Scaling theory of continuous symmetry breaking under advection

Abstract

In this work, we discuss how the linear and non-linear advection terms modify the scaling behavior of the continuous symmetry breaking and stabilize the long-range order, even in d=2 far from equilibrium, by means of simple scaling arguments. For an example of the liner advection, we consider the O(n) model in the steady shear. Our scaling analysis reveals that the model can undergo the continuous symmetry breaking even in d=2 and, moreover, predicts the upper critical dimension d up=2. These results are fully consistent with a recent numerical simulation of the O(2) model, where the mean-field critical exponents are observed even in d=2. For an example of the non-linear advection, we consider the Toner-Tu hydrodynamic theory, which was introduced to explain polar-ordered flocks, such as the Vicsek model. Our simple scaling argument reproduces the previous results by the dynamical renormalization theory. Furthermore, we discuss the effects of the additional non-linear terms discovered by the recent re-analysis of the hydrodynamic equation. Our scaling argument predicts that the additional non-linear terms modify the scaling exponents and, in particular, recover the isotropic scaling reported in a previous numerical simulation of the Vicsek model. We discuss that the critical exponents predicted by the naive scaling theory become exact in d=2 by using a symmetry consideration and similar argument proposed by Toner and Tu.