Particle-hole transformation in the continuum and determinantal point processes

Abstract

Let X be an underlying space with a reference measure σ. Let K be an integral operator in L2(X,σ) with integral kernel K(x,y). A point process μ on X is called determinantal with the correlation operator K if the correlation functions of μ are given by k(n)(x1,…,xn)=det[K(xi,xj)]i,j=1,…,n. It is known that each determinantal point process with a self-adjoint correlation operator K is the joint spectral measure of the particle density (x)= A+(x) A-(x) (x∈ X), where the operator-valued distributions A+(x), A-(x) come from a gauge-invariant quasi-free representation of the canonical anticommutation relations (CAR). If the space X is discrete and divided into two disjoint parts, X1 and X2, by exchanging particles and holes on the X2 part of the space, one obtains from a determinantal point process with a self-adjoint correlation operator K the determinantal point process with the J-self-adjoint correlation operator K=KP1+(1-K)P2. Here Pi is the orthogonal projection of L2(X,σ) onto L2(Xi,σ). In the case where the space X is continuous, the exchange of particles and holes makes no sense. Instead, we apply a Bogoliubov transformation to a gauge-invariant quasi-free representation of the CAR. This transformation acts identically on the X1 part of the space and exchanges the creation operators A+(x) and the annihilation operators A-(x) for x∈ X2. This leads to a quasi-free representation of the CAR, which is not anymore gauge-invariant. We prove that the joint spectral measure of the corresponding particle density is the determinantal point process with the correlation operator K.