Dynamical renormalization group analysis of O(n) model in steady shear flow

Abstract

We study the critical behavior of the O(n) model under steady shear flow using a dynamical renormalization group (RG) method. Incorporating the strong anisotropy in scaling ansatz, which has been neglected in earlier RG analyses, we identify a new stable Gaussian fixed point. This fixed point reproduces the anisotropic scaling of static and dynamical critical exponents for both non-conserved (Model A) and conserved (Model B) order parameters. Notably, the upper critical dimensions are dup = 2 for the non-conserved order parameter (Model A) and dup = 0 for the conserved order parameter (Model B), implying that the mean-field critical exponents are observed even in both d=2 and 3 dimensions. Furthermore, the scaling exponent of the order parameter is negative for all dimensions d ≥ 2, indicating that shear flow stabilizes the long-range order associated with continuous symmetry breaking even in d = 2. In other words, the lower critical dimensions are d low < 2 for both types of order parameters. This contrasts with equilibrium systems, where the Hohenberg -- Mermin -- Wagner theorem prohibits continuous symmetry breaking in d = 2.