Linear statistics at the microscopic scale for the 2D Coulomb gas
Abstract
We consider the classical Coulomb gas in two dimensions at the inverse temperature β=2, confined within a droplet of radius R by a rotationally invariant potential U(r). For U(r) r2 this describes the eigenvalues of the complex Ginibre ensemble of random matrices. We study linear statistics of the form LN = Σi=1N f(| xi|), where xi's are the positions of the N particles, in the large N limit with R=O(1). It is known that for smooth functions f(r) the variance Var \, LN= O(1), while for an indicator function relevant for the disk counting statistics, all cumulants of LN of order q ≥ 2 behave as N. In addition, for smooth functions, it was shown that the cumulants of LN of order q ≥ 3 scale as N2-q. Surprisingly it was found that they depend only on f'(| x|) and its derivatives evaluated exactly at the boundary of the droplet. To understand this property, and interpolate between the two behaviors (smooth versus step-like), we study the microscopic linear statistics given by f(r) fN(r) = φ((r- r) N/), which probes the fluctuations at the scale of the inter-particle distance. We compute the cumulants of LN at large N for a fixed φ(u) at arbitrary . For large they match the predictions for smooth functions which shows that the leading contribution in that case comes from a boundary layer of size 1/N near the boundary of the droplet. Finally we show that the full probability distribution of LN take two distinct large deviation forms, in the regime LN N and LN N respectively. We also discuss applications of our results to fermions in a rotating harmonic trap and to the Ginibre symplectic ensemble.
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