Stanford University
Showing 28,941-28,960 of 36,196 Results
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Dawn H. Siegel, MD
Clinical Professor, Dermatology
Clinical Professor (By courtesy), PediatricsCurrent Research and Scholarly InterestsI'm dedicated to connecting patients with clinical research trials and contributing to research on specific skin conditions particularly hemangiomas, birthmarks, and PHACE syndrome. My research also aims to develop solutions to health disparities through improved access to pediatric dermatologists and treatments.
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Robert Siegel
Professor (Teaching) of Microbiology and Immunology
Current Research and Scholarly InterestsMy work is primarily involved in medical education and curricular development, especially in the areas of infectious disease, virology, HIV, and molecular biology. Projects included electronic applications to science education, three dimensional model building, service learning, and the development of undergraduate research projects.
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Robert E. Siegel
Lecturer
Current Research and Scholarly InterestsRobert Siegel researches strategy and innovation in both large and small companies, as well as the opportunities and challenges that technological change brings to these firms. Additionally, Robert teaches product management and product development best practices and methods, as well as entrepreneurial finance over the life-cycle of growing companies.
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Nicholas Siemons
Research Engineer, Precourt Institute for Energy
Postdoctoral Scholar, Materials Science and EngineeringBioNicholas began his academic career by studying integrated Masters at University College, London. During this time he published his first article, "Multiple exciton generation in nanostructures for advanced photovoltaic cells" - a review of how to produce photovoltaics with greater than 100% internal efficiencies. Following this Nicholas began research into solar voltaics and organic batteries in the group of Prof. Jenny Nelson at Imperial College, London. During this time Nicholas developed his keen interest in how to relate the chemical design of polymers to their ability to function as battery electrode materials. To achieve this goal, Nicholas applies atomistic simulation methods to such polymer systems, and relates the simulated findings to experimental results, bridging the gap between chemistry and device properties. As well as linking molecular chemical design to device performance, Nicholas applies novel simulation and analysis methodologies to study these systems, including Molecular Dynamics, Density Functional Theory, Molecular Metadynamics and Network Analysis.
