Minimal Energy Dissipation Rate and Director Orientation Relative to External Dissipative Fields such as Temperature and Velocity Gradients in Nematic and Cholestric Liquid Crystals

S. Sarman, Yong-lei Wang, A. Laaksonen
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引用次数: 1

Abstract

: The purpose of this review article is to summarize observations accumulated over the years on director alignment phenomena in nematic and cholesteric liquid crystals by molecular dynamics simulation of molecular model systems and by experiment on real systems. The main focus is on the alignment angle between the director and external dissipative fields such as velocity gradients in various flow geometries and temperature gradients doing irreversible work on the system. A general observation is that the director attains an orientation relative to the field where the energy dissipation rate is minimal in the steady state. In the case of planar elongational flow, it can be proven by using symmetry arguments that the energy dissipation rate must be either maximal or minimal and simulations have shown that is minimal. In planar Couette flow both simulations and experiments imply that the energy dissipation rate is minimal in the steady state. Finally, in the case of heat conduction, symmetry arguments imply that the energy dissipation rate must be either minimal or maximal and simulations and experiments indicate that it is minimal. All these observations can be explained by applying a recently proven theorem according to which the energy dissipation rate is minimal in the steady state in the linear regime at low fields.
向列型和胆甾型液晶中相对于外部耗散场(如温度和速度梯度)的最小能量耗散率和指向
本文综述了近年来通过分子模型系统的分子动力学模拟和实际系统的实验,对向列型和胆甾型液晶中定向取向现象的观察结果进行了总结。主要关注的是导向器和外部耗散场之间的对准角度,例如各种流动几何形状的速度梯度和温度梯度对系统产生不可逆的作用。一般的观察结果是,在稳态中,指导者获得了一个相对于能量耗散率最小的场的方向。在平面延伸流的情况下,利用对称性论证可以证明能量耗散率要么是最大的,要么是最小的,模拟结果表明耗散率是最小的。在平面库埃特流中,模拟和实验均表明稳态时能量耗散率最小。最后,在热传导的情况下,对称论点意味着能量耗散率必须是最小或最大的,模拟和实验表明它是最小的。所有这些观测都可以用最近证明的一个定理来解释,根据这个定理,在低场的线性状态下,能量耗散率在稳定状态下是最小的。
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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