基本信息
浏览量:60
职业迁徙
个人简介
Research Interests
We are applying large-scale numerical simulation and high-performance computing to better understand continuum transport and reaction in the processing of advanced materials. These exciting tools provide a means of obtaining the fundamental physical insight necessary to enable advances in many modern materials processing operations, and the sphere of accessible problems continues to enlarge with the rapid evolution of computers and numerical methods. Research areas include analyses of crystal growth processes, morphological instabilities, microstructure evolution, and colloidal crystallization (with Prof. David Norris and others). The development of efficient numerical methods are performed in support of these studies.
Our research in crystal growth is directed at understanding the complex, inherently nonlinear phenomena that control the processes used to create these materials. This understanding is motivated by needs of current and future electronic and optical systems, which require single-crystal substrates with precisely controlled properties. We are particularly interested in describing heat transfer in high-temperature melt growth systems, internal radiant heat transfer in semitransparent crystals, three-dimensional time-dependent flows in crystal growth systems, mass transfer in melt and solution growth, faceting phenomena, and morphological stability of crystal interfaces. Recent work has concentrated on the growth and properties of radiation detector crystals, such as cadmium zinc telluride, step dynamics during solution growth, and growth processes for crystalline silicon in photovoltaic devices.
We are applying large-scale numerical simulation and high-performance computing to better understand continuum transport and reaction in the processing of advanced materials. These exciting tools provide a means of obtaining the fundamental physical insight necessary to enable advances in many modern materials processing operations, and the sphere of accessible problems continues to enlarge with the rapid evolution of computers and numerical methods. Research areas include analyses of crystal growth processes, morphological instabilities, microstructure evolution, and colloidal crystallization (with Prof. David Norris and others). The development of efficient numerical methods are performed in support of these studies.
Our research in crystal growth is directed at understanding the complex, inherently nonlinear phenomena that control the processes used to create these materials. This understanding is motivated by needs of current and future electronic and optical systems, which require single-crystal substrates with precisely controlled properties. We are particularly interested in describing heat transfer in high-temperature melt growth systems, internal radiant heat transfer in semitransparent crystals, three-dimensional time-dependent flows in crystal growth systems, mass transfer in melt and solution growth, faceting phenomena, and morphological stability of crystal interfaces. Recent work has concentrated on the growth and properties of radiation detector crystals, such as cadmium zinc telluride, step dynamics during solution growth, and growth processes for crystalline silicon in photovoltaic devices.
研究兴趣
论文共 215 篇作者统计合作学者相似作者
按年份排序按引用量排序主题筛选期刊级别筛选合作者筛选合作机构筛选
时间
引用量
主题
期刊级别
合作者
合作机构
Journal of Crystal Growthpp.127599, (2024)
Journal of Crystal Growth (2023): 127150-127150
SSRN Electronic Journal (2022): 126723
加载更多
作者统计
合作学者
合作机构
D-Core
- 合作者
- 学生
- 导师
数据免责声明
页面数据均来自互联网公开来源、合作出版商和通过AI技术自动分析结果,我们不对页面数据的有效性、准确性、正确性、可靠性、完整性和及时性做出任何承诺和保证。若有疑问,可以通过电子邮件方式联系我们:report@aminer.cn