On the asymptotic limit for the dynamic isotropic-nematic phase transition with anisotropic elasticity

Abstract

In this paper, we consider the isotropic-nematic phase transition with anisotropic elasticity governed by the Landau-de Gennes dynamics of liquid crystals. For -32< L<0, we rigorously justify the limit from the Landau-de Gennes flow to a sharp interface system characterized by a two-phase flow: The interface evolves via motion by mean curvature; In the isotropic region, Q=0; In the nematic region, Q=s+(nn-13I) with n∈ S2 and s+>0, where the alignment vector field n satisfies (2s+2∂t n+h)× n=0 and h=-δ E(n,∇ n)δ n with E(n,∇ n) denoting the Oseen-Frank energy; On the interface, the strong anchoring condition n= is satisfied. This result rigorously verifies a claim made by de Gennes [Mol. Cryst. Liq. Cryst. 1971] regarding the surface tension strength of isotropic-nematic interfaces in dynamical settings. Furthermore, we rigorously justify this limit using the method of matched asymptotic expansions. First, we employ the idea of ``quasi-minimal connecting orbits'' developed by Fei-Lin-Wang-Zhang [Invent.math. 2023] to construct approximated solutions up to arbitrary order. Second, we derive a uniform spectral lower bound for the linearized operator around the approximate solution. To achieve this, we introduce a suitable basis decomposition and a coordinate transformation to reduce the problem to spectral analysis of two scalar one-dimensional linear operators and some singular product estimates. To address the difficulties arising from anisotropic elasticity and the strong anchoring boundary condition, we introduce a div-curl decomposition and, when estimating the cross terms, combine these with the anisotropic elastic terms to close the energy estimates.