Shear stimulated Brillouin microscopy for cell mechanobiology. This project aims to develop novel technology for non-contact imaging of micro-mechanical properties in cells and tissues to answer fundamental questions of cell mechnanobiology. Based on principles of Brillouin light scattering, the project takes advantage of a radio-frequency lock-in detection scheme. The project will result in a real-time, high-sensitivity, non-contact 3D imaging solution for spatial characterisation of cell's loc ....Shear stimulated Brillouin microscopy for cell mechanobiology. This project aims to develop novel technology for non-contact imaging of micro-mechanical properties in cells and tissues to answer fundamental questions of cell mechnanobiology. Based on principles of Brillouin light scattering, the project takes advantage of a radio-frequency lock-in detection scheme. The project will result in a real-time, high-sensitivity, non-contact 3D imaging solution for spatial characterisation of cell's local stiffness and compressibility. This will underpin the advancement of knowledge in the area of cell mechanobiology and the investigation of diseases, where microscale changes in cell mechanical properties lead to cell dysfunction and apoptosis.Read moreRead less
Quantum effects in photosynthesis: responsible for highly efficient energy transfer or trivial coincidence? Understanding the precise details of the highly efficient energy transfer processes in photosynthesis has the potential to impact the design of efficient solar energy solutions. This project will gain this understanding by exploring the nature of interactions between different components and the significance of quantum mechanics.