Critical Casimir amplitudes for n-component φ4 models with O(n)-symmetry breaking quadratic boundary terms

Abstract

Euclidean n-component φ4 theories whose Hamiltonians are O(n) symmetric except for quadratic symmetry breaking boundary terms are studied in films of thickness L. The boundary terms imply the Robin boundary conditions ∂nφα =c(j)α φα at the boundary planes Bj=1,2 at z=0 and z=L. Particular attention is paid to the cases in which mj of the n variables c(j)α take the special value cmj-sp corresponding to critical enhancement while the remaining ones are subcritically enhanced. Under these conditions, the semi-infinite system bounded by Bj has a multicritical point, called mj-special, at which an O(mj) symmetric critical surface phase coexists with the O(n) symmetric bulk phase, provided d is sufficiently large. The L-dependent part of the reduced free energy per area behaves as C/Ld-1 as L∞ at the bulk critical point. The Casimir amplitudes C are determined for small ε=4-d in the general case where mc,c components φα are critically enhanced at both boundary planes, mc,D + mD,c components are enhanced at one plane but satisfy asymptotic Dirichlet boundary conditions at the respective other, and the remaining mD,D components satisfy asymptotic Dirichlet boundary conditions at both Bj. Whenever mc,c>0, these expansions involve integer and fractional powers εk/2 with k 3 (mod logarithms). Results to O(ε3/2) for general values of mc,c, mc,D+mD,c, and mD,D are used to estimate the C of 3D Heisenberg systems with surface spin anisotropies when (mc,c, mc,D+ mD,c) = (1,0), (0,1), and (1,1).