Low-temperature plasma processes for high-quality graphene films. The project aims to develop novel plasma-enabled processes for low-cost, energy-efficient, and scalable growth of high-quality graphene films for applications in touch screen, solar cell and other devices. It aims to discover non-equilibrium plasma-surface interactions enabling nucleation and growth of graphene films with large and low-defect domains on metal catalysts at low temperatures, and then develop energy-efficient, enviro ....Low-temperature plasma processes for high-quality graphene films. The project aims to develop novel plasma-enabled processes for low-cost, energy-efficient, and scalable growth of high-quality graphene films for applications in touch screen, solar cell and other devices. It aims to discover non-equilibrium plasma-surface interactions enabling nucleation and growth of graphene films with large and low-defect domains on metal catalysts at low temperatures, and then develop energy-efficient, environment-friendly, and scalable fabrication and device transfer processes. These processes are designed to retain high quality of graphene films upon scale-up and will be compatible with the existing and emerging applications in touch screens and other devices. The expected outcomes include fundamental understanding and novel practical approaches to control synthesis and device integration of two-dimensional atomically-thin materials.Read moreRead less
The converging shock driven Richtmyer-Meshkov instability in magnetohydrodynamics. Fluid dynamic instabilities limit the chance of inertial confinement fusion, a carbon-free process, achieving net energy production. The project will investigate the effectiveness and consequences of suppressing one of these instabilities with a magnetic field.
Electron scattering and transport for plasma-liquid interactions. The project aims to address the emerging technologies associated with the interaction of plasmas with liquids and biological matter, including plasma medicine. The project expects to generate new knowledge on the role of electron-induced processes through the development of complete and accurate sets of microscopic cross-sections for electrons with biomolecules within tissue. This microscopic data will inform new microscopic model ....Electron scattering and transport for plasma-liquid interactions. The project aims to address the emerging technologies associated with the interaction of plasmas with liquids and biological matter, including plasma medicine. The project expects to generate new knowledge on the role of electron-induced processes through the development of complete and accurate sets of microscopic cross-sections for electrons with biomolecules within tissue. This microscopic data will inform new microscopic models for non-equilibrium electron transport in liquids and biological matter, and its coupling to plasmas. The expected outcomes of this project include progress towards the optimisation of safety/efficacy of future generation plasma medicine devices through detailed understanding of plasma-biological tissue interactions.Read moreRead less