Discovery Early Career Researcher Award - Grant ID: DE160100167
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Electro-optical quantum transport in semiconductor microcavities. The project seeks to expand fundamental knowledge in the new area of exciton-polariton physics which has a range of practical applications. This project plans to connect fundamental study in quantum physics with application-oriented research involving elements of quantum engineering. The project plans to investigate the transport of exciton polaritons – hybrid light–matter particles that can propagate nearly as fast as light and a ....Electro-optical quantum transport in semiconductor microcavities. The project seeks to expand fundamental knowledge in the new area of exciton-polariton physics which has a range of practical applications. This project plans to connect fundamental study in quantum physics with application-oriented research involving elements of quantum engineering. The project plans to investigate the transport of exciton polaritons – hybrid light–matter particles that can propagate nearly as fast as light and are very robust. It may allow us to better understand fundamental features in physics and optics, and to model and construct optoelectronic devices such as quantum switchers, filters, transistors and detectors. The theory that the project aims to develop could be employed in different spheres of modern physics, chemistry, and medicine and biology.Read moreRead less
Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outc ....Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outcomes include highly developed theoretical insights into solid-state emitters and how to control their interactions with light and other fields. The expected benefit based on the ability to engineer optimised emitters for optical sensors and quantum technologies will transform material science from exploration to design.Read moreRead less
ARC Centre of Excellence for Engineered Quantum Systems. The future of technology lies in controlling the quantum world. The ARC Centre of Excellence for Engineered Quantum Systems (EQuS) will deliver the building blocks of future quantum technologies and, critically, ensure Australian primacy in this endeavour. Three strategic research programs will target Quantum Measurement and Control; Synthetic Quantum Systems and Simulation; and Quantum-Enabled Sensors and Metrology. Within these programs, ....ARC Centre of Excellence for Engineered Quantum Systems. The future of technology lies in controlling the quantum world. The ARC Centre of Excellence for Engineered Quantum Systems (EQuS) will deliver the building blocks of future quantum technologies and, critically, ensure Australian primacy in this endeavour. Three strategic research programs will target Quantum Measurement and Control; Synthetic Quantum Systems and Simulation; and Quantum-Enabled Sensors and Metrology. Within these programs, our Centre will exploit the deepest principles and resources of quantum physics to solve specific problems in engineering, chemistry biology and medicine, stimulating the Australian scientific and engineering communities to exploit (and benefit from) transformative quantum devices.Read moreRead less