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of the field, there remains a substantial knowledge gap in how structure, substituent effects, and molecular environment influence the strength, selectivity, and mechanistic role of chalcogen bonding in real
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not reflect the systems commonly used in catalysis. Advancing truly orthogonal and complementary chalcogen bonding catalysts therefore requires a deeper understanding of how catalyst structure
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the THz labs at Warwick and by our collaborators at the Institute of Saint-Louis (ISL). By suggesting design modifications to the molecular structures, your work will improve the next generation of
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behaviour with amorphous liquid-like structure. These mysterious signature properties are ubiquitous across science and engineering, with examples ranging from optical fibres to novel formulations
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, machine learning, molecular dynamics, and fluid mechanics. We aim to understand how chemical structure of precursors and process conditions affect film quality, helping design better materials and
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potentials and automated reaction discovery, we will reveal how nanoparticle composition, geometry and electronic structure govern electrochemical reaction rates, helping design efficient, low-cost materials
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an adhesive heavy application, and to find methods for End-of-Life disassembly. Battery pack construction uses adhesives to fix multiple cells in place, creating a block of battery modules. The adhesive has