Interplay of complete wetting, critical adsorption, and capillary condensation

Abstract

The excess adsorption in two-dimensional Ising strips (∞ × L) subject to identical boundary fields, at both one-dimensional surfaces decaying in the orthogonal direction j as -h1j-p, is studied for various values of p and along various thermodynamic paths below the critical point by means of the density-matrix renormalization-group method. The crossover behavior between the complete wetting and critical adsorption regimes, occurring in semi-infinite systems, are strongly influenced by confinement effects. Along isotherms T=const the asymptotic power law dependences on the external bulk field, which characterize these two regimes, are undercut by capillary condensation. Along the pseudo first-order phase coexistence line of the strips, which varies with temperature, we find a broad crossover regime where both the thickness of the wetting film and increase as function of the reduced temperature τ but do not follow any power law. Above the wetting temperature the order parameter profiles are not slab-like but exhibit wide interfacial variations and pronounced tails. Inter alia, our explicit calculations demonstrate that, contrary to opposite claims by Kroll and Lipowsky [Phys. Rev. B 28, 5273 (1983)], for p=2 critical wetting transitions do exist and we determine the corresponding wetting phase diagram in the (h1,T) plane.