Enhancing gravitational wave detector sensitivity and bandwidth for astronomy. This project aims to create small optomechanical devices that amplify the signals in gravitational wave detectors, increasing their sensitivity, especially for higher frequency signals. Calibrated against the 2015 first detection of gravitational waves from black hole mergers, this technology could allow humanity to listen to black holes merging up to 30 times every day, while giving much greater sensitivity to signal ....Enhancing gravitational wave detector sensitivity and bandwidth for astronomy. This project aims to create small optomechanical devices that amplify the signals in gravitational wave detectors, increasing their sensitivity, especially for higher frequency signals. Calibrated against the 2015 first detection of gravitational waves from black hole mergers, this technology could allow humanity to listen to black holes merging up to 30 times every day, while giving much greater sensitivity to signals from smaller black holes and neutron stars. The new technology, which uses nano-scale suspended tiny mirrors controlled by laser light, is likely to have applications in making sensors and quantum devices for advanced instrumentation, improve mineral exploration and measure tiny electromagnetic signals.Read moreRead less
Engineering and testing of three mode opto-acoustic parametric amplifiers. This project will engineer a new type of sensor called an opto-acoustic parametric amplifier. It is so sensitive to measure individual quantum units of vibration. The devices use laser light to measure the motion of tiny mirrors. Practical devices could be used to create quantum memory for quantum computers and sensors of exquisite sensitivity.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100144
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Equipment for International Collaboration in Next Generation GW Detectors. Equipment for international collaboration in next-generation gravitational wave detectors:
This project aims to create a silicon optics research facility which combines Australian capabilities in silicon manufacturing at nanometre precision, with revolutionary crystalline mirror technology. The equipment is designed to enable international teams of physicists to research the optical and acoustic properties of silicon in ....Equipment for International Collaboration in Next Generation GW Detectors. Equipment for international collaboration in next-generation gravitational wave detectors:
This project aims to create a silicon optics research facility which combines Australian capabilities in silicon manufacturing at nanometre precision, with revolutionary crystalline mirror technology. The equipment is designed to enable international teams of physicists to research the optical and acoustic properties of silicon in high optical power and high precision silicon measurement systems. Research facilitated by this equipment may pave the way for the next generation of ultra-low-noise systems required for gravitational wave detection, while opening the possibility of multiple new applications in precision measurement devices. Read moreRead less
Nanoscale quantum metrology using circuit quantum electrodynamics. Using superconducting microcircuits, we aim to control microwave photons in order to achieve detection of nanoscale electrical and mechanical systems that is limited only by the constraints imposed by quantum mechanics. Such quantum-limited measurements will enable the use of quantum feedback for enhanced control of these nanoscale devices.
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