Linear k-power preservers and trace of power-product preservers

Abstract: Let $V$ be the set of $n\times n$ complex or real general matrices, Hermitian matrices, symmetric matrices, positive definite (resp. semi-definite) matrices, diagonal matrices, or upper triangular matrices. Fix $k\in \mathbb{Z}\setminus {0, 1}$. We characterize linear maps $\psi:V\to V$ that satisfy $\psi(A^k)=\psi(A)^k$ on an open neighborhood $S$ of $I_n$ in $V$. The $k$-power preservers are necessarily $k$-potent preservers, and the case $k=2$ corresponds to Jordan homomorphisms. Applying the results, we characterize maps $\phi,\psi:V\to V$ that satisfy "$ \operatorname{tr}(\phi(A)\psi(B)^k)=\operatorname{tr}(AB^k)$ for all $A\in V$, $B\in S$, and $\psi$ is linear" or "$ \operatorname{tr}(\phi(A)\psi(B)^k)=\operatorname{tr}(AB^k)$ for all $A, B\in S$ and both $\phi$ and $\psi$ are linear." The characterizations systematically extend existing results in literature, and they have many applications in areas like quantum information theory. Some structural theorems and power series over matrices are widely used in our characterizations.