Performing cold microwave measurements with warm diamonds. Detecting weak microwave signals at room temperature is an exceptionally difficult task, due to the excessive thermal microwave noise that exists all around us. At present, the best microwave receivers must be cooled to cryogenic temperatures, restricting their widespread use. This project aims to apply diamond-based quantum technologies to achieve unprecedented microwave signal detection sensitivities with a room-temperature setup, prov ....Performing cold microwave measurements with warm diamonds. Detecting weak microwave signals at room temperature is an exceptionally difficult task, due to the excessive thermal microwave noise that exists all around us. At present, the best microwave receivers must be cooled to cryogenic temperatures, restricting their widespread use. This project aims to apply diamond-based quantum technologies to achieve unprecedented microwave signal detection sensitivities with a room-temperature setup, providing more accessible ultra-low noise detectors. The ability to measure weak microwave signals is crucial for a range of sectors and the results of this project are expected to have applications in defence (radar), space exploration (satellite communication), and fundamental research (spectroscopy).Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100144
Funder
Australian Research Council
Funding Amount
$415,154.00
Summary
Quantum-enabled super-resolution imaging. The aim is to design large scale, quantum-enabled imaging systems to boost the resolution of state-of-the-art instruments by three to five orders of magnitude. Using the toolbox of quantum information and quantum optics, the project expects to generate novel methods for 2D and 3D imaging, and precision measurements that can reach fundamental limits. Imaging is critical in much of today's research. The unparalleled resolution can benefit a broad range of ....Quantum-enabled super-resolution imaging. The aim is to design large scale, quantum-enabled imaging systems to boost the resolution of state-of-the-art instruments by three to five orders of magnitude. Using the toolbox of quantum information and quantum optics, the project expects to generate novel methods for 2D and 3D imaging, and precision measurements that can reach fundamental limits. Imaging is critical in much of today's research. The unparalleled resolution can benefit a broad range of scientific fields, the medical and the defence sector by resolving objects otherwise impossible. This project will strengthen Australia’s position as a world leader in quantum technologies by presenting solutions to overcome critical bottlenecks in imaging methods in the optical domain.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100045
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcome ....Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcomes include the creation of new intellectual property, enhanced engagement with industry, and will further boost Australia's efforts to build a commercially scalable quantum computer. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100590
Funder
Australian Research Council
Funding Amount
$457,500.00
Summary
On-chip microwave generation and detection with Josephson photonics . The ability to generate and detect a single photon, a single particle of light, is a key requirement of many quantum technologies from quantum sensors, to quantum computing and quantum communications protocols. This project aims to develop next-generation microwave photon sources and detectors that are based on superconducting effects. It will lead to new knowledge in how to control, entangle and detect single microwave photon ....On-chip microwave generation and detection with Josephson photonics . The ability to generate and detect a single photon, a single particle of light, is a key requirement of many quantum technologies from quantum sensors, to quantum computing and quantum communications protocols. This project aims to develop next-generation microwave photon sources and detectors that are based on superconducting effects. It will lead to new knowledge in how to control, entangle and detect single microwave photons in order to make devices that are simpler to build and operate and more efficient than state-of-the-art technologies. This has direct economic benefits in developing new sensors for biological, chemical and astronomical processes and will advance Australia's efforts to build a scalable quantum computer. Read moreRead less
ARC Centre of Excellence for Engineered Quantum Systems. This Centre aims to build sophisticated quantum machines to harness the quantum world for the future health, economy, environment and security of Australian society. It intends to pioneer the designer quantum materials, engines and imaging systems at the heart of these machines. It also solves the most challenging research problems at the interface of basic quantum physics and engineering. The Centre will work with industry partners to tra ....ARC Centre of Excellence for Engineered Quantum Systems. This Centre aims to build sophisticated quantum machines to harness the quantum world for the future health, economy, environment and security of Australian society. It intends to pioneer the designer quantum materials, engines and imaging systems at the heart of these machines. It also solves the most challenging research problems at the interface of basic quantum physics and engineering. The Centre will work with industry partners to translate these research discoveries into practical applications and devices. It will train scientists in research, innovation, and entrepreneurship, which is expected to affect Australia’s high-tech economy.Read moreRead less
Chaotic Semiconductor Lasers and Controllability of Semiconductor Laser Noise. Chaotic semiconductor lasers (CSLs) are emerging as a potentially important light source for optical communication systems with improved security. Novel designs for compact, practical CSLs that can be integrated into existing optical communications networks will result. CSL systems suitable for secure point-to-point optical communication systems will also be developed. Fabrication of the devices in Australia means th ....Chaotic Semiconductor Lasers and Controllability of Semiconductor Laser Noise. Chaotic semiconductor lasers (CSLs) are emerging as a potentially important light source for optical communication systems with improved security. Novel designs for compact, practical CSLs that can be integrated into existing optical communications networks will result. CSL systems suitable for secure point-to-point optical communication systems will also be developed. Fabrication of the devices in Australia means there is the opportunity for commercial exploitation at a national level. The scientific study of the characteristics of the CSLs, especially the chaos, will be interesting to the scientific and general community. The early career researchers involved will benefit from high quality professional development experiences.Read moreRead less
Outmaneuvering correlated noise in quantum computers. The project aims to characterise and control quantum machines available today. These machines overwhelmingly suffer from noise with complex structures. Thus, a key target of the project is to develop a theory to describe and manipulate complex quantum processes. The project then intends to apply this theory to commercial-grade quantum computers. This approach is anticipated to lead to a new understanding of time-correlated complex quantum pro ....Outmaneuvering correlated noise in quantum computers. The project aims to characterise and control quantum machines available today. These machines overwhelmingly suffer from noise with complex structures. Thus, a key target of the project is to develop a theory to describe and manipulate complex quantum processes. The project then intends to apply this theory to commercial-grade quantum computers. This approach is anticipated to lead to a new understanding of time-correlated complex quantum processes and develop methods to enhance the performance of today's quantum computers. Noise characterisation and mitigation should have commercial value and benefit research groups working to develop quantum technologies, both in Australia and internationally.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100396
Funder
Australian Research Council
Funding Amount
$764,472.00
Summary
Scalable semiconductor quantum processor with flip chip bonding technology. Australia is famous for quantum computing research based on electron spin in silicon quantum dot. This project aims to enable the manufacturing of such scalable quantum processor. Currently, superconducting quantum processor has reached >100 of qubits by the utilization of 3D integration fabrication technology such as flip chip bonding. Likewise, for semiconductor spin-qubit to grow, it is inevitable that novel 3D archit ....Scalable semiconductor quantum processor with flip chip bonding technology. Australia is famous for quantum computing research based on electron spin in silicon quantum dot. This project aims to enable the manufacturing of such scalable quantum processor. Currently, superconducting quantum processor has reached >100 of qubits by the utilization of 3D integration fabrication technology such as flip chip bonding. Likewise, for semiconductor spin-qubit to grow, it is inevitable that novel 3D architecture by expanding the building block to the next dimension must be explored to pave the way to scalable semiconductor quantum processor. This project will spearhead Australia's semiconductor quantum processor to the realm of hundreds of qubits and put this technology on par with superconducting quantum processor.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101148
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Quantum state translation in integrated optics: enabling multicolour quantum processing. This project aims to use nonlinear effects in photonic waveguide devices to shift the energies of photons, single particles of light, from one state to another. This will have a profound impact on provably secure quantum communication and potentially provide novel routes to the building of a quantum computer.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100131
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
National Facility for Cryogenic Photonics. National facility for cryogenic photonics: The project will establish a multi-disciplinary, multi-user facility for the development and analysis of photonic materials and devices at cryogenic temperatures, heralding a new paradigm in quantum optical research in Australia. The two nodes, one for photonic materials development and one for quantum device characterisation, will enable new physical phenomena to be discovered, new materials to be developed an ....National Facility for Cryogenic Photonics. National facility for cryogenic photonics: The project will establish a multi-disciplinary, multi-user facility for the development and analysis of photonic materials and devices at cryogenic temperatures, heralding a new paradigm in quantum optical research in Australia. The two nodes, one for photonic materials development and one for quantum device characterisation, will enable new physical phenomena to be discovered, new materials to be developed and will ultimately result in the creation of ground-breaking new photonic technologies. This collaborative facility will play a role in the quantum revolution, hailed as the next major step in societal evolution, providing breakthroughs in modern technology and placing Australia at the forefront of this field.Read moreRead less