Stanford University
Showing 821-840 of 1,354 Results
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Michael McFaul
Director, Freeman Spogli Institute for International Studies, Ken Olivier and Angela Nomellini Professor of International Studies and Senior Fellow at the Hoover Institution, at the Freeman Spogli Institute and at the Woods Institute
Current Research and Scholarly InterestsAmerican foreign policy, great power relations, comparative autocracies, and the relationship between democracy and development.
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Audrey McManemin
Masters Student in Energy Science and Engineering, admitted Autumn 2023
BioAudrey is pursuing a master's degree in Energy Science & Engineering and is expecting to graduate in Spring 2025. She holds a B.S.E in Mechanical Engineering from Duke University and has previously worked in data engineering. Her research at Stanford focuses on evaluating methane detection and quantification technologies currently used in both commercial and academic applications.
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Mark Patrick McVay
Staff, Stanford Doerr School of Sustainability - Dean's Office
Temp - Non-Exempt, Stanford Doerr School of Sustainability - Dean's OfficeBioMark joined Stanford Energy in January of 2020 to focus on business model innovation supporting energy transformation. He is working with students and faculty throughout Stanford on efforts to create solutions for Carbon Reduction and Sustainability goals in large organizations. He is now working with Doerr School of Sustainability on external relations. Mark has spent his career in energy starting as a nuclear power engineer aboard an aircraft carrier. He most recently helped build and sell the energy analytics firm PowerAdvocate and currently serves on the boards of several energy related small companies. Mark earned an MBA from the Stanford GSB and an MS from the School of Engineering. He has a BS from the US Naval Academy.
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Cheng Mei
Postdoctoral Scholar, Geophysics
BioMy research focuses on solid earth geophysics, particularly earthquakes, geomechanics, and rock/fluid mechanics. I employ a multidisciplinary approach, incorporating theoretical, numerical, and experimental models, to uncover the patterns, mechanisms, and impacts of natural earthquakes and induced seismicity in subsurface engineering systems. I am developing a macroscopic framework that incorporates multiple important controls, such as velocity, temperature, normal stress, fluid diffusion, and surface roughness. I believe this work would contribute significantly to understanding and mitigating seismic risks.
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Nicholas Melosh
Professor of Materials Science and Engineering
BioThe Melosh group explores how to apply new methods from the semiconductor and self-assembly fields to important problems in biology, materials, and energy. We think about how to rationally design engineered interfaces to enhance communication with biological cells and tissues, or to improve energy conversion and materials synthesis. In particular, we are interested in seamlessly integrating inorganic structures together with biology for improved cell transfection and therapies, and designing new materials, often using diamondoid molecules as building blocks.
My group is very interested in how to design new inorganic structures that will seamless integrate with biological systems to address problems that are not feasible by other means. This involves both fundamental work such as to deeply understand how lipid membranes interact with inorganic surfaces, electrokinetic phenomena in biologically relevant solutions, and applying this knowledge into new device designs. Examples of this include “nanostraw” drug delivery platforms for direct delivery or extraction of material through the cell wall using a biomimetic gap-junction made using nanoscale semiconductor processing techniques. We also engineer materials and structures for neural interfaces and electronics pertinent to highly parallel data acquisition and recording. For instance, we have created inorganic electrodes that mimic the hydrophobic banding of natural transmembrane proteins, allowing them to ‘fuse’ into the cell wall, providing a tight electrical junction for solid-state patch clamping. In addition to significant efforts at engineering surfaces at the molecular level, we also work on ‘bridge’ projects that span between engineering and biological/clinical needs. My long history with nano- and microfabrication techniques and their interactions with biological constructs provide the skills necessary to fabricate and analyze new bio-electronic systems.
Research Interests:
Bio-inorganic Interface
Molecular materials at interfaces
Self-Assembly and Nucleation and Growth
