Collaborative Research: Computational and theoretical approaches for the morphological control of material microstructures

合作研究：材料微观结构形态控制的计算和理论方法

• 批准号: 0914923
• 负责人: Shuwang Li
• 金额: $ 26.03万
• 依托单位: Illinois Institute of Technology
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-08-01 至 2013-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0914923&HistoricalAwards=false
• 关键词: Collaborative; Research; Computational; theoretical; approaches

This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5). The investigator and colleagues study the prediction and morphological control of two-phase microstructures in solid/liquid and solid/solid diffusional phase transitions. Much of the research in this area is concerned with detailed and extensive studies of complex patterns such as dendritic growing shapes. In many applications (e.g. castings), it is desirable to control the formation of dendrites and grow compact shapes, which, however, has been much less studied. This project helps to fill the gap and aims to develop guidelines by which microstructures with desired shapes may be grown. The research team plans to (1) develop a suitable nonlinear theory of compact precipitate growth including existence, uniqueness, and stability of self-similar shapes; (2) develop and employ state-of-the-art adaptive 3D numerical methods to test the validity and limitations of theory;(3) compare theoretical and numerical results with existing experiments to test the validity of the mathematical assumptions and to verify the accuracy of predictions derived from the theory and simulations.Diffusional phase transformations deal with transformations of melts into precipitates (and vice-versa) as well as the separation of solids (e.g. metal alloys) into distinct phases. These phenomena have importance for a variety of processes including casting, welding and soldering, crystal growth, and related problems concerning protein and macromolecular crystallization. For example, crystal growth processes for technological applications began in the late 19th century, and form the cornerstone of virtually all modern semiconductor electronics and photonics today. The research activities will provide new mathematical theory and numerical simulations that can be used to develop guidelines for controlling the morphology of certain solidified materials. The new mathematical theory and adaptive numerical methods developed in the project have applications to a broader set of related problems including multiphase flows, biostructures and growth of solid tumors. In addition, this project will provide valuable interdisciplinary training opportunities for young researchers.

该奖项是根据2009年美国复苏和再投资法案（公法111-5）资助的。研究人员及其同事研究了固/液和固/固扩散相变中两相微观结构的预测和形态控制。这一领域的大部分研究都是关于复杂模式的详细和广泛的研究，如树枝状生长的形状。在许多应用中（例如铸件），需要控制枝晶的形成并生长致密的形状，然而，这方面的研究要少得多。 该项目有助于填补这一差距，并旨在制定具有所需形状的微结构可以生长的指导方针。 研究小组计划（1）开发一个合适的紧凑沉淀物生长的非线性理论，包括自相似形状的存在性、唯一性和稳定性;（2）开发和使用最先进的自适应3D数值方法来测试理论的有效性和局限性;（三）将理论和数值计算结果与已有的实验结果进行比较，以检验数学假设的有效性，并验证其准确性扩散相变处理的是熔体转化为沉淀物（反之亦然）以及固体（例如金属合金）分离成不同的相。 这些现象对于包括铸造、焊接和钎焊、晶体生长以及与蛋白质和大分子结晶有关的相关问题在内的各种工艺具有重要意义。 例如，用于技术应用的晶体生长工艺开始于世纪后期，并且形成了今天几乎所有现代半导体电子学和光子学的基石。研究活动将提供新的数学理论和数值模拟，可用于制定控制某些固化材料形态的指导方针。 该项目开发的新数学理论和自适应数值方法可应用于更广泛的相关问题，包括多相流，生物结构和实体肿瘤的生长。此外，该项目将为年轻研究人员提供宝贵的跨学科培训机会。