Theory and Simulation of Complex Liquids, Solutions, Interfaces, and Nucleation Processes

复杂液体、溶液、界面和成核过程的理论和模拟

• 批准号: 1314-2013
• 负责人: Patey, Grenfell
• 金额: $ 5.03万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=632373
• 关键词: Theory; Simulation; Complex; Liquids; Solutions

This proposal is concerned with complex liquids and solutions, both in homogeneous phases and in situations where interfacial interactions are of crucial importance. The long-term objective is to gain a microscopic understanding of systems that are of both fundamental and practical importance. This is achieved by combining first principles statistical mechanical analyses with modern computer simulation methods. Principal areas of current research are as follows: (1) The Origin of Water's Anomalies and Related Questions. Water is of obvious importance, yet its unusual physical properties are not well understood at the molecular level. The objective of our work is to directly relate water's anomalies to local molecular arrangements. (2) Heterogeneous Ice Nucleation. Ice nucleation is very important in many environmental and biological systems. Our aim is to determine the characteristics of a good ice nucleus, with emphasis on atmospheric aerosol particles that are critical to ice cloud formation. (3) Crystal Nucleation and Growth from Solution. The nucleation and growth of crystals in solution is important in many physical processes. Our focus is to understand the nucleation mechanisms that determine the early stages of crystal birth. (4) Microheterogeneity in Aqueous Solutions. Aqueous solutions of some small amphiphilic molecules such as alcohols can exhibit remarkable behaviour associated with solute aggregation. We are using large-scale simulations to get a clearer picture of the physical nature of these aggregates. (5) Room Temperature Ionic Liquids. Ionic compounds that exist as liquids at room temperature are of theoretical interest, and are finding industrial application as solvents with special properties. Our focus is on understanding the important molecular features that contribute to the melting point, structure, and dynamics of these ionic liquid. (6) Adsorption and Transport of Water and Ionic Solutions in Nanopores. The objective of this project is to investigate adsorption, structure, and transport of water and ionic solutions in inhomogeneous nanopores. Such systems have relevance ranging from transport and selectivity in biological channels to the development of nanoscale fluid conduits and storage devices.

该提案涉及复杂的液体和溶液，无论是在均相中还是在界面相互作用至关重要的情况下。长期目标是获得对具有基础和实际重要性的系统的微观理解。这是通过将第一原理统计力学分析与现代计算机模拟方法相结合来实现的。目前的主要研究领域如下：（1）水异常的起源及相关问题。水的重要性显而易见，但其不寻常的物理性质在分子水平上尚未得到很好的了解。我们工作的目标是将水的异常与局部分子排列直接联系起来。 (2)异质冰核。冰核在许多环境和生物系统中非常重要。我们的目标是确定良好冰核的特征，重点关注对冰云形成至关重要的大气气溶胶颗粒。 (3)晶体成核和溶液生长。溶液中晶体的成核和生长在许多物理过程中都很重要。我们的重点是了解决定晶体诞生早期阶段的成核机制。 (4) 水溶液中的微观不均匀性。一些小两亲分子（例如醇）的水溶液可以表现出与溶质聚集相关的显着行为。我们正在使用大规模模拟来更清楚地了解这些聚集体的物理性质。 (5)室温离子液体。在室温下以液体形式存在的离子化合物具有理论上的意义，并且正在作为具有特殊性质的溶剂得到工业应用。我们的重点是了解影响这些离子液体熔点、结构和动力学的重要分子特征。 (6)纳米孔中水和离子溶液的吸附和传输。该项目的目的是研究不均匀纳米孔中水和离子溶液的吸附、结构和传输。此类系统具有从生物通道中的运输和选择性到纳米级流体导管和存储装置的开发的相关性。