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Accelerated Discovery of Next Generation Polymers Using Artificially Intelligent Reactor Platforms School of Chemical, Materials and Biological Engineering PhD Research Project Directly Funded UK
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Improving the mechanical properties of carbon fibre composites via inkjet printed polymer inclusions
Improving the mechanical properties of carbon fibre composites via inkjet printed polymer inclusions Department of Mechanical Engineering PhD Research Project Self Funded Dr Patrick Smith
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Next-Generation Hydrogen Production Using Polymer Nanotemplates Department of Chemical & Biological Engineering PhD Research Project Self Funded Dr Alisyn Nedoma Application Deadline: Applications
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Modelling and characterisation of chip formation and machining induced defects of nano-particle toughened Carbon Fibre Polymer Composites Department of Mechanical Engineering PhD Research Project
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Next-Generation Hydrogen Production Using Polymer Nanotemplates
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Accelerated Discovery of Next Generation Polymers Using Artificially Intelligent Reactor Platforms
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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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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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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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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