Memory and light for integrated quantum systems. Optical quantum information technologies have the potential to change the way we work and play, but there are problems to be overcome: we lack both a memory for quantum information and reliable light sources that can be integrated into quantum networks. This project addresses both these issues and will bring quantum technologies closer to market.
Towards an intercontinental quantum network. This project aims to address the security vulnerabilities of online data transmission. Cyber attacks and data stealing are threatening the daily operations of public and private organisations worldwide, and the privacy of individuals. This project expect to realise the key element for a new global network architecture where security is guaranteed by the fundamental laws of physics. This element is the quantum node and it will be implemented through th ....Towards an intercontinental quantum network. This project aims to address the security vulnerabilities of online data transmission. Cyber attacks and data stealing are threatening the daily operations of public and private organisations worldwide, and the privacy of individuals. This project expect to realise the key element for a new global network architecture where security is guaranteed by the fundamental laws of physics. This element is the quantum node and it will be implemented through the development of new techniques for the control and manipulation of individual atoms and innovative integrated optical devices for the interface with fibre networks. The development of this technology will lead to intrinsically secure online communication for organisations in the health and defence sectors and private individuals worldwide.Read moreRead less
Quantum-Assisted Sensing. Modern physics has been very successful at developing incredibly precise theoretical descriptions of nature. Can exquisitely accurate models of the interaction between light and matter, to push sensing and measurement far beyond the current state-of-the art, be exploited? This project aims to address this question, focussing on three domains of measurement: temperature, time and power. Improving sensors and measurement has been the cornerstone of new physical discoverie ....Quantum-Assisted Sensing. Modern physics has been very successful at developing incredibly precise theoretical descriptions of nature. Can exquisitely accurate models of the interaction between light and matter, to push sensing and measurement far beyond the current state-of-the art, be exploited? This project aims to address this question, focussing on three domains of measurement: temperature, time and power. Improving sensors and measurement has been the cornerstone of new physical discoveries, with applications from radio-astronomy to quantum information and navigation. This project aims to build the theoretical foundations for world-beating thermometers, clocks, and photon counters, and to guide experiments in Australia and abroad to bring them into reality.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100037
Funder
Australian Research Council
Funding Amount
$223,039.00
Summary
Cryogenic quantum microscope facility. This project aims to establish a cryogenic, quantum microscope facility in Australia. Quantum sensing is a new field that harnesses the properties of individual quantum systems to realise new types of detection and imaging with unprecedented combination of sensitivity and spatial resolution. The potential innovations, applications and benefits to society are far reaching across the full spectrum of scientific and engineering activity, from the development o ....Cryogenic quantum microscope facility. This project aims to establish a cryogenic, quantum microscope facility in Australia. Quantum sensing is a new field that harnesses the properties of individual quantum systems to realise new types of detection and imaging with unprecedented combination of sensitivity and spatial resolution. The potential innovations, applications and benefits to society are far reaching across the full spectrum of scientific and engineering activity, from the development of atomic-scale imaging of protein structures for drug discovery, to the study of chemical, physical, and biological processes and materials for advanced technology and manufacturing.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL130100119
Funder
Australian Research Council
Funding Amount
$3,110,000.00
Summary
New views of life: quantum imaging in biology. This project will create and apply new technology, based on the quantum properties of diamond, to attack important problems in biology; from how cells differentiate at the beginning of life, to understanding brain function. The results of this project will directly benefit society through the development of new technology for nano-medicine and drug discovery.
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
Quantum physics and complexity. How much information about a system’s present is needed to predict its future? This project aims to show that the answer fundamentally depends on how information is stored. Simulations of partially random processes are critical in real-world applications. Surprisingly, theory suggests that a simulation must store much more classical data (like bits) than is required to determine its output. This wastes precious resources. Via optical quantum information experiment ....Quantum physics and complexity. How much information about a system’s present is needed to predict its future? This project aims to show that the answer fundamentally depends on how information is stored. Simulations of partially random processes are critical in real-world applications. Surprisingly, theory suggests that a simulation must store much more classical data (like bits) than is required to determine its output. This wastes precious resources. Via optical quantum information experiments, the project aims to demonstrate and characterise how storing and handling data in quantum states massively reduces this complexity overhead. Another goal is to use novel quantum optics ideas to greatly reduce communication complexity in important remote processing tasks.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100356
Funder
Australian Research Council
Funding Amount
$327,216.00
Summary
Quantum measurements: new, better, easier. This project aims to: engineer new state-of-the-art quantum measurements; devise the best ways of sensing quantum signals; and make quantum measurements and characterisation of large quantum systems easier to do. Quantum measurements are the principal means by which we gain access to and characterise the quantum world. The new, better and easier measurements that should result from this project will greatly advance quantum technologies. Specifically, th ....Quantum measurements: new, better, easier. This project aims to: engineer new state-of-the-art quantum measurements; devise the best ways of sensing quantum signals; and make quantum measurements and characterisation of large quantum systems easier to do. Quantum measurements are the principal means by which we gain access to and characterise the quantum world. The new, better and easier measurements that should result from this project will greatly advance quantum technologies. Specifically, they should allow for more efficient characterisation of quantum computers and enable us to engineer the ultimate quantum sensors, enhance mineral prospecting; and make building a quantum computer practical.Read moreRead less
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: DE170101371
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Designer defects in diamond for solid state quantum networks. This project aims to develop an artificial atom in diamond that can connect to other nodes in a network. Network connectivity and data distribution are increasingly important in today's information economy. Tiny glowing artificial atoms in coloured diamonds can receive, store and send information in a network using laser light and microwaves. Because they work at the level of individual atoms and photons, they can use quantum-weirdnes ....Designer defects in diamond for solid state quantum networks. This project aims to develop an artificial atom in diamond that can connect to other nodes in a network. Network connectivity and data distribution are increasingly important in today's information economy. Tiny glowing artificial atoms in coloured diamonds can receive, store and send information in a network using laser light and microwaves. Because they work at the level of individual atoms and photons, they can use quantum-weirdness to achieve feats impossible even for supercomputers on the classical internet. The proposed device is expected to make it easier to construct technologies that move beyond the limitations of existing infrastructure thus satisfying the unmet core requirements for a quantum network.Read moreRead less