Phase transition and critical behavior in hierarchical integer-valued Gaussian and Coulomb gas models

Abstract

Given a square box n⊂eq Z2 of side length Ln with L,n>1, we study hierarchical random fields \φx x∈n\ with law proportional to e12β(φ,nφ)Πx∈n( dφx), where β>0 is the inverse temperature, n is a hierarchical Laplacian on n, and is a non-degenerate 1-periodic measure on R. Our setting includes the integer-valued Gaussian field (a.k.a. DG model or Villain Coulomb gas) and the sine-Gordon model. Relying on renormalization group analysis we derive sharp asymptotic formulas, in the limit as n∞, for the covariance φxφy and the fractional charge e2π iα(φx-φy) in the subcritical β<β c:=π2/ L, critical β=β c and slightly supercritical β>β c regimes. The field exhibits logarithmic correlations throughout albeit with a distinct β-dependence of both the covariance scale and the fractional-charge exponents in the sub/supercritical regimes. Explicit logarithmic corrections appear at the critical point.

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