Discovery Early Career Researcher Award - Grant ID: DE210100453
Funder
Australian Research Council
Funding Amount
$442,408.00
Summary
Nervous tissue stimulation using Multi-Junction Silicon Photodiodes. Currently, in order to stimulate different areas in nervous tissue, brain-machine-interfaces (BMIs) usually rely on multi electrode arrays where each electrode is connected to a wire, that connects to other electronics, all of which has to be safely encapsulated, thus increasing the size of the devices and complicating the surgical procedure for implanted devices. This project aims to develop a silicon multi-junction photodiode ....Nervous tissue stimulation using Multi-Junction Silicon Photodiodes. Currently, in order to stimulate different areas in nervous tissue, brain-machine-interfaces (BMIs) usually rely on multi electrode arrays where each electrode is connected to a wire, that connects to other electronics, all of which has to be safely encapsulated, thus increasing the size of the devices and complicating the surgical procedure for implanted devices. This project aims to develop a silicon multi-junction photodiode that can provide a photovoltage high enough to efficiently excite nervous tissue. A BMI based on this approach could be much smaller and could be powered optically via thin fibres, thus in the long run enabling smaller and safer implants for restoring function in disabled people.Read moreRead less
Liquids to semiconductors: the formation of solution-processed electronics. This project aims to understand and control the formation of solution-processed organic semiconductors. This project will create unique experimental methodologies to study, in situ, the evolution of the structure and the emergence of electrical transport all the way from the initial solution to the final film. These findings will be used to formulate design rules and principles that will accelerate the development of sol ....Liquids to semiconductors: the formation of solution-processed electronics. This project aims to understand and control the formation of solution-processed organic semiconductors. This project will create unique experimental methodologies to study, in situ, the evolution of the structure and the emergence of electrical transport all the way from the initial solution to the final film. These findings will be used to formulate design rules and principles that will accelerate the development of solution-processed semiconductors beyond current trial-and-error approaches. This will provide significant benefits, such as unlocking the potential of soft and flexible semiconductors for new technologies based on sustainable manufacturing.Read moreRead less