Cumulants and large deviations for the linear statistics of the one-dimensional trapped Riesz gas

Abstract

We consider the classical trapped Riesz gas, i.e., N particles at positions xi in one dimension with a repulsive power law interacting potential 1/|xi-xj|k, with k>-2, in an external confining potential of the form V(x) |x|n. We focus on the equilibrium Gibbs state of the gas, for which the density has a finite support [-0/2,0/2]. We study the fluctuations of the linear statistics LN = Σi=1N f(xi) in the large N limit for smooth functions f(x). We obtain analytic formulae for the cumulants of LN for general k>-2. For long range interactions, i.e. k<1, which include the log-gas (k 0) and the Coulomb gas (k =-1) these are obtained for monomials f(x)= |x|m. For short range interactions, i.e. k>1, which include the Calogero-Moser model, i.e. k=2, we compute the third cumulant of LN for general f(x) and arbitrary cumulants for monomials f(x)= |x|m. We also obtain the large deviation form of the probability distribution of LN, which exhibits an "evaporation transition" where the fluctuation of LN is dominated by the one of the largest xi. In addition, in the short range case, we extend our results to a (non-smooth) indicator function f(x), obtaining thereby the higher order cumulants for the full counting statistics of the number of particles in an interval [-L/2,L/2]. We show in particular that they exhibit an interesting scaling form as L/2 approaches the edge of the gas L/0 1, which we relate to the large deviations of the emptiness probability of the complementary interval on the real line.