The Goldman-Turaev Lie bialgebra and the Kashiwara-Vergne problem in higher genera

Abstract

For a compact oriented surface of genus g with n+1 boundary components, the space g() spanned by free homotopy classes of loops in carries the structure of a Lie bialgebra equipped with a natural decreasing filtration, whose structure morphisms are called the Goldman bracket and the (framed) Turaev cobracket. We address the following Goldman-Turaev (GT) formality problem: construct a Lie bialgebra homomorphism θ from g() to its associated graded gr\, g() such that gr \, θ = id. In order to solve it, we define a family of higher genus Kashiwara-Vergne (KV) problems for an element F∈ Aut(L), where L is a free Lie algebra. In the case of g=0 and n=2, it is the classical KV problem from Lie theory. For g>0, these KV problems are new. We show that an element F induces a GT formality map if and only if it is a solution of the KV problem. A crucial step in solving the higher genus KV problem is to construct solutions for the case of g=1 and n=1 in terms of certain elliptic associators following Enriquez. By solving the KV problem, we establish the GT formality for every g and n, with the exception of some framings for g=1 in which case the GT formality actually does not hold. Furthermore, we introduce pro-unipotent groups KV and KRV which act on the space of solutions of the KV problem freely and transitively. There are injective maps GT1 KV, GRT1 KRV from Grothendieck-Teichm\"uller groups. As an application, we show that the Johnson obstruction given by the Turaev cobracket coincides with the one given by the Enomoto-Satoh trace. As part of our study, we prove a uniqueness theorem for non-commutative divergence cocycles on the group algebra of a free group which is of independent value.