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Field
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theory is a theoretical framework that unifies all particles and forces in nature, including gravity, in a way consistent with the laws of quantum mechanics and relativity. String theory answers
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the second phase particles and recrystallization. The project aims to understand the complex interactions between alloy chemistry, processing, microstructure and performance. The alloy microstructure will be
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the National Institutes of Health (NIH). It will employ cutting-edge computational approaches using Australian and American supercomputers, alongside single-particle cryo-electron microscopy and functional
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techniques for security applications and the nuclear physics group at the University of Manchester have great experience working with neutrons and particle detectors. This PhD covers both fundamental research
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bilayers, this project is leveraging dynamic mass photometry (DMP)—a label-free, single-particle technique capable of measuring both mass (protein interactions) and diffusion (protein-membrane affinity
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fluid or as individual particles; moreover, complex chemical reactions can occur between species in the plasma. Modelling a plasma is accordingly a very complex and challenging task. The objective
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ambitious research team exploring quantum phenomena in large scale and complex systems, from high-temperature Bose-Einstein condensates to trapped solid-state particles in ultra-high vacuum. We combine
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will be on extracellular vesicles (EVs)—tiny particles released by cells that play an essential role in communication. Studying EVs will help us understand: How brain cells respond to genetic changes
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the next frontier of photonic quantum technologies. About the Project: Making Strongly Interacting Photons investigates a remarkable class of particles called polaritons — hybrids of light and matter
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such as lipid nanoparticles (LNPs), extracellular vesicles and cell membrane mimics. We use a variety of single particle techniques as well as small angle scattering experiments to identify lipid self