The structure of gauge invariant Gaussian quantum operations on finite Fermion systems

Abstract

Let H1 be a finite dimensional complex Hilbert space. Let Z() be a canonical anti-commutation relations (CAR) field over H1 acting irreducibly on a Hilbert space K. The *-algebra A H1 generated by the Z(), ∈ H1, is simply all operators on K. However, the CAR field endows A H1 with additional structure, and we are concerned with quantum operations acting in harmony with this structure. In particular, there is a gauge automorphism group generated by ``second quantizing'' eit. The fixed point algebra of the gauge group, G H1, is a sub-algebra of A H1 studied by Araki and Wyss. It contains the density matrices of an important class of states, the gauge invariant Gaussian states, SGIG. Our focus is on semigroups \et L\t≥ 0 of quantum operations on A H1 that map SGIG into itself. Each et L is one-to-one, and our first main result is a structure theorem for such quantum operations on G H1 that map SGIG into itself. We apply this to study semigroups of quantum operations on G H1 that map SGIG into itself. Our second main result is a structure theorem showing that they are parameterized by pairs (G,A) where G is a contraction semigroup generator on H1, and 0 ≤ A ≤ -G -G*. We then show that each of these semigroups has a natural extension to the full CAR algebra A H1. Further results are obtained under further assumptions on the pair (G,A).