Gauge-invriant quasi-free states on the algebra of the anyon commutation relations

Abstract

Let X= R2 and let q∈ C, |q|=1. For x=(x1,x2) and y=(y1,y2) from X2, we define a function Q(x,y) to be equal to q if x1<y1, to q if x1>y1, and to q if x1=y1. Let ∂x+, ∂x- (x∈ X) be operator-valued distributions such that ∂x+ is the adjoint of ∂x-. We say that ∂x+, ∂x- satisfy the anyon commutation relations (ACR) if ∂+x∂y+=Q(y,x)∂y+∂x+ for x y and ∂-x∂y+=δ(x-y)+Q(x,y)∂y+∂-x for (x,y)∈ X2. In particular, for q=1, the ACR become the canonical commutation relations and for q=-1, the ACR become the canonical anticommutation relations. We define the ACR algebra as the algebra generated by operator-valued integrals of ∂x+, ∂x-. We construct a class of gauge-invariant quasi-free states on the ACR algebra. Each state from this class is completely determined by a positive self-adjoint operator T on the real space L2(X,dx) which commutes with any operator of multiplication by a bounded function (x1). In the case q<0, the operator T additionally satisfies 0 T -1/ q. Further, for T=2 1 (>0), we discuss the corresponding particle density (x):=∂x+∂x-. For q∈(0,1], using a renormalization, we rigorously define a vacuum state on the commutative algebra generated by operator-valued integrals of (x). This state is given by a negative binomial point process. A scaling limit of these states as ∞ gives the gamma random measure, depending on parameter q.