Fluctuation-induced forces in strongly anisotropic critical systems

Abstract

Strongly anisotropic critical systems are considered in a d-dimensional film geometry. Such systems involve two (or more) distinct correlation lengths β and α that scale as nontrivial powers of each other, i.e.\ αβθ with anisotropy index θ 1. Thus two fundamental orientations, perpendicular () and parallel (\|), for which the surface normal is oriented along an α- and β-direction, respectively, must be distinguished. The confinement of critical fluctuations caused by the film's boundary planes is shown to induce effective forces FC that decay as FC-(∂/∂ L),\|\,L-ζ,\| as the film thickness L becomes large, where the proportionality constants involve nonuniversal amplitudes. The decay exponents ζ,\| and the Casimir amplitudes ,\| are universal but depend on the type of orientation. To corroborate these findings, n-vector models with an m-axial bulk Lifshitz point are investigated by means of RG methods below the upper critical dimension d*(m)=4+m/2 under various boundary conditions (BC). The exponents ζ,\| are determined, and explicit results to one- or two-loop order are presented for several Casimir amplitudes BC,\|. The large-n limits of the Casimir amplitudes \|BC/n for periodic and Dirichlet BC are shown to be proportional to their critical-point analogues at dimension d-m/2. The limiting values PBC\|,,∞=n∞\|,PBC/n are determined exactly for the uniaxial cases (d,m)=(3,1) under periodic BC. Unlike PBC\|,∞, PBC,∞ is positive, so that the corresponding Casimir force is repulsive.