Completely bounded maps into certain Hilbertian operator spaces
Abstract
We prove a factorization of completely bounded maps from a C*-algebra A (or an exact operator space E⊂ A) to 2 equipped with the operator space structure of (C,R)θ (0<θ<1) obtained by complex interpolation between the column and row Hilbert spaces. More precisely, if F denotes 2 equipped with the operator space structure of (C,R)θ, then u: A F is completely bounded iff there are states f,g on A and C>0 such that \[ ∀ a∈ A \|ua\|2 C f(a*a)1-θg(aa*)θ.\] This extends the case θ=1/2 treated in a recent paper with Shlyakhtenko. The constants we obtain tend to 1 when θ 0 or θ 1. We use analogues of "free Gaussian" families in non semifinite von Neumann algebras. As an application, we obtain that, if 0<θ<1, (C,R)θ does not embed completely isomorphically into the predual of a semifinite von Neumann algebra. Moreover, we characterize the subspaces S⊂ R C such that the dual operator space S* embeds (completely isomorphically) into M* for some semifinite von neumann algebra M: the only possibilities are S=R, S=C, S=R C and direct sums built out of these three spaces. We also discuss when S⊂ R C is injective, and give a simpler proof of a result due to Oikhberg on this question. In the appendix, we present a proof of Junge's theorem that OH embeds completely isomorphically into a non-commutative L1-space. The main idea is similar to Junge's, but we base the argument on complex interpolation and Shlyakhtenko's generalized circular systems (or ``generalized free Gaussian"), that somewhat unifies Junge's ideas with those of our work with Shlyakhtenko.
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