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the dynamics of ultracold collisions and the properties of ultracold molecules. They will develop quantum-mechanical scattering and bound-state methods and apply them to a variety of ultracold atomic and
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radar interferometry (InSAR) integrated with GNSS and airborne laser scanning. The PhD candidate will: Develop a recursive, dynamic monitoring strategy for near-continuous 3D surface displacement
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on this project, you will: Design and Model : Develop novel concepts for integrating photonic systems (e.g., laser-based, integrated optic components) with advanced microwave scattering/diagnostic
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many-body physics with ultracold polar molecules Controlling collisions between laser-cooled molecules and atoms The grants are in collaboration with the experimental groups of Prof Simon Cornish (Durham
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various areas of theoretical and computational chemistry such as quantum and semi-classical theory of molecules, electronic excited-state dynamics and relaxation, materials and light, statistical mechanics
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, statistical mechanics, reaction kinetics and dynamics, and theory/simulation of ultrafast time-resolved experiments. You will be a part of the Physical Chemistry section at DTU Chemistry (https
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separation techniques (AF4, SEC) and light-scattering analysis (MALS, DLS); Demonstrated experience in peptide/protein characterization using AF4-MALS, SEC-MALS, and high-resolution mass spectrometry; Strong
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micrometres. Furthermore, this nonlinearity gives rise to rich fundamental phenomena ranging from the superfluidity of light (i.e., propagation without scattering from imperfections) and ultra-low-power self
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primarily focus on the theme of Scattering for Catalysis, carrying out experiments on the creation of Al projectiles by laser ablation and their reactions with fluorinated liquid surfaces. The aim is to
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the dynamics of ultracold collisions and the properties of ultracold molecules. They will develop quantum-mechanical scattering and bound-state methods and apply them to a variety of ultracold atomic and