Discovery Early Career Researcher Award - Grant ID: DE130100575
Funder
Australian Research Council
Funding Amount
$373,944.00
Summary
Quantum enhancement for ultra-precise atomic sensors. This project will investigate methods for drastically improving the sensitivity of measurement devices derived from atom interferometers. This will enable experimental tests of certain aspects of fundamental physics, as well as practical tools such as ultra-precise geodesy for minerals exploration.
Discovery Early Career Researcher Award - Grant ID: DE130100240
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Deterministic photonic quantum gates by amplified optical nonlinearities. Quantum devices will reshape future technology in ways similar to the information revolution heralded by modern computing. This proposal will combine theoretic advances in optical sciences with cutting-edge materials to build photonic quantum gates, removing the last major roadblock on the path to photonic quantum computers and simulators.
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
Advanced Quantum Sensors for Next-Generation Sensing Applications. The aim of this theoretical physics project is to develop ultra-precise sensing capabilities for two main applications: ultrastable inertial sensors for improved navigation and gravimetry, and to search for signatures of quantum gravity. This project expects to improve the performance of quantum sensors via the use of machine optimisation, and may lead to much-needed experimental data to help guide one of the most challenging pro ....Advanced Quantum Sensors for Next-Generation Sensing Applications. The aim of this theoretical physics project is to develop ultra-precise sensing capabilities for two main applications: ultrastable inertial sensors for improved navigation and gravimetry, and to search for signatures of quantum gravity. This project expects to improve the performance of quantum sensors via the use of machine optimisation, and may lead to much-needed experimental data to help guide one of the most challenging problems in theoretical physics: the quantisation of gravity. The expected outcomes of this project are enhanced quantum sensor design, leading to improved inertial sensing technology. This should provide benefits such as improved capabilities for minerals exploration and monitoring the movement of ground water.Read moreRead less
Plasmonic nano-antennas for next-generation photon sources. Extending concepts from standard radio-frequency antenna technology down to the nanoscale will open up new applications in fields from biotechnology to telecommunications. This project will embed a light emitting particle in a nanostructured metallic device to produce an ultrabright, directional single-photon source.
Spinning spins: measuring geometric phases in rotating quantum systems. The quantum geometric phase has long been viewed as an interesting, but somewhat mysterious, feature of quantum mechanics. However, the ability to harness and control geometric phase in individual quantum systems may drive the development of a new class of quantum technologies. This project aims to measure, for the first time, geometric phase due to the macroscopic motion of an atom-scale quantum system, specifically in rota ....Spinning spins: measuring geometric phases in rotating quantum systems. The quantum geometric phase has long been viewed as an interesting, but somewhat mysterious, feature of quantum mechanics. However, the ability to harness and control geometric phase in individual quantum systems may drive the development of a new class of quantum technologies. This project aims to measure, for the first time, geometric phase due to the macroscopic motion of an atom-scale quantum system, specifically in rotating nitrogen-vacancy defects in diamond. It is expected that these proof-of-principle measurements will provide the basis for the future development and design of new nano-scale quantum gyroscopes and set the foundations for using nano-diamonds as rotational diagnostic tools in a range of important nanoscopic systems.Read moreRead less
Optically resonant dielectric structures for nanophotonics. This project aims to develop a novel research program underpinning the rapid development of a new generation of low-loss nanophotonics based on the physics of optically resonant dielectric nanoparticles. Such nanoparticles are the best candidates for the emerging field of metadevices with unique functionalities well beyond the capabilities of currently existing devices. The project aims to explore the confluence of subwavelength photoni ....Optically resonant dielectric structures for nanophotonics. This project aims to develop a novel research program underpinning the rapid development of a new generation of low-loss nanophotonics based on the physics of optically resonant dielectric nanoparticles. Such nanoparticles are the best candidates for the emerging field of metadevices with unique functionalities well beyond the capabilities of currently existing devices. The project aims to explore the confluence of subwavelength photonics, metamaterial concepts, graphene physics, and nonlinear optics. The expected outcomes of this research will enable the design and world-first experimental demonstration of ultra-thin, tunable, and low-loss metadevices for novel optical technologies with unique energy harvesting, switching, and sensing functionalities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100810
Funder
Australian Research Council
Funding Amount
$343,450.00
Summary
Optical tweezers for bio-nanotechnologies. This project aims to develop a platform of diamond nanosensors and novel optical tweezers for probing cellular processes with single-molecule resolution, in vivo and over physiologically relevant time scales. In biomedicine, long-term imaging of single-molecules is beyond reach with existing bio-labels. The project combines the superior properties of nanodiamond biomarkers (brightness, stability, small size and non-toxicity), with new optical tweezers w ....Optical tweezers for bio-nanotechnologies. This project aims to develop a platform of diamond nanosensors and novel optical tweezers for probing cellular processes with single-molecule resolution, in vivo and over physiologically relevant time scales. In biomedicine, long-term imaging of single-molecules is beyond reach with existing bio-labels. The project combines the superior properties of nanodiamond biomarkers (brightness, stability, small size and non-toxicity), with new optical tweezers which exploit laser trapping of atoms to manipulate nanodiamonds in three-dimensional biological environments. By accessing smaller size and higher force regimes, the platform will improve bio-imaging and bio-manipulation techniques, and potentially advance pathogentracking and early detection of diseases.Read moreRead less
Optical frequency conversion in nonlinear dielectric metasurfaces. This project aims to investigate the mixing of light colours in semiconductor nanocrystals arranged in an ultra-thin transparent film, called a nonlinear metasurface. Understanding of the resonant nonlinear interactions in such metasurfaces will allow for the up and down frequency conversion of light beams and images with efficiencies well beyond current capabilities. The outcomes of the project will form the basis for novel cost ....Optical frequency conversion in nonlinear dielectric metasurfaces. This project aims to investigate the mixing of light colours in semiconductor nanocrystals arranged in an ultra-thin transparent film, called a nonlinear metasurface. Understanding of the resonant nonlinear interactions in such metasurfaces will allow for the up and down frequency conversion of light beams and images with efficiencies well beyond current capabilities. The outcomes of the project will form the basis for novel cost-effective and compact devices for infrared imaging, and will also enable ultra-fast sources of quantum light with tailored spatial and spectral correlations. These will benefit important applications in defence and security, including night vision, security holograms, quantum cryptography and communications.Read moreRead less
Dual nanoparticles to distinguish between right and left biomolecules. This project aims to enhance the sensitivity of optical activity to ultralow molecular concentration samples. Optical activity is a commercially available technique used to distinguish chemically identical and morphologically different biomolecules (enantiomers). Unlike other scattering techniques, near-field enhancing of optical activity has not been achieved, thus limiting these measurements to high molecular concentrations ....Dual nanoparticles to distinguish between right and left biomolecules. This project aims to enhance the sensitivity of optical activity to ultralow molecular concentration samples. Optical activity is a commercially available technique used to distinguish chemically identical and morphologically different biomolecules (enantiomers). Unlike other scattering techniques, near-field enhancing of optical activity has not been achieved, thus limiting these measurements to high molecular concentrations. There is evidence indicating that optical activity can be enhanced using dual nanoparticles (ie small particles with the same response to electric and magnetic fields). This project aims to advance our understanding of these dual nanoparticles and experimentally implement their use to enhance optical activity.Read moreRead less