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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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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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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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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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and opportunities for travel to international facilities. 2D materials are the future. Graphene was just the beginning, and the possibilities before us now are endless. Our group aims to identify new
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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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innovation areas. Graphene Applications Lab (at CFPR) already has facilities for material synthesis, ink formulations, surface engineering and necessary characterisation tools for this project. Interest in
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printing to create novel multimaterial functional structures capable of new ways of sensing underlying material properties. We will use low dimensional materials, including graphene, perovskites and