Two-Dimensional Elliptic Determinantal Point Processes and Related Systems

Abstract

We introduce new families of determinantal point processes (DPPs) on a complex plane C, which are classified into seven types following the irreducible reduced affine root systems, RN=AN-1, BN, BN, CN, CN, BCN, DN, N ∈ N. Their multivariate probability densities are doubly periodic with periods (L, iW), 0 < L, W < ∞, i=-1. The construction is based on the orthogonality relations with respect to the double integrals over the fundamental domain, [0, L) × i [0, W), which are proved in this paper for the RN-theta functions introduced by Rosengren and Schlosser. In the scaling limit N ∞, L ∞ with constant density =N/(LW) and constant W, we obtain four types of DPPs with an infinite number of points on C, which have periodicity with period i W. In the further limit W ∞ with constant , they are degenerated into three infinite-dimensional DPPs. One of them is uniform on C and equivalent with the Ginibre point process studied in random matrix theory, while other two systems are rotationally symmetric around the origin, but non-uniform on C. We show that the elliptic DPP of type AN-1 is identified with the particle section, obtained by subtracting the background effect, of the two-dimensional exactly solvable model for one-component plasma studied by Forrester. Other two exactly solvable models of one-component plasma are constructed associated with the elliptic DPPs of types CN and DN. Relationship to the Gaussian free field on a torus is discussed for these three exactly solvable plasma models.