Jordan rigidity of full matrix algebras

Abstract

Let F be a field of characteristic different from 2, and let Mn(F)+ denote the Jordan algebra of all n× n matrices over F with product X Y:=(XY+YX)/2. We prove a rigidity theorem for Mn(F)+, n2: if J is any 2-torsion-free Jordan ring and ϕ:Mn(F)+ is a Jordan multiplicative (product-preserving) map, then ϕ(0) is an idempotent and Xϕ(X)-ϕ(0) is either zero or an injective Jordan ring homomorphism. Thus, up to an idempotent constant, preservation of the Jordan product alone forces additivity and the zero-or-injective dichotomy. When specialized to associative codomains, the theorem yields the Jacobson--Rickart decomposition into homomorphic and antihomomorphic parts. In particular, for maps Mn( F)+ Mk( K)+, where K is a field of characteristic different from 2, we also obtain a block normal form governed by finite-dimensional K-representations of F, together with a criterion for the existence of nonconstant maps.