Poisson brackets symmetry from the pentagon-wheel cocycle in the graph complex

Abstract

Kontsevich designed a scheme to generate infinitesimal symmetries P = Q(P) of Poisson brackets P on all affine manifolds Mr; every such deformation is encoded by oriented graphs on n+2 vertices and 2n edges. In particular, these symmetries can be obtained by orienting sums of non-oriented graphs γ on n vertices and 2n-2 edges. The bi-vector flow P = Or(γ)(P) preserves the space of Poisson structures if γ is a cocycle with respect to the vertex-expanding differential in the graph complex. A class of such cocycles γ2+1 is known to exist: marked by ∈ N, each of them contains a (2+1)-gon wheel with a nonzero coefficient. At =1 the tetrahedron γ3 itself is a cocycle; at =2 the Kontsevich--Willwacher pentagon-wheel cocycle γ5 consists of two graphs. We reconstruct the symmetry Q5(P) = Or(γ5)(P) and verify that Q5 is a Poisson cocycle indeed: [\![P,Q5(P)]\!] 0 via [\![P,P]\!]=0.