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About Us The Department of Infectious Diseases brings together researchers and students to understand the pathogenic mechanisms, diagnosis and treatment of human infections. Our research bridges our
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-temporally cooperate to result in an emergent macroscopic flow. Besides the immediate applications of the work to soft matter physics, and potentially also to the fracture mechanics of hard materials, yielding
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Applications are invited for an exceptional Postdoctoral Scientist to the join the group of Prof. Claus Nerlov to study blood cell development, with particular emphasis on mechanisms of HSC ageing
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campus. The research focuses on elucidating mechanisms underlying human trophectoderm development. The aim of this project is to test the functional requirement for signalling pathways in trophectoderm
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interdisciplinary environment, first-class mechanical and electronics workshops, and access to the King’s core facilities network. King’s is committed to an inclusive, supportive research culture. Researchers benefit
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of 24 months. The project aim’s to develop new constitutive models to describe the mechanical behaviour of Thermoplastic Elastomers (TPEs). These polymers are increasingly being developed as a
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the long-standing and counterintuitive observation of attraction between similarly charged particles in solution. In a series of papers we described the mechanism behind an “electrosolvation force” that can
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of attraction between similarly charged particles in solution. In a series of papers we described the mechanism behind an “electrosolvation force” that can drive such an attraction (J Chem Phys 2020, Langmuir
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Goldstein FRS to work on experimental aspects of (a) the biomechanics of multicellular choanoflagellates and (b) the growth and mechanics of the extracellular matrix in green algae, supported by
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in neurodevelopment. This role will focus on data analysis and methods development to develop a better understanding of the mechanisms underpinning typical and altered neurodevelopment, brain structure