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synergistically combine world-leading expertise in membrane biology and novel polymer chemistries to establish a first-of-its-kind institute, expanding our distinctive excellence in computational membrane science
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synergistically combine world-leading expertise in membrane biology and novel polymer chemistries to establish a first-of-its-kind institute, expanding our distinctive excellence in computational membrane science
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Next-Generation Hydrogen Production Using Polymer Nanotemplates
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of both advanced composites and polymers manufacturing at UU and the industrial partner (Purapipe UK Ltd). The student will join the AFM2 group in the School of Engineering and participate in
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such as cancer and inflammatory diseases. To create these nanoparticles, we will use a biomimetic technique called molecular imprinting. This allows us to construct bio-recognition sites into polymeric
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developed a number of porphyrin containing biomimetic macromolecules. These have included a porphyrin cored polymer capable of reversibly binding oxygen. As such, these molecules have the potential to be
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water soluble polymer systems capable of encapsulating and solubilising various hydrophobic drug moieties. Despite the formation of stable complexes, we have demonstrated that encapsulated drug can also
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to develop new manufacturing processes that will enable the high throughput production of nanoscale polymer micelles loaded with anticancer drugs. Obtaining stable, loaded micelles is a challenge that has
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fibre reinforcements in a thermosetting polymeric matrix) to meet this need is now commonplace for several reasons. These include significant weight savings over traditional materials and design
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commercially viable. In this project, an experimental investigation into the performance of different designs of Polymer Electrolyte Membrane fuel cells (PEMFCs) will be undertaken; this will involve