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Continuum mechanics approaches have been used to model the mechanical behaviour of biological (and active) systems at length scales that are large enough. For example, when analysed at the micron-scale, biological membranes can be treated as continuum objects that deform regulated by effective...
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School of Chemistry and Optoelectronics Research Centre (ORC), the Rosalind Franklin Institute (RFI), and the Central Laser Facility (CLF) at the Rutherford Appleton Laboratories. The project will design
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to deliver practical teaching sessions to any and all University of Edinburgh Undergraduate students required to study aspects of Chemistry. Practical sessions run Monday to Friday and form the core of hands
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Engineering/Materials Engineering. Please note that this advert will close as soon as a suitable candidate is found. Further Information: The University of Edinburgh is committed to equality of opportunity
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years. The PDRA will be supervised by Prof. Stephen Thomas (ST) and is based in the School of Chemistry at the University of Edinburgh. This position is funded by the EPSRC through a programme grant
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. Callanan - Edinburgh University Profile The University of Edinburgh is committed to equality of opportunity for all its staff and students, and promotes a culture of inclusivity. Please see details here
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. These skills will be essential for a student perusing industrial careers in the biomechanical and modeling sector. Further Information: Dr. Callanan - Google Scholar Profile Dr. Callanan - Edinburgh University
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Engineering/Biomedical Engineering. Further Information: Dr. Callanan - Google Scholar Profile Dr. Callanan - Edinburgh University Profile The University of Edinburgh is committed to equality of opportunity
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Engineering/Biomedical Engineering. Further Information: Dr. Callanan - Edinburgh University Profile Dr. Callanan - Google Scholar Profile The University of Edinburgh is committed to equality of opportunity
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PhD Studentship: Molecular Simulations and Data-driven Modelling for Polymer Nanocomposite Membranes
applications. However, optimizing MMMs for efficient gas separation remains a challenge, due to the many factors that influence the membrane performance, such as size, shape, surface chemistry, and loading