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sources. However, plasma catalysis still faces key challenges: low energy efficiency and a limited understanding of reaction mechanism, imposing a significant barrier to their wider adoption. The Project
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could provide clean alternative routes to other platform chemicals and intermediates. In addition to synthesis and catalysis studies, the project will involve DFT modelling of reaction mechanisms. Number
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Solid-Supported Chalcogen Bonding Catalysis A 3.5 year fully-funded PhD position is available in the group of Dr Mark Greenhalgh at the University of Warwick, in collaboration with GoldenKeys High
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Application deadline: All year round Research theme: Catalysis and porous materials; Hydrogen storage The 3.5 year project is co-funded by ISIS Neutron and Muon Source. Home students can apply for
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class UK honours degree or equivalent in a related discipline. This project would suit students with knowledge and experience of chemical and reaction engineering, catalysis and materials. Funding To be
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2024. The projects will be based around the development of advanced magnetic resonance techniques to optimise heterogenous catalysts and the operation of the reactor in which the catalysis occurs. Two
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Research theme: Catalysis and Porous Materials This 3.5 year long PhD project is for UK students and EU students with settled status. The funding will cover home tuition fees and provide a tax free
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methods Switchable catalysis for pharma Sustainable additives for construction Smarter Synthesis via process intensification All Projects will all be informed by Life Cycle Assessments (LCA) and will
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provided us with a more efficient, in silico approach to develop new ligands for functional materials and catalysis. We aim to extend the Big Data/high throughput DFT methodology in Nguyen group to carry out
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prove extremely beneficial for applications in various areas, including electrochemical energy storage, catalysis and gas adsorption. MXenes have already shown promise for gas separations, as they showed