Massive Field-Theory Approach to Surface Critical Behavior in Three-Dimensional Systems
Abstract
The massive field-theory approach for studying critical behavior in fixed space dimensions d<4 is extended to systems with surfaces.This enables one to study surface critical behavior directly in dimensions d<4 without having to resort to the ε expansion. The approach is elaborated for the representative case of the semi-infinite |φ|4 n-vector model with a boundary term 1/2 c0∫∂ Vφ2 in the action. To make the theory uv finite in bulk dimensions 3 d<4, a renormalization of the surface enhancement c0 is required in addition to the standard mass renormalization. Adequate normalization conditions for the renormalized theory are given. This theory involves two mass parameter: the usual bulk `mass' (inverse correlation length) m, and the renormalized surface enhancement c. Thus the surface renormalization factors depend on the renormalized coupling constant u and the ratio c/m. The special and ordinary surface transitions correspond to the limits m 0 with c/m 0 and c/m∞, respectively. It is shown that the surface-enhancement renormalization turns into an additive renormalization in the limit c/m∞. The renormalization factors and exponent functions with c/m=0 and c/m=∞ that are needed to determine the surface critical exponents of the special and ordinary transitions are calculated to two-loop order. The associated series expansions are analyzed by Pad\'e-Borel summation techniques. The resulting numerical estimates for the surface critical exponents are in good agreement with recent Monte Carlo simulations. This also holds for the surface crossover exponent .
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