The Jordan multiplication semigroup of matrix algebras is the full endomorphism semigroup

Abstract

Let K be a field of characteristic different from 2, and let Mn(K) be the algebra of all n× n matrices over K. We consider the corresponding special Jordan algebra A:=Mn(K)+ with symmetrized product A B:=(AB+BA)/2, and write A v:=Mn(K) for the underlying K-vector space of A. For A∈A, let LA(X):=A X be the multiplication operator. We consider the Jordan multiplication semigroup generated by all multiplication operators, \[ JMS(A):= LA:A∈A⊂eq EndK(A v). \] We prove that JMS(A)=EndK(A v). Equivalently, every K-linear endomorphism of A v is a composition of multiplication operators. The proof is primarily linear-algebraic. The main step is to show that SL(A v)⊂eq JMS(A) by constructing elementary transvections inside the semigroup. We then prove determinant surjectivity on the unit group of JMS(A) and combine it with the existence of a singular element of rank n2-1 to obtain the full endomorphism semigroup. In the finite-field case, the determinant-surjectivity step is established via Jacobi-sum estimates.