Crossover from low-temperature to high-temperature fluctuations. I. Thermodynamic Casimir forces of isotropic systems

Abstract

We study the crossover from low- to high-temperature fluctuations including critical fluctuations in confined isotropic O(n)-symmetric systems on the basis of a finite-size renormalization-group approach at fixed dimension d introduced previously [V. Dohm, Phys. Rev. Lett. 110, 107207 (2013)]. Our theory is formulated within the 4 lattice model in a d-dimensional block geometry with periodic boundary conditions. We derive the finite-size scaling functions F ex and X of the excess free energy density and of the thermodynamic Casimir force, respectively, for 1≤ n ≤ ∞, 2<d<4. Applications are given for Ld-1 × L slab geometries with a finite aspect ratio =L/L as well as for the film limit 0 at fixed L. For n=1 and =0 the low-temperature limits of F ex and X vanish whereas they are finite for n≥ 2 and = 0 due to the effect of the Goldstone modes. For n=1 and >0 we find a finite low-temperature limit of F ex which deviates from that of the the Ising model. We attribute this deviation to the nonuniversal difference between the 4 model with continuous variables and the Ising model with discrete spin variables s=1. For n≥ 2 and >0, a logarithmic divergence of F ex in the low-temperature limit is predicted, in excellent agreement with Monte Carlo (MC) data for the d=3 XY model. For 2≤ n ≤ ∞ and 0≤ <0=0.8567 the Goldstone modes generate a negative (attractive) low-temperature Casimir force that vanishes for = 0 and becomes positive (repulsive) for > 0. Our predictions are compared with MC data for Ising, XY, and Heisenberg models in slab geometries with 0.01≤≤1. Good overall agreement is found.