Precision inertial sensing with cold atoms. Many advances in our technology-driven society rely on precision measurement. The project will provide the Australian industrial and government sectors with new and better inertial sensors to measure acceleration, rotation and gravity. The technology will find application in navigation, defence, mineral exploration, earth science and fundamental physics.
A Quantum Matterwave Vortex Gyroscope for Ultrastable Rotation Sensing. This project aims to investigate the basic science underpinning a new rotation sensing technology based on matterwave vortices. Current gyroscopes are susceptible to long-term calibration drifts, which limit their applicability on long timescales where re-calibration is not practical or possible. This project expects to build a matterwave vortex gyroscope and demonstrate that it offers unparalleled long-term stability over ` ....A Quantum Matterwave Vortex Gyroscope for Ultrastable Rotation Sensing. This project aims to investigate the basic science underpinning a new rotation sensing technology based on matterwave vortices. Current gyroscopes are susceptible to long-term calibration drifts, which limit their applicability on long timescales where re-calibration is not practical or possible. This project expects to build a matterwave vortex gyroscope and demonstrate that it offers unparalleled long-term stability over `classical’ gyroscopes based on mechanical and/or optical technology. This could deliver new navigation capabilities, benefitting Australia’s defence forces and nascent space technology industry, as well as enabling slow timescale precision gravimetry for mineral exploration, hydrology, and geology. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100495
Funder
Australian Research Council
Funding Amount
$419,366.00
Summary
Optimising Space-Based Atom Interferometer Design. This theoretical physics project aims to enable high-precision atom interferometry in space. Atom interferometers could allow measurements of unparalleled precision in the low-gravity, low-noise environment of space, however, size, weight, and power constraints must also influence the design of any space-based device. This project expects to develop implementable strategies for the optimal design and performance of space-based atom interferomete ....Optimising Space-Based Atom Interferometer Design. This theoretical physics project aims to enable high-precision atom interferometry in space. Atom interferometers could allow measurements of unparalleled precision in the low-gravity, low-noise environment of space, however, size, weight, and power constraints must also influence the design of any space-based device. This project expects to develop implementable strategies for the optimal design and performance of space-based atom interferometers. This could deliver new space-based sensing capabilities, advancing our capacity to monitor the Earth’s fresh water supply, geology, oceans, and ice caps, as well as precipitating much-needed measurements that probe potential quantum gravitational effects.Read moreRead less