Asymptotics of the partition function for β-ensembles at high temperature
Abstract
We consider the real β-ensemble (or 1D log-gas) of dimension N in the high-temperature regime, i.e. where the inverse temperature β scales as Nβ=2P with P a fixed positive parameter. We establish the large-N asymptotic expansion at all orders of the partition function: equation* ZN[V]=∫RNΠi<jN |xi-xj|2PN·Πi=1Ne-V(xi) dxi equation* for V(x)=x2+φ(x) with φ a bounded smooth function, and identify the first two terms of this expansion. In this regime, the energy no longer dominates the entropy, as in the fixed-β case, but rather scales at the same order in N. Consequently, at large N, the system is macroscopically described by the so-called thermal equilibrium measure which is supported on the entire real line. Our proof relies on the loop equations method, previously applied in the fixed-β setting in BoG1,BoG2, and provides the first example in which this approach can be successfully implemented using the thermal equilibrium measure. This requires a detailed understanding of both the thermal equilibrium measure and the associated master operator, an unbounded differential operator, leading to several new analytical challenges. In this setting, we carry out a technically involved analysis to obtain precise estimates for the inverse of the master operator in suitable functional norms. In addition we establish, through subtle operator arguments, a crucial continuity property of the equilibrium density with respect to the potential dependence. These two results constitute the main novelties of the paper and allow us to exhibit a new class of multiple integrals for which such an expansion can be obtained, while providing a deeper understanding of the thermal equilibrium measure and its properties.
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