FRG: Collaborative Research: Dynamics of Thin Liquid Films: Mathematics and Experiments

FRG：合作研究：薄液膜动力学：数学和实验

• 批准号: 0968258
• 负责人: Michael Shearer
• 金额: $ 78.1万
• 依托单位: North Carolina State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-06-01 至 2015-05-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0968258&HistoricalAwards=false
• 关键词: FRG; Collaborative; Research; Dynamics; Thin

The science of thin liquid films has developed rapidly in recent years, with applications to coating flows, biofluids, microfluidic engineering, and medicine. In this project, we will focus on three groups of free-surface flow problems using a combination of mathematical modeling, analysis and numerical simulation, coupled to carefully chosen quantitative experiments. The three areas are: (i) flows driven by surface tension gradients, (ii) the role of inertia in regimes where lubrication is inadequate to model thin film flow, and (iii) vibrating thin films. Advances in our understanding of theoretical issues surrounding modeling these flows, and the exploration of new features of the flows through experiments will have direct applications to improving control and reliability of manufacturing processes in high-tech industries and to biomedical systems. The flow of thin liquid layers or films occurs in contexts including industrial coating flows, microfluidic engineering, and medicine. In this project, we focus on properties of thin liquid films such as the role of surface tension in driving flow, and the behavior of thin layers under rapid vibration. Surface tension is an important mechanism in the dynamics of mucus layers in the lung, and is central to the treatment of premature infants by surfactant replacement therapy. The control of thin layer flow, through the temperature dependence of surface tension or using rapid vibrations, has the potential to eliminate damaging nonuniformities in industrial coating processes. Each of these areas and applications pose substantial scientific challenges that will be met with a collaborative effort between mathematicians and physicists, exploring theoretical and experimental methods in tandem. The project includes graduate and undergraduate student training in an interdisciplinary research program that will develop coordinated advanced skills in physics, engineering, and applied mathematics.

近年来，液体薄膜科学发展迅速，在涂层流、生物流体、微流体工程和医学等方面有着广泛的应用。在这个项目中，我们将集中在三组自由表面流动问题，使用数学建模，分析和数值模拟相结合，再加上精心选择的定量实验。这三个领域是：（i）由表面张力梯度驱动的流动，（ii）在润滑不足以模拟薄膜流动的情况下惯性的作用，以及（iii）振动薄膜。在我们的理解的理论问题，围绕这些流动建模的进展，并通过实验的流动的新功能的探索将有直接的应用程序，以提高控制和可靠性的制造过程中的高科技产业和生物医学系统。薄液体层或薄膜的流动发生在包括工业涂覆流、微流体工程和医学的背景下。在这个项目中，我们专注于薄液膜的性质，如表面张力在驱动流动中的作用，以及快速振动下薄层的行为。 表面张力是肺中粘液层动力学的重要机制，并且是通过表面活性剂替代疗法治疗早产儿的核心。通过表面张力的温度依赖性或使用快速振动来控制薄层流动，具有消除工业涂覆过程中的破坏性不均匀性的潜力。这些领域和应用中的每一个都提出了重大的科学挑战，这些挑战将通过数学家和物理学家之间的合作努力来解决，同时探索理论和实验方法。该项目包括研究生和本科生培训的跨学科研究计划，将发展协调的先进技能，在物理，工程和应用数学。