Injective von Neumann algebra - MathOverflow most recent 30 from http://mathoverflow.net 2013-05-26T00:15:36Z http://mathoverflow.net/feeds/question/101321 http://www.creativecommons.org/licenses/by-nc/2.5/rdf http://mathoverflow.net/questions/101321/injective-von-neumann-algebra Injective von Neumann algebra m07kl 2012-07-04T17:02:59Z 2012-07-04T20:33:27Z <p>Let $G$ be a non-amenable countable discrete group. How can I show that the group von Neumann algebra $L(G)$ has no injective direct summand?</p> http://mathoverflow.net/questions/101321/injective-von-neumann-algebra/101340#101340 Answer by Jesse Peterson for Injective von Neumann algebra Jesse Peterson 2012-07-04T20:33:27Z 2012-07-04T20:33:27Z <p>Here is an adaptation of the standard proof that $G$ is amenable if $LG$ is injective. (I believe for instance that it is contained in the book of Brown and Ozawa).</p> <p>Suppose $p \in LG$ is a non-zero central projection such that $p LG$ is injective. Thus, there exists a conditional expectation $E: \mathcal B(p \ell^2 G) \to p LG$. If we view $\ell^\infty G \subset \mathcal B(\ell^2 G)$ as diagonal multiplication operators (for $f \in \ell^\infty G$ and $\xi \in \ell^2 G$ we set $(M_f \xi)(\gamma) = f(\gamma) \xi(\gamma)$), and if we denote by $\tau$ a tracial state on $pLG$ then we can construct a state $\varphi$ on $\ell^\infty G$ by the formula $\varphi(f) = \tau \circ E(p M_f p)$. If $\gamma \in G$ then we have $$\varphi( f \circ \gamma) = \tau \circ E(p M_{f \circ \gamma} p)$$ $$= \tau \circ E(p \lambda_{\gamma^{-1}} M_f \lambda_{\gamma} p) = \tau( (p\lambda_{\gamma^{-1}}p) E(p M_f p) (p \lambda_{\gamma}p) ) = \varphi(f).$$ Thus $\varphi$ is an invariant mean for $G$ and so $G$ is amenable.</p>