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that electrodes strategically fouled with non-conductive plastics are better performers than perfectly clean electrodes. Electrolysis rates of organic molecules are augmented where electrode, hydrophobic insulator
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I supervise a wide range of PhD projects on experimental research into the electronic properties of novel quantum materials including topological insulators, graphene, and other atomically thin two
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-insulating perovskite oxides with high mechanical strength, favourable chemical stability, high hydroxide ion conductivity and long lifespan as inorganic electrolyte membrane; (4) To advance all-perovskite
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PhD student(s) will join a vibrant team of postdocs, academics, and up to four PhD students working collaboratively across modelling, qualitative fieldwork, and optimisation techniques. PhD Research
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insulators and Weyl semimetals. The former favours quantum states of matter (e.g. excitonic superfluidity, quantum magnetism, superconductivity), while the latter makes their optical and transport properties
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the structure present in food systems dictates functional aspects such as digestion and release of nutrients. Working alongside other postdocs and students focused more on biological aspects of these processes
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I supervise a wide range of projects in surface and materials physics, with a particular focus on novel electronic materials such as topological insulators where electrons can be transported without
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for examining and imaging the magnetic fields from exotic conducting materials (e.g. superconductors, topological insulators), performing high bandwidth and high sensitivity vector magnetic sensing and developing
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known as Team COMPAS -- includes a number of amazing undergraduate and graduate students, postdocs, alumni, and other fantastic collaborators. Please contact me if you are interested in joining our group
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Fellowship at LMU Munich, and a postdoc position at RMIT University. My nanophotonics research seeks to uncover the underlying physics in structured light-matter interactions at nanoscale. We aim to develop