Classification of Jordan multiplicative maps on matrix algebras

Abstract

Let Mn(F) be the algebra of n × n matrices over a field F of characteristic not equal to 2. If n 2, we show that an arbitrary map φ : Mn(F) Mn(F) is Jordan multiplicative, i.e.\ it satisfies the functional equation φ(XY+YX)=φ(X)φ(Y)+φ(Y)φ(X), for all X,Y ∈ Mn(F) if and only if one of the following holds: either φ is constant, equal to P/2 for some idempotent P ∈ Mn(F), or there exists an invertible matrix T ∈ Mn(F) and a ring monomorphism ω: F F such that φ(X)=Tω(X)T-1 or φ(X)=Tω(X)tT-1, for all X ∈ Mn(F), where ω(X) denotes the matrix obtained by applying ω entrywise to X. In particular, any Jordan multiplicative map φ : Mn(F) Mn(F) with φ(0)=0 is automatically additive. The analogous characterization fails when F has characteristic 2.

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