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stresses, leading to faster creep rates / shorter lives. Oxidation forms fastest on newly created fresh surfaces, for example as the specimen tapers and begins to neck. Several other surface / environment
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; Computational photonics simulations; Comparison with real physical systems (especially photonic systems using light). Facilities and research environment: High-performance computing facilities; Photonics and
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and adaptive potential. By treating organisms as active systems that regulate their own development and modify their environments, the work aims to improve predictions of population resilience and
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home learning, and inequalities in education and mental health outcomes Project details This project offers the opportunity to take a broad view of children’s home learning environments, to include how
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shelters and nurseries, and how animals interact with their subterranean environment. This exciting, multi-disciplinary, technology-driven PhD aims to clarify how the structure of breeding and sleeping
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English, as we operate in a global research environment. A high degree of intrinsic motivation, curiosity, and the ability to work both independently and collaboratively. Desirable skills Experience in
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About the project Rising ultraviolet (UV) radiation levels present a growing challenge for both human health and the environment. While sunscreens play a critical role in preventing skin cancer
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timeline constraints, applications are open to Home applicants only. The School of Computing Sciences provides a vibrant research environment for conducting Computing and allied research and training
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their environments, the work aims to improve predictions of population resilience and evolutionary responses to environmental change. The project builds on recent work developing a “development-centric” approach to
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derived biomaterials for cartilage tissue engineering and joint immunomodulation. The successful applicant will work in a multidisciplinary environment spanning biomaterials formulation, electroactive