UNS: Collaborative Research: Dynamics of Active Particles in Anisotropic Fluids

UNS：合作研究：各向异性流体中活性粒子的动力学

• 批准号: 1852379
• 负责人: Nicholas Abbott
• 金额: $ 4.35万
• 依托单位: Cornell University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2018
• 资助国家: 美国
• 起止时间: 2018-08-09 至 2019-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1852379&HistoricalAwards=false
• 关键词: UNS; Collaborative; Research; Dynamics; Active

1510949(Cordova) & 1508987(Abbott)The goal of the proposed research is to investigate with both experiments and computations the behavior of complex, anisotropic active fluids. Active fluids are fluids that behave in unique ways, because of the presence of active particles that can self-assemble, or can move and pack in different ways, giving different macroscopic properties to the fluid. The proposed research can uncover novel phenomena that could be exploited for design new fluid materials that are responsive to their external environment. Past studies have focused largely on the physics of "active colloids" in isotropic Newtonian fluids, yet many future applications of active fluids would require an understanding of their behavior in complex fluids. This is the white space that this proposal covers: how anisotropy in the viscoelastic properties of a fluid can impact fundamental transport phenomena involving active colloids. A first research thrust will focus on the effect of the anisotropic environment of a liquid crystal suspension has on the diffusivity of a self-propelled particle within the suspension. Specifically, Brownian Dynamics (BD) simulations will be combined with experiments involving tracking of single self-propelled colloidal Janus particles at the interface of a nematic liquid crystal. A second thrust will focus on the effects of a suspension of active particles hosted within an anisotropic fluid on the diffusion of passive tracer particles. Motile bacteria dispersed within biocompatible liquid crystals will be used to explore how passive particles diffuse in the presence of the motion of the rod-shaped bacteria. The overall outcome of this integrated program of experiment and simulation will be new knowledge regarding fundamental transport processes driven by internally generated gradients in complex fluids. The collaborating group will establish a collaboration with the Teacher Preparation Program at the University of Puerto Rico Mayaguez to develop, disseminate and assess bilingual educational modules. Educational activities are proposed to expose students to cross-cultural educational experiences and to prepare them to work in diverse settings. An interdisciplinary class on soft matter will be offered to students at both institutions.

1510949(科尔多瓦)&&1508987(雅培)拟议研究的目标是通过实验和计算来研究复杂的、各向异性的活性流体的行为。活性流体是以独特方式表现的流体，因为活性颗粒的存在可以自组装，或者可以以不同的方式移动和填充，从而赋予流体不同的宏观性质。这项拟议的研究可以揭示新的现象，可以用来设计对外部环境做出反应的新流体材料。过去的研究主要集中在各向同性牛顿流体中的“活性胶体”的物理学上，然而，活性流体的许多未来应用都需要了解它们在复杂流体中的行为。这就是这项建议所涵盖的空白：流体粘弹性性质的各向异性如何影响涉及活性胶体的基本传输现象。第一个研究重点将集中在液晶悬浮液的各向异性环境对悬浮液中自推进粒子的扩散系数的影响。具体地说，布朗动力学(BD)模拟将与涉及跟踪向列相液晶界面上的单个自推进胶体Janus粒子的实验相结合。第二个推力将集中在各向异性流体中的活性颗粒悬浮对被动示踪剂颗粒扩散的影响。分散在生物相容液晶中的可移动细菌将被用来探索在杆状细菌运动存在的情况下被动粒子是如何扩散的。这一实验和模拟综合计划的总体结果将是关于复杂流体中由内部产生的梯度驱动的基本传输过程的新知识。合作小组将与波多黎各大学教师培训方案合作，开发、传播和评估双语教学模块。教育活动是为了让学生接触到跨文化的教育经验，并为他们在不同的环境中工作做好准备。两所大学都将开设软物质跨学科课程。