Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.Read moreRead less
Atomistic anatomy of a nano transistor. The high-speed and low-power requirements of state-of-the-art transistors are met by material control that has reached an unprecedented level. The material in a nano-device has drastically different characteristics than in the bulk. To achieve this, the industry needs to implement strain, ultra sharp junctions, and well controlled potential profiles all on the nanometre scale. This project aims to develop a technique to directly measure these properties in ....Atomistic anatomy of a nano transistor. The high-speed and low-power requirements of state-of-the-art transistors are met by material control that has reached an unprecedented level. The material in a nano-device has drastically different characteristics than in the bulk. To achieve this, the industry needs to implement strain, ultra sharp junctions, and well controlled potential profiles all on the nanometre scale. This project aims to develop a technique to directly measure these properties in an actual device. Electrical and optical atom tomography will make it possible to map device parameters on the atomic scale. This atomistic anatomy has the potential to revolutionise the development of nanoscale devices and grow into a tool for a multi-billion dollar industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100151
Funder
Australian Research Council
Funding Amount
$760,000.00
Summary
Probe and engineer interactions in atomic-scale devices with a LT STM. A low-temperature scanning tunnelling microscope: The project aims to establish a facility to exploit the spectroscopic and spatial resolution of an ultra-low temperature scanning tunnelling microscope in conjunction with atomically controlled dopant engineering. In a variety of experiments the research team will explore ultra-scaled transistors, quantum information science devices, and engineered quantum matter. Improving ou ....Probe and engineer interactions in atomic-scale devices with a LT STM. A low-temperature scanning tunnelling microscope: The project aims to establish a facility to exploit the spectroscopic and spatial resolution of an ultra-low temperature scanning tunnelling microscope in conjunction with atomically controlled dopant engineering. In a variety of experiments the research team will explore ultra-scaled transistors, quantum information science devices, and engineered quantum matter. Improving our ability to investigate semiconductor materials at the atomic scale impacts fields ranging from electronics, telecommunication, quantum information to renewable energy research and puts Australia at the forefront of the field of controlled atomic systems in semiconductors.Read moreRead less