Let $A$ and $B$ be $C^{\ast}-$ algebras and $A \otimes B$ denotes minimal(spatial) tensor product.
Is there any classification of primitive ideals of $A \otimes B$? (I'm mainly interested in the case when either $A$ or $B$ is commutative.)
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$\begingroup$ If $A$ and $B$ are commutative, then $A = C_0(X)$ and $B= C_0(Y)$ for locally compact Hausdorff spaces, and $A \otimes B = C_0(X \times Y)$. $\endgroup$– Matthias LudewigCommented Aug 12, 2021 at 18:14
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1 Answer
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I expect that this answer is satisfactory, although it isn't a complete answer. This is really the best result one can hope for.
For a $C^\ast$-algebra $A$ let $Prime(A)$ be the prime ideal space (defined exactly as the primitive ideal space, but with prime (two-sided closed) ideals instead). It is well-known that $Prime(A) = Prim(A)$ when $A$ is separable or when $A$ is Type I.
The following result is due to Proposition 2.16 and 2.17 in [Blanchard, Etienne; Kirchberg, Eberhard Non-simple purely infinite C∗-algebras: the Hausdorff case. J. Funct. Anal. 207 (2004), no. 2, 461–513.] and builds on Kirchberg's deep work on exact $C^\ast$-algebras:
Theorem: If $A$ and $B$ are $C^\ast$-algebra and at least one of them is exact, then $Prime(A\otimes_{\textrm{min}} B)$ is homeomorphic to $Prime(A) \times Prime(B)$.
There is a canonical map $Prime(A) \times Prime(B) \to Prime(A\otimes_{\mathrm{min}} B)$ given by $(I,J) \mapsto I\otimes_{\mathrm{min}} B + A \otimes_{\mathrm{min}} J$, and this is the homeomorphism in the theorem above.
If $I$ and $J$ are primitive ideals in $A$ and $B$ respectively, then $I\otimes_{\mathrm{min}} B + A\otimes_{\mathrm{min}} J$ is also primitive. Hence we get the following corollary for primitive ideal spaces instead of prime ideal spaces.
Corollary: Let $A$ and $B$ be $C^\ast$-algebras for which all prime ideals are primitive (e.g. separable/Type I/simple), and such that at least one of $A$ and $B$ is exact. Then $Prim(A\otimes_{\textrm{min}} B)$ is homeomorphic to $Prim(A) \times Prim(B)$.
The results fail in general (even when $A$ is simple, non-exact, and $B=\mathcal B(\ell^2(\mathbb N))$), so you can't really hope for anything better.
As commutative $C^\ast$-algebras are exact, the above theorem is applicable if one of the $C^\ast$-algebras is commutative.
Note that one gets $Prim(A\otimes_{\mathrm{min}} B) \cong Prim(A) \times Prim(B)$ (with primitive ideal spaces), if, for instance, $A$ is commutative (hence Type I) and $B$ is separable.
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$\begingroup$ Thanks Jamie. Do we get the isomorphism mentioned in last paragraph in the case when $A$ is commutative and $B$ is simple? $\endgroup$ Commented Aug 13, 2021 at 7:22
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$\begingroup$ Yes, it is true when $A$ is commutative and $B$ is simple since $Prim(B) = Prime(B)$ (is a one-point space). I forgot to add that when the theorem applies and all prime ideals of A and B are primitive, then all prime ideals of $A\otimes_{\mathrm{min}} B$ are also primitive. I'll modify my answer to include this, since this is how one obtains results on the primitive ideal space instead of the prime ideal space. $\endgroup$ Commented Aug 13, 2021 at 9:54