Critical free energy and Casimir forces in rectangular geometries

Abstract

We study the critical behavior of the free energy and the thermodynamic Casimir force in a Ld-1 × L block geometry in 2<d<4 dimensions with aspect ratio =L/L above, at, and below Tc on the basis of the O(n) symmetric φ4 lattice model with periodic boundary conditions (b.c.). We consider a simple-cubic lattice with isotropic short-range interactions. Exact results are derived in the large - n limit describing the geometric crossover from film ( =0) over cubic =1 to cylindrical ( = ∞) geometries. For n=1, three perturbation approaches are presented that cover both the central finite-size regime near Tc for 1/4 3 and the region outside the central finite-size regime well above and below Tc for arbitrary . At bulk Tc of isotropic systems with periodic b.c., we predict the critical Casimir force in the vertical (L) direction to be negative (attractive) for a slab ( < 1), positive (repulsive) for a rod ( > 1), and zero for a cube (=1). We also present extrapolations to the cylinder limit (=∞) and to the film limit (=0) for n=1 and d=3. Our analytic results for finite-size scaling functions in the minimal renormalization scheme at fixed dimension d=3 agree well with Monte Carlo data for the three-dimensional Ising model by Hasenbusch for =1 and by Vasilyev et al. for =1/6 above, at, and below Tc.