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blade aerodynamics, gust interactions, and fluid-structure interactions. The research focuses on unfolding the origin and development of unsteady flow separation and vortex formation. The lab has built a
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collaboration to combine their expertise. By integrating these complementary approaches, we aim to provide the first comprehensive picture of Hsp90's structure–dynamics–function relationship, with broad
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, for advancing our fluorescence-based DyeCycling/FRET technology to study biomolecular dynamics. Biomolecular dynamics, such as conformational changes, are the understudied link between biomolecular structure and
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of nanoparticles for healthcare and industrial applications. As a PhD candidate, you will: Develop and refine SAXS and FCCS methods to quantify size, concentration, density and internal structure of diverse
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-duration energy storage. The approach is to use hierarchical structures, i.e. complex material layers that can be optimized to specific battery chemistries and flow phenomena from the microscale up
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-duration energy storage. The approach is to use hierarchical structures, i.e. complex material layers that can be optimized to specific battery chemistries and flow phenomena from the microscale up
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Your position Biomolecular dynamics, such as conformational changes, are the understudied link between biomolecular structure and function. Single-molecule FRET is an established technique, unique
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systems as most biomolecules are chiral and their interactions with other chiral objects are fundamental to many key biological processes. Chiral molecules exist in two forms, a left-handed one and a right
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in medical applications, this challenge is largely a materials challenge. Existing medical implants are dominated by rigid structures that often lack the adaptability and sophistication required
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enables label-free trapping and sensing of single proteins in solution for up to hours. Now, we leverage the unique abilities of nanopore trapping to detect proteins and their conformations, dynamics