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About the Role You will join an interdisciplinary research team working at the interface of nanotechnology, biophysics, and single-molecule sensing. In this role, you will design, develop, and apply
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integrates structural biology, biochemistry, single molecule biophysics, and microbiology to understand how membrane proteins enable microbes to withstand antimicrobial drugs and other sources of cellular
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atmosphere manipulation of air- and moisture-sensitive chemicals as well as analytical techniques for characterizing the newly synthesized molecules and polymers (NMR, IR, Mass spec, single crystal XRD, GPC
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for mechanistic analysis of meiotic crossover interference and high resolution imaging of single molecule dynamics of chromosomes Basic Qualifications expertise in high resolution imaging, knowledge of mitotic
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organic methods for functional small molecules and polymers. The goal of projects in the Huang lab is to tackle critical societal challenges through precise structural control, efficient manufacturing, and
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organic methods for functional small molecules and polymers. The goal of projects in the Huang lab is to tackle critical societal challenges through precise structural control, efficient manufacturing, and
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following areas: -Biophysical instrumentation development: optical and mechanical design, simulation, development and control -Optical imaging; Single-molecule fluorescence and FRET; Lasers; Pump-probe
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integrating statistical-mechanical theory, quantitative modeling, and experimental single-molecule methods. We aim to develop mechanistic models of receptor activation that combine physical theory with data
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(MATHEMATIC MODELING OF MACROMOLECULAR ASSEMBLY) Key Responsibilities: Utilizing advanced techniques such as single-molecule imaging and super-resolution imaging Conducting quantitative protein biochemistry
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light-matter interactions, developing nanophotonic and plasmonic devices that enable strong coupling between light and quantum materials, including single emitters, molecules, and two-dimensional