Lavrentovich Oleg D
Advanced Materials and Liquid Crystal Institute, Department of Physics, Materials Science Graduate Program, Kent State University, Kent, OH 44242, USA.
Liq Cryst Rev. 2020;8(2):59-129. doi: 10.1080/21680396.2021.1919576. Epub 2021 May 26.
The dynamics of small particles, both living such as swimming bacteria and inanimate, such as colloidal spheres, has fascinated scientists for centuries. If one could learn how to control and streamline their chaotic motion, that would open technological opportunities in the transformation of stored or environmental energy into systematic motion, with applications in micro-robotics, transport of matter, guided morphogenesis. This review presents an approach to command microscale dynamics by replacing an isotropic medium with a liquid crystal. Orientational order and associated properties, such as elasticity, surface anchoring, and bulk anisotropy, enable new dynamic effects, ranging from the appearance and propagation of particle-like solitary waves to self-locomotion of an active droplet. By using photoalignment, the liquid crystal can be patterned into predesigned structures. In the presence of the electric field, these patterns enable the transport of solid and fluid particles through nonlinear electrokinetics rooted in anisotropy of conductivity and permittivity. Director patterns command the dynamics of swimming bacteria, guiding their trajectories, polarity of swimming, and distribution in space. This guidance is of a higher level of complexity than a simple following of the director by rod-like microorganisms. Namely, the director gradients mediate hydrodynamic interactions of bacteria to produce an active force and collective polar modes of swimming. The patterned director could also be engraved in a liquid crystal elastomer. When an elastomer coating is activated by heat or light, these patterns produce a deterministic surface topography. The director gradients define an activation force that shapes the elastomer in a manner similar to the active stresses triggering flows in active nematics. The patterned elastomer substrates could be used to define the orientation of cells in living tissues. The liquid-crystal guidance holds a major promise in achieving the goal of commanding microscale active flows.
几个世纪以来,小颗粒的动力学一直吸引着科学家,这些小颗粒包括有生命的(如游动的细菌)和无生命的(如胶体球)。如果能够学会如何控制和简化它们的混沌运动,将为把储存的能量或环境能量转化为系统运动带来技术机遇,可应用于微型机器人技术、物质运输、引导形态发生等领域。本综述提出了一种通过用液晶取代各向同性介质来控制微观尺度动力学的方法。取向有序以及相关特性,如弹性、表面锚定和体各向异性,能够产生新的动力学效应,从类粒子孤立波的出现和传播到活性液滴的自推进。通过光取向,液晶可以被图案化为预先设计的结构。在电场存在的情况下,这些图案能够通过基于电导率和介电常数各向异性的非线性电动学实现固体和流体颗粒的运输。指向矢图案控制着游动细菌的动力学,引导它们的轨迹、游动极性和空间分布。这种引导比棒状微生物简单地跟随指向矢要复杂得多。也就是说,指向矢梯度介导细菌的流体动力相互作用以产生活性力和集体游动极性模式。图案化的指向矢也可以刻在液晶弹性体中。当弹性体涂层被热或光激活时,这些图案会产生确定性的表面形貌。指向矢梯度定义了一种激活力,它以类似于触发活性向列相流动的活性应力的方式塑造弹性体。图案化的弹性体基底可用于确定活组织中细胞的取向。液晶引导在实现控制微观尺度活性流的目标方面具有重大前景。