The Rank Theorem and L2-invariants in Free Entropy: Global Upper Bounds

Abstract

Using an analogy with the rank theorem in differential geometry, it is shown that for a finite n-tuple X in a tracial von Neumann algebra and any finite m-tuple F of *-polynomials in n noncommuting indeterminates, eqnarray* δ0(X) & ≤ & Nullity(DsF(X)) + δ0(F(X):X) eqnarray* where δ0 is the (modified) microstates free entropy dimension and DsF(X) is a kind of derivative of F evaluated at X. When F(X) =0 and |DsF(X)| has nonzero Fuglede-Kadison-L\"uck determinant, then X is α-bounded in the sense of j3 where α = Nullity(DsF(X)). Using Linnell's L2 integral domain results in l as well as Elek and Szab\'o's work on L\"uck's determinant conjecture for sofic groups in es the following result is proven. Suppose is a sofic, left-orderable, discrete group with 2 generators and ≠ \0\. The following conditions are equivalent: (1) F2. (2) L() L( F2). (3) L() is strongly 1-bounded. (4) δ0(X) = 1 for any finite set of generators X for L(). From Brodskii and Howie's results on local indicability (b, h), it follows that a sofic, torsion-free, one-relator group von Neumann algebra on two generators with nontrivial relator is strongly 1-bounded. It also follows from the residual solvability of the positive one relator groups (baum) that a one-relator group von Neumann algebra on two generators whose relator is a nontrivial, positive, non-proper word in the generators is strongly 1-bounded.