Thermodynamic Casimir forces in strongly anisotropic systems within the N ∞ class

Abstract

We analyze the thermodynamic Casimir effect in strongly anizotropic systems from the vectorial N∞ class in a slab geometry. Employing the imperfect (mean-field) Bose gas as a representative example, we demonstrate the key role of spatial dimensionality d in determining the character of the effective fluctuation-mediated interaction between the confining walls. For a particular, physically conceivable choice of anisotropic dispersion and periodic boundary conditions, we show that the Casimir force at criticality as well as within the low-temperature phase is repulsive for dimensionality d∈ (52,4) (6,8) (10,12)… and attractive for d∈ (4,6) (8,10) …. We argue, that for d∈\4,6,8…\ the Casimir interaction entirely vanishes in the scaling limit. We discuss implications of our results for systems characterized by 1/N>0 and possible realizations in the context of quantum phase transitions.