Schwarz maps with symmetry

Abstract

The theory of symmetry of quantum mechanical systems is applied to study the structure and properties of several classes of relevant maps in quantum information theory: CPTP, PPT and Schwarz maps. First, we develop the general structure that equivariant maps : A B between C-algebras satisfy. Then, we undertake a systematic study of unital, Hermiticity-preserving maps that are equivariant under natural unitary group actions. Schwarz maps satisfy Kadison's inequality (X X) ≥ (X) (X) and form an intermediate class between positive and completely positive maps. We completely classify U(n)-equivariant on Mn( C) and determine those that are completely positive and Schwarz. Partial classifications are then obtained for the weaker DU(n)-equivariance (diagonal unitary symmetry) and for tensor-product symmetries U(n1) U(n2). In each case, the parameter regions where is Schwarz or completely positive are described by explicit algebraic inequalities, and their geometry is illustrated. Finally, we further show that the U(n)-equivariant family satisfies PPT EB, while the DU(2), symmetric DU(3), U(2) U(2) and U(2) U(3), families obey the PPT2 conjecture through a direct symmetry argument. These results reveal how group symmetry controls the structure of non-completely positive maps and provide new concrete examples where the PPT2 property holds.