School of Engineering
Showing 1,041-1,060 of 6,554 Results
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Jen-Fei Chu
Graduate, Stanford Center for Professional Development
BioDr. Chu is an experienced postdoctoral researcher who has built a strong track record at Academia Sinica, Taiwan. He completed his Ph.D. in Biophysics and Physical Chemistry at the Institute of Atomic and Molecular Sciences (IAMS), gaining expertise in single-molecule imaging, molecular mechanisms, and data analysis. He then applied these imaging skills to neuroscience research at the Institute of Molecular Biology (IMB), with a focus on autism spectrum disorder (ASD) and amyotrophic lateral sclerosis (ALS).
Beyond his rigorous research, Dr. Chu studied law at National Taiwan University (NTU) in preparation for the bar examination. He is now taking credit-bearing graduate courses in electrical engineering and AI at Stanford University through the Center for Global and Online Education (CGOE), working toward the advanced degrees. -
William Chueh
Director, Precourt Institute for Energy, Kimmelman Professor, Professor of Materials Science and Engineering, of Energy Science and Engineering, and Senior Fellow at the Precourt Institute for Energy
BioThe availability of low-cost but intermittent renewable electricity (e.g., derived from solar and wind) underscores the grand challenge to store and dispatch energy so that it is available when and where it is needed. Redox-active materials promise the efficient transformation between electrical, chemical, and thermal energy, and are at the heart of carbon-neutral energy cycles. Understanding design rules that govern materials chemistry and architecture holds the key towards rationally optimizing technologies such as batteries, fuel cells, electrolyzers, and novel thermodynamic cycles. Electrochemical and chemical reactions involved in these technologies span diverse length and time scales, ranging from Ångströms to meters and from picoseconds to years. As such, establishing a unified, predictive framework has been a major challenge. The central question unifying our research is: “can we understand and engineer redox reactions at the levels of electrons, ions, molecules, particles and devices using a bottom-up approach?” Our approach integrates novel synthesis, fabrication, characterization, modeling and analytics to understand molecular pathways and interfacial structure, and to bridge fundamentals to energy storage and conversion technologies by establishing new design rules.
