x)\Vert\geqq\Vert(\pi_{F}\times U_{F})\circ\theta_{p}(x)\Vert$
.
, which in
SIMPLE CROSSED PRODUCTS OF
turn implies, since
$C^{*}$
-ALGEBRAS
83
is arbitrary,
$p$
$\Vert(\pi_{F}\times U_{F})\circ a_{p}(x)\Vert=\Vert(\pi_{F}\times U_{F})(x)\Vert$
,
$ p\in\Gamma$
.
is simple [3], we can conclude that Sinoe is faithful. Now let be any irreducible representation of . By a similar reason as given in the proof of Theorem 4.4 it suffioes to show that ker $O_{\infty}$
$\pi_{F}\times U_{F}$
$\pi\times U$
$0_{\infty}\times_{\alpha}G$
$(\pi\times U)\cap$
$O_{\infty}^{\gamma}\times_{\alpha}G=(0)$
.
Let be a $mplete$ orthonormal system of M. Then mutually orthogonal projections. Let $(f_{i})$
$P=\sum_{i=1}^{\infty}\pi(O(f_{\ell})O^{*}(f_{i}))$
$\pi(O(f_{i})O^{*}(f_{\ell}))$
are
.
. which is independent from choice of $P\neq 1$ . Let be a projection in such that $0\neq e\leqq 1-P$ . Then by the irreducibility, we have that . But , i.e. $1-P=e$ . Hence $1-P$ is one-dimensional. Now it is easily shown that is equivalent to and that $U=pU_{F}$ with some . Hence the faithfulness of follows from the above. Suppose that $P=1$ . Let $p\in Spu+\cdots+Spu$ ( terms). There is a sequence of unit vectors with such that Sp given before. Now we define a family of isometries:
$P$
is a projection in First suppose that
$U(G)^{\prime}$
$(f_{\ell})$
$U(G)^{\prime}$
$e$
$(1-P)[\pi(O_{\infty})e\ovalbox{\tt\small REJECT}_{n}]$
$[\pi(O_{\infty})e\ovalbox{\tt\small REJECT}_{\pi}]=\ovalbox{\tt\small REJECT}_{\pi}$
$=e\ovalbox{\tt\small REJECT}_{\pi}$
$\pi$
$ p\in\Gamma$
$\pi_{F}$
$\pi\times U\simeq\pi_{F}\times u_{F}\circ a_{p}$
$k$
$\psi_{1\iota}\otimes\cdots\otimes\psi_{k\iota}\in\ovalbox{\tt\small REJECT}\otimes k$
$U_{F}(\psi_{1\iota}\otimes\cdots\otimes\psi_{k\iota})cp+\Omega_{\iota}$
$\Omega_{\iota}$
$V_{\iota}^{t0)}=\pi(O(\psi_{1\iota})\cdots O(\psi_{k\iota}))$
$V_{\iota}^{tm})=\sum\pi(O(f_{i}))V^{(m-1)}\pi(O^{*}(f_{\ell}))$
Note that Let
$V|^{m}$
)
.
does not depend on . where are monomials, say, . For we have that $(f_{i})$
$x=\sum a_{k}\otimes f_{k}\in O_{\infty}^{\gamma}\times_{\alpha}G$
$a_{k}$
$a_{k}=O(g_{1})\cdots O(g_{m_{k}})$
.
$m\geqq m_{k}$
$O^{*}(h_{1})\cdots O^{*}(h_{m_{k}})$
$\pi(a_{k})V_{\iota}^{(m)}=V_{\iota}^{(m)}\pi(a_{k})$
$\lim\Vert U_{t}V_{\iota}^{(m)}-\langle t, p\rangle V_{l}^{(m)}U_{t}\Vert=0$
Thus, for
.
$m\geq\max(m_{k})$
$\lim\Vert(\pi\times U)(x)V^{(m)}-V_{l}^{(m})(\pi\times U)\circ\theta_{p}(x)\Vert=0$
) Sinoe are isometries, we have that is dense in , we have $V_{\iota}^{1m}$
$p$
.
$\Vert(\pi\times U)(x)\Vert\geq\Vert(\pi\times U)\circ\theta_{p}(x)\Vert$
$\Gamma$
$\Vert(\pi\times U)(x)\Vert=\Vert(\pi\times U)\circ\theta_{p}(x)\Vert$
,
$\forall p\in\Gamma$
.
.
Sinoe such
AKITAKA KISHIMOTO
84
Sinoe
$0_{\infty}$
is simple, we know that
$(\pi\times U)|O_{\infty}^{\gamma}\times_{\alpha}G$
is faithful.
added by those of the essential Remark 5.2. If the set of elements of Sp contains the gauge automorphism itself and if spectrum of is equal to Sp equals Sp . For example group , then it follows from the above proof that $U_{F}$
$\alpha(G)$
$U_{F}$
$u$
$\tilde{\Gamma}(\alpha)$
$U_{F}$
$\gamma$
$r_{(\gamma)=Z_{+}}$
.
of In passing we give a remark on a quasi-free automorphism tends to zero weakly as such that induoed by a unitary on following proposition implies, in particular, that the Fock state is the only . state of
$O_{\infty}$
$\alpha_{u}$
$u^{n}$
$\ovalbox{\tt\small REJECT}$
$u$
which is . The
$ n\rightarrow\infty$
$\alpha_{u}$
-invariant
$0_{\infty}$
Proposition5.3.
$Let\alpha_{u}$
be as above.
$Thenforanyx\in O_{\infty}$
,
$M_{N}(x)\equiv(2N+1)^{-1}\sum_{n=-N}^{N}\alpha_{u}^{n}(x)$
converges in norm to a multiple
of the
identity.
Suppose $x=O(f_{1})\cdots O(f_{n})O^{*}(g_{1})\cdots O(g_{m})^{*}$ with $=\cdots=\Vert g_{m}\Vert=1$ . Then if $n\geq 1$ ,
Proof.
$n+m\geq 1$ ,
and
$\Vert f_{1}\Vert$
$\Vert M_{N}(x)\Vert^{2}=\Vert M_{N}(x)^{*}M_{N}(x)\Vert$
$\leq(2N+1)^{-}:_{m=-N}\sum^{N}|\langle u^{n}f_{1}u^{m}f_{1}\rangle|$
. which implies that $\lim\Vert M_{N}(x)\Vert^{2}=0$ . Similarly we have the same in case , which is dense in The linear span of 1 and elements of the fom completes the proof. is with With alittle more care we can conclude that the system weakly asymptotically abelian. $m\geqq 1$
$O(f_{1})\cdots O^{*}(g_{m})$
$(0_{\infty}, Z, \alpha)$
$O_{\infty}$
$\alpha_{n}\equiv\alpha_{u^{n}}$
Note and Acknowledgements
The problems treated in this note were brought up by H. Takai to a series of seminars, held in Tokyo, attended by A. Ikunishi and Y. Nakagami besides us. The basic ideas of Section 5 were obtained during the seminars, and those of Sections 2 and 3 are a result of many discussions with H. Takai during the summer in 1979. I would like to thank the other members of the seminars and especially Dr. H. Takai for stimulating discussions. I am grateful to Professor D. W. Robinson for warm hospitality at the University of New South Wales, Sydney, Australia, where this was completed. I am also grateful to Dr. D. Olesen for a couple of comments.
SIMPLE CROSSED PRODUCTS OF
$C^{*}$
-ALGEBRAS
85
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[3]
Akemann, C. A., Pedersen, G. K., Tomiyama, J. : Multipliers of -algebras, J. Functional Analysis, 13, 277-301 (1973). Arveson, W. B. : On groups of automorphisms of operator algebras, J. Functional Analysis, 15, 217-243 (1974). Cuntz, J. : Simple -algebras generated by isometries, Commun. math. Phys. 57, 173$C^{*}$
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Evance, D. E. : On (preprint). Gootman, E. G., Rosenberg, J. : The structure of Crossed product -algebras: A proof of the generalized Effros-Hahn conjecture, Invent. Math. 52, 283-298 (1979). Olesen, D. : Inner automorphisms of simple -algebras, Commun. math. Phys. 44, 175(1975).
Olesen, D., Pedersen, G. K. : Applications of the Connes spectrum to -dynamical systems. J. Functional Analysis 30, 179-197 (1978). Olesen, D., Pedersen, G. K. : APplications of the Connes sPectrum to -dynamical systems II (preprint). Pedersen, G. K., Takai, H. : Crossed products of -algebras by aPproximately uniformly continuous actions, Math. Scand. 45, 282-288 (1979). Takai, H. : On a duality for crossed products of -algebras, J. Functional Analysis 19, $C^{*}$
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Department of Mathematics Yokohama City University
Yokohama, Japan
