Two-Loop Renormalization Group Analysis of the Burgers-Kardar-Parisi-Zhang Equation

Abstract

A systematic analysis of the Burgers--Kardar--Parisi--Zhang equation in d+1 dimensions by dynamic renormalization group theory is described. The fixed points and exponents are calculated to two--loop order. We use the dimensional regularization scheme, carefully keeping the full d dependence originating from the angular parts of the loop integrals. For dimensions less than dc=2 we find a strong--coupling fixed point, which diverges at d=2, indicating that there is non--perturbative strong--coupling behavior for all d ≥ 2. At d=1 our method yields the identical fixed point as in the one--loop approximation, and the two--loop contributions to the scaling functions are non--singular. For d>2 dimensions, there is no finite strong--coupling fixed point. In the framework of a 2+ε expansion, we find the dynamic exponent corresponding to the unstable fixed point, which describes the non--equilibrium roughening transition, to be z = 2 + O (ε3), in agreement with a recent scaling argument by Doty and Kosterlitz. Similarly, our result for the correlation length exponent at the transition is 1/ = ε + O (ε3). For the smooth phase, some aspects of the crossover from Gaussian to critical behavior are discussed.

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