Truncated linear statistics in the one dimensional one-component plasma

Abstract

In this paper, we study the probability distribution of the observable s = (1/N)Σi=N-N'+1N xi, with 1 ≤ N' ≤ N and x1<x2<·s< xN representing the ordered positions of N particles in a 1d one-component plasma, i.e., N harmonically confined charges on a line, with pairwise repulsive 1d Coulomb interaction |xi-xj|. This observable represents an example of a truncated linear statistics -- here the center of mass of the N' = \, N (with 0 < ≤ 1) rightmost particles. It interpolates between the position of the rightmost particle (in the limit 0) and the full center of mass (in the limit 1). We show that, for large N, s fluctuates around its mean s and the typical fluctuations are Gaussian, of width O(N-3/2). The atypical large fluctuations of s, for fixed , are instead described by a large deviation form PN, (s) [-N3 φ(s)], where the rate function φ(s) is computed analytically. We show that φ(s) takes different functional forms in five distinct regions in the (,s) plane separated by phase boundaries, thus leading to a rich phase diagram in the (,s) plane. Across all the phase boundaries the rate function φ(,s) undergoes a third-order phase transition. This rate function is also evaluated numerically using a sophisticated importance sampling method, and we find a perfect agreement with our analytical predictions.