Non-classical motion of a macroscopic mechanical resonator. This project will create the experimental tools to fully control the motion of a mechanical oscillator at the single-quanta level, opening a rich avenue for fundamental research and the development of quantum physics enhanced applications. This project will prepare a quantum state of a macroscopic mechanical resonator exhibiting quantum interference fringes at at an unprecedented mass scale. The observation of these fringes will enable ....Non-classical motion of a macroscopic mechanical resonator. This project will create the experimental tools to fully control the motion of a mechanical oscillator at the single-quanta level, opening a rich avenue for fundamental research and the development of quantum physics enhanced applications. This project will prepare a quantum state of a macroscopic mechanical resonator exhibiting quantum interference fringes at at an unprecedented mass scale. The observation of these fringes will enable the study of the intricacies of quantum decoherence and ultimately even probe quantum gravitational phenomena. To achieve these goals it will employ micro-scale optical resonators fabricated by established techniques, that also provide the ideal platform for scalable mechanical-oscillator-based quantum information applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101899
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Developing the next generation of single and entangled photon sources. Low noise and efficient sources of single and entangled photons are important resources to implement a scalable platform for large-scale quantum information tasks. This project will develop the prototypes for these sources which will be suitable for a wide range of interesting applications in quantum information.
Quantum networks based on superconducting circuits and dissipative channels. Superconducting circuits have great potential for probing and using quantum nature on a chip but lack networking capabilities between remote sites. However, non-local quantum correlations are critical for quantum devices to surpass classical systems. This project aims to create capabilities for establishing entanglement between remote superconducting chips using non-local dissipative interaction. Within this approach th ....Quantum networks based on superconducting circuits and dissipative channels. Superconducting circuits have great potential for probing and using quantum nature on a chip but lack networking capabilities between remote sites. However, non-local quantum correlations are critical for quantum devices to surpass classical systems. This project aims to create capabilities for establishing entanglement between remote superconducting chips using non-local dissipative interaction. Within this approach the created entanglement can be also preserved as long as necessary as a resource for quantum protocols. The resulting technology is expected to enable quantum information processing in superconducting circuits on fundamentally larger scales and provides a powerful platform to test the limits for building artificial quantum systems.Read moreRead less
Distributed quantum networks with cascaded superconducting circuits. At the heart of all communication is the need to establish strong correlations between remote sites. The non-local character of quantum correlations enables new communication protocols that are impossible with classical resources alone. This project aims to realise a novel class of superconducting devices capable of establishing quantum correlations between distant electronic chips through long-range irreversible interactions. ....Distributed quantum networks with cascaded superconducting circuits. At the heart of all communication is the need to establish strong correlations between remote sites. The non-local character of quantum correlations enables new communication protocols that are impossible with classical resources alone. This project aims to realise a novel class of superconducting devices capable of establishing quantum correlations between distant electronic chips through long-range irreversible interactions. The resulting technology will enable completely new approaches to quantum information processing in superconducting quantum circuits and provide a powerful platform to test the limits of the ability to engineer macroscopic quantum systems.Read moreRead less
Optical circuits for quantum non-locality with single photons. This collaborative project between the University of Queensland and Hokkaido University will investigate fundamental aspects of quantum mechanics concerned with non-locality. The results will have direct relevance to the emerging field of quantum technology - new technologies based exploiting the quantum mechanical nature of physical systems. Through the collaboration Australia will gain access to world-class single photon generation ....Optical circuits for quantum non-locality with single photons. This collaborative project between the University of Queensland and Hokkaido University will investigate fundamental aspects of quantum mechanics concerned with non-locality. The results will have direct relevance to the emerging field of quantum technology - new technologies based exploiting the quantum mechanical nature of physical systems. Through the collaboration Australia will gain access to world-class single photon generation facilities that will be replicated here. A strong link between Japanese and Australian researchers, including students, will be formed.Read moreRead less
Quantum Atom Optics and Single Atom Detection with Micro-Bose-Einstein Condensates. A Bose Einstein condensate (BEC) is a collection of atoms, all in the same quantum state, like the photons in a laser. It is now possible to create a micro-BEC and move it around on an 'atom chip'. We propose an experimental and theoretical study of its properties including those quantum statistical effects which will limit future ultra-sensitive measurement technologies such as quantum electromechanical transdu ....Quantum Atom Optics and Single Atom Detection with Micro-Bose-Einstein Condensates. A Bose Einstein condensate (BEC) is a collection of atoms, all in the same quantum state, like the photons in a laser. It is now possible to create a micro-BEC and move it around on an 'atom chip'. We propose an experimental and theoretical study of its properties including those quantum statistical effects which will limit future ultra-sensitive measurement technologies such as quantum electromechanical transducers. We will develop methods to count small numbers of ultra-cold atoms, engineer their state and build a prototype device.Read moreRead less
Controlling quantum technologies. Australia is a leader in quantum technology - from molecular machines to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. Our project will enhance the nation's profile in this discipline by developing some of the ground rules for measuring and controlling the operation of quantum devices. This foundational work will put Australian theoretical and experimental researchers at the forefront of this new field, an ....Controlling quantum technologies. Australia is a leader in quantum technology - from molecular machines to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. Our project will enhance the nation's profile in this discipline by developing some of the ground rules for measuring and controlling the operation of quantum devices. This foundational work will put Australian theoretical and experimental researchers at the forefront of this new field, and there is significant opportunity for development of intellectual property such as patents. Young researchers and postgraduate students will play a substantial role in the project, maximising the training impact for new professionals in cutting-edge science and high technology.Read moreRead less
Quantum Measurement, Control and Information: Forging Links to Underpin Quantum Technology. The 21st century is seeing the birth of the first truly quantum technologies - devices whose operation can only be explained using quantum physics - which can outperform any conventional technology. This project will advance new theoretical foundations for designing quantum technologies by forging links between the three key areas of quantum measurement, control, and information. It will also establish th ....Quantum Measurement, Control and Information: Forging Links to Underpin Quantum Technology. The 21st century is seeing the birth of the first truly quantum technologies - devices whose operation can only be explained using quantum physics - which can outperform any conventional technology. This project will advance new theoretical foundations for designing quantum technologies by forging links between the three key areas of quantum measurement, control, and information. It will also establish the first experimental laboratory in Australia to test these new theories. As the miniaturization of technology continues, quantum design principles will be required for more and more devices. The discoveries made will help keep Australian science at the forefront of this revolution.Read moreRead less
Integrated quantum photonics. Australia is a leader in quantum science and technology - from nanotechnology to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. This project will enhance the nation's profile in this discipline by developing a new technology that allows photons - single particles of light - to be added together to form powerful quantum machines; and using this to explore the phenomenon that makes quantum technology powerful. Th ....Integrated quantum photonics. Australia is a leader in quantum science and technology - from nanotechnology to quantum computers, amazing advances are being made possible as we harness the laws of quantum physics. This project will enhance the nation's profile in this discipline by developing a new technology that allows photons - single particles of light - to be added together to form powerful quantum machines; and using this to explore the phenomenon that makes quantum technology powerful. This work will put Australian researchers at the forefront of new quantum technologies. Young researchers and postgraduate students will play a substantial role in the project, maximising the training impact for new professionals in cutting-edge science and high technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775637
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
An Australian Attosecond Science Facility. The laser facility requested here will provide Australian researchers with the ability to take snapshots of physical and biological processes at unprecedented time resolution. Such a facility will enable Australian researchers to remain competitive and continue to contribute significantly to scientific research on an international scale. The facility will provide excellent training for research higher degree students, preparing them for work in high-tec ....An Australian Attosecond Science Facility. The laser facility requested here will provide Australian researchers with the ability to take snapshots of physical and biological processes at unprecedented time resolution. Such a facility will enable Australian researchers to remain competitive and continue to contribute significantly to scientific research on an international scale. The facility will provide excellent training for research higher degree students, preparing them for work in high-tech industries based on cutting-edge discoveries in physics and biology.Read moreRead less