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with fully ab initio theoretical approaches. Due to the project nature, a base requirement for applicants is an interest in simulations of nanosystems using quantum-mechanical methods. Ideally
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the an interdisciplinary environment of the Metamaterials and Nanophotonics group (https://www.birmingham.ac.uk/research/activity/physics/quantum/metamaterials/index.aspx ), which will substantially favour collaboration
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as ligands. The fundamental science behind the selective enrichment of lithium-6 by solvent extraction is poorly understood. This project will combine molecular quantum mechanics and molecular dynamics
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accurate reaction enthalpies and activation free energies for relevant intermediates. While quantum chemical predictions typically can provide sufficient accuracy of prediction (~1kcal/mol error
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potential. Our research focuses on Materials physics; Quantum technology; Soft & living matter; and Advanced energy solutions. Topics extend from fundamental research to important applications. We educate
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goes beyond understanding the Higgs boson. The interplay between the strength of the top-Higgs interaction and the Higgs self-interaction is directly related to the stability of the Universe at a quantum
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nature, a base requirement for applicants is an interest in simulations of nanosystems using quantum-mechanical methods. Ideally, applicants should have: prior experience with density functional theory
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mathematical modelling skills Strong skills in solid state physics and quantum mechanics Experience in theoretical modelling and experimental investigation of optical devices including optical microresonators We
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learning potentials) and analytical calculation methods (quantum dynamics) to develop robust methods for predicting and interpreting observables from XFEL experiments. Methodologies developed be applicable
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, high vacuum apparatus and instrumentation, charged particle manipulation and detection systems, signal processing and scientific programming, quantum chemical calculations and molecular dynamics