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emissions target will require significant innovation in advanced materials, graphene and related 2D materials offer a route to achieving these goals, with applications already demonstrated in reinforcing
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environmental applications (advancednanomaterials.weebly.com [advancednanomaterials.weebly.com] ). We are based at the National Graphene Institute and the Henry Royce Institute for Advanced Materials (University
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of multi-scale composites using graphene/nanoparticles reinforcement in glass/carbon epoxy composites to increase the delamination resistance. Graphene/nanoparticles, due to its nano dimension, can reinforce
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is classically possible [7]. This requires nanoscale resonators made from graphene or carbon nanotubes, which due to their extremely low mass are sensitive to the minuscule momentum transferred by
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, assemble them into functional macroscale structures, and use them for sustainable energy and environmental applications (https://advancednanomaterials.weebly.com/ ). We are based at the National Graphene
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exciton-polaritons being coupled to magnons [1-3]. Recent theoretical calculations suggest that, in combination with other 2D layers such as graphene and transition metal dichalcogenides (TMDCs), CrSBr
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synthesis & characterisation followed by neutron scattering experiments to study the details of magnetic structures in exotic new 2D materials. 2D materials are the future. Graphene was just the beginning
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high value manufacturing. Enhance our commitment to manufacturing and materials’ technologies (composites, graphene, thermal barrier coatings, welding and laser technology and other advanced materials
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-layer and pathogenicity in C. difficile, paving the way for new therapeutic avenues. You work alongside fellow PhD students and postdocs at Newcastle University, and access Diamond Light Source's cutting
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in the fields of energy engineering, computational fluid dynamics, and multiphase fluid mechanics. You will join an enthusiastic, friendly, and supportive group of PhD students and postdocs who are all