Diamond Voltage Microscopy: A new tool for neuroscience. This project aims to develop an optoelectronic voltage imaging microscope that can capture the sub-cellular electrical dynamics of neuronal networks. This will be achieved by leveraging the team’s technological breakthrough in the production of near-surface fluorescent defects in semiconducting diamond, which can optically detect local changes in electric potential. The expected outcomes of the project are a new microscopy modality and exp ....Diamond Voltage Microscopy: A new tool for neuroscience. This project aims to develop an optoelectronic voltage imaging microscope that can capture the sub-cellular electrical dynamics of neuronal networks. This will be achieved by leveraging the team’s technological breakthrough in the production of near-surface fluorescent defects in semiconducting diamond, which can optically detect local changes in electric potential. The expected outcomes of the project are a new microscopy modality and experimental framework which enables in vitro electrophysiological stimulation and recording at network scale and with single-synapse resolution. This will provide a much-needed tool to understand mechanisms underlying learning, memory formation and recall, and cognitive decline.Read moreRead less
Nature’s advanced optical materials and their role in thermal management. This project aims to discover the nano-structural properties of beetles than enable effective management of solar and thermal radiation in different environments. A further aim is to reveal how these composite biological materials combine thermal control with desirable mechanical properties, such as strength and flexibility. Passive control of radiative energy is critical for both animal survival and for the design of many ....Nature’s advanced optical materials and their role in thermal management. This project aims to discover the nano-structural properties of beetles than enable effective management of solar and thermal radiation in different environments. A further aim is to reveal how these composite biological materials combine thermal control with desirable mechanical properties, such as strength and flexibility. Passive control of radiative energy is critical for both animal survival and for the design of many manufactured materials, particularly in a warming world. This interdisciplinary project will provide new knowledge of the different ways that biological materials mediate radiative energy exchange with the environment. This knowledge is essential for the design of bioinspired, energy-efficient, multi-functional materials.Read moreRead less