Statics and Kinetics at the Nematic-Isotropic Interface: Effects of Biaxiality

V. Popa-Nita, T. Sluckin, A. A. Wheeler
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引用次数: 30

Abstract

We use the Landau-de Gennes theory of a nematic liquid crystal to investigate anew aspects of the properties of the interface between the isotropic and nematic liquid crystal phases of the same fluid. The equations of the static interface have been solved, both numerically and using asymptotic analysis, with an emphasis on the effect of inclusion of the order parameter biaxiality on the physical properties. We have compared the results of the exact solutions to the commonly used de Gennes ansatz, which assumes positive and uniform unixiality through the interface. Although the de Gennes ansatz in general gives good results, when bend and splay elastic constants dominate over the twist constants, it can lead to errors of up to 10% in the surface energy. The asymptotic analysis also shows that, by contrast with the de Gennes ansatz, the order parameter wings in the isotropic phase exhibit negative order parameter, with principal axis perpendicular to the surface. For moving interfaces, using an approximation which at this stage does not yet include hydrodynamic coupling, we have compared our results with the analogue of the de Gennes ansatz used by the present authors in an earlier paper. We find that including biaxiality leads to larger effects in the dynamic than in the static properties, and that whereas this is essentially a perturbation to the energy, the velocity of the moving interface can be significantly slowed down. The slowing down effects are strongly correlated with surface biaxiality, but both effects seem to be diminished when the isotropic phase is advancing.
向列-各向同性界面的静力学和动力学:双轴性的影响
我们利用向列液晶的朗道-德-热纳理论来研究相同流体的各向同性和向列液晶相之间的界面特性的新方面。本文用数值方法和渐近分析方法求解了静界面方程,重点讨论了双轴序参数的加入对其物理性质的影响。我们将精确解的结果与常用的de Gennes ansatz进行了比较,后者假设了通过界面的正一致唯一性。尽管de Gennes ansatz通常给出了很好的结果,但当弯曲和伸展弹性常数占主导地位时,它可能导致表面能误差高达10%。渐近分析还表明,与de Gennes ansatz相比,各向同性相的阶参数翼呈现负阶参数,主轴垂直于表面。对于移动界面,我们使用了一种目前还不包括流体动力耦合的近似,将我们的结果与本作者在早期论文中使用的德热纳分析的模拟结果进行了比较。我们发现,包括双轴性导致更大的影响,在动态比静态性质,而这本质上是一个扰动的能量,移动界面的速度可以显著减慢。减缓效应与表面双轴性密切相关,但当各向同性相推进时,这两种效应似乎都减弱了。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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