On simple transposed Poisson algebras

Abstract

We develop a structure theory for transposed Poisson algebras over fields of characteristic different from two. In particular, we prove that every finite-dimensional transposed Poisson algebra over an algebraically closed field decomposes as the direct sum of a unital ideal and a nilpotent ideal. As a consequence, we obtain restrictions on simple transposed Poisson algebras and use them to classify the simple finite-dimensional transposed Poisson algebras over an algebraically closed field of characteristic p>3. Precisely, we show that every such algebra has as underlying Lie algebra a Zassenhaus algebra W(1;n) and is isomorphic to one of the algebras of the family Wn(q) arising from a mutation of a natural associative commutative structure on W(1;n). We then study the corresponding isomorphism problem for the family Wn(q) and determine the irreducible finite-dimensional representations of these simple transposed Poisson algebras Wn(q) in the unital case. We conclude with some applications to Jordan superalgebras, weak-Leibniz algebras and quasi-Poisson algebras.