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biocompatibility testing methods often overlook the biological complexity of aged soft tissue. Changes in extracellular matrix composition, immune responsiveness, and cellular senescence can significantly alter how
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this fundamental challenge, the PhD candidate will be part of a wider team to establish methodological framework, combing utilisation of controlled tree growth test, thermodynamic modelling and advanced optical
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mechanical fatigue—individually and sequentially, followed by electrical breakdown testing to assess their impact on the dielectric performance of the material subsystems. The target is to develop a
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. Training and Facilities The successful candidate will benefit from access to world-class facilities at the National Graphene Institute (NGI) and the Henry Royce Institute (HRI), including advanced microscopy
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farms at relatively close proximity can be relevant when considering their annual energy production. This project will examine the uncertainty of various types of numerical models, from fast-computing
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class is a collection of models that includes the random growth of a surface over time or the behaviour of a large number of particles that move around in space and interact with each other according
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will be removed once the position has been filled. Project Description Are you excited by the idea of using world-class microscopy to unlock the secrets of materials and shape the future of sustainable
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the online application form. The post will remain open until filled.
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transition to a circular economy. A minimum of an upper second-class Honours degree (or equivalent) in Chemical Engineering, Mechanical Engineering, Industrial Engineering, Operations Research, or a related
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transfer and laser-matter interactions. The “design-manufacture-inspect-model-test” approach of this project will equip the successful PhD candidate with a wide range of valuable and transferable skills