Discovery Early Career Researcher Award - Grant ID: DE190101174
Funder
Australian Research Council
Funding Amount
$395,000.00
Summary
Building a mechanical quantum memory from superfluid helium. This project aims to implement a quantum computer memory module which can be integrated in a future hybrid quantum computer, where the advantages of different quantum platforms are combined. The memory module will be achieved by coupling a superconducting qubit to the surface vibrations of superfluid helium and exchanging quantum information between the qubit and helium. By simulating chemical reactions, the project expects to find cle ....Building a mechanical quantum memory from superfluid helium. This project aims to implement a quantum computer memory module which can be integrated in a future hybrid quantum computer, where the advantages of different quantum platforms are combined. The memory module will be achieved by coupling a superconducting qubit to the surface vibrations of superfluid helium and exchanging quantum information between the qubit and helium. By simulating chemical reactions, the project expects to find cleaner alternatives of current industrial processes, reducing environmental impact. The outcomes should provide significant benefits for testing the validity of quantum mechanics, and by contributing to the realisation of a quantum computer, contribute to broad socio-economic benefits.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
An atom-scale fabrication technique for diamond quantum microprocessors. This project aims to develop an atomically-precise fabrication technique for the production of diamond quantum microprocessors through the pursuit of a novel bottom-up approach. This project expects to create significant new knowledge and capability in precision diamond growth, surface chemistry, electronics and characterisation, establish a long-term strategic partnership between Quantum Brilliance and the participating or ....An atom-scale fabrication technique for diamond quantum microprocessors. This project aims to develop an atomically-precise fabrication technique for the production of diamond quantum microprocessors through the pursuit of a novel bottom-up approach. This project expects to create significant new knowledge and capability in precision diamond growth, surface chemistry, electronics and characterisation, establish a long-term strategic partnership between Quantum Brilliance and the participating organisations, and enable the realisation of high-performance quantum microprocessors. These outcomes will potentially deliver Australia and Quantum Brilliance a profound advantage in quantum computing, thereby securing their positions in the emerging global quantum market and the associated economic and security benefits.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882792
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
High Power Laser, Test Masses, Digital Control System and Vacuum System for High Optical Power Interferometry Experiments. Gravitational waves are expected to offer humanity a completely new spectrum with which to study the Universe. Australia has been a pioneer in the quest to open up this new spectrum. This project will allow Australia to play a key role in a world-wide project which aims for the first time to enable gravitational waves to be detected from black holes and neutron stars through ....High Power Laser, Test Masses, Digital Control System and Vacuum System for High Optical Power Interferometry Experiments. Gravitational waves are expected to offer humanity a completely new spectrum with which to study the Universe. Australia has been a pioneer in the quest to open up this new spectrum. This project will allow Australia to play a key role in a world-wide project which aims for the first time to enable gravitational waves to be detected from black holes and neutron stars throughout the universe. It will give Australia access to developed technologies, and will be a major boost to physical science research and education.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
Resources for Quantum Networks. In classical information theory communication is an important resource. In quantum information theory there are the additional resources of entanglement and quantum communication. The aim of this project is to establish a complete theory of resources for quantum networks, by determining the relation between these resources, their symmetry properties, and effective ways of calculating capacities. Critical issues, such as the networking of quantum computers, quan ....Resources for Quantum Networks. In classical information theory communication is an important resource. In quantum information theory there are the additional resources of entanglement and quantum communication. The aim of this project is to establish a complete theory of resources for quantum networks, by determining the relation between these resources, their symmetry properties, and effective ways of calculating capacities. Critical issues, such as the networking of quantum computers, quantum teleportation and secure communication, require a complete theory of resources. The expected outcome of this project is a rigorous foundation for resources in quantum information that may be used to address these issues.Read moreRead less
Interferometry beyond the Standard Quantum Limit. This research aims to realise measurements below the Standard Quantum Limit (SQL) using advanced quantum optic and opto-mechanical techniques. This is of fundamental interest as the SQL is yet to be observed for a macroscopic object. It is also of particular significance to second generation gravitational wave detectors which are expected to be limited by the SQL. This project will develop an opto-mechanical sensor capable of achieving SQL sensit ....Interferometry beyond the Standard Quantum Limit. This research aims to realise measurements below the Standard Quantum Limit (SQL) using advanced quantum optic and opto-mechanical techniques. This is of fundamental interest as the SQL is yet to be observed for a macroscopic object. It is also of particular significance to second generation gravitational wave detectors which are expected to be limited by the SQL. This project will develop an opto-mechanical sensor capable of achieving SQL sensitivity as well as develop and test techniques to surpass the SQL. These techniques will be directly applicable to long base-line gravitational wave detectors.Read moreRead less
Entanglement as resource for quantum technology. This project focuses on groundbreaking research in quantum information theory, an exciting new area of fundamental physics that underpins the development of quantum technologies. Australia has already invested heavily in one particular quantum technology: computation. Our project, if successful, will enable an Australian research effort into other quantum technologies for communication, metrology, data storage and security. This project will as ....Entanglement as resource for quantum technology. This project focuses on groundbreaking research in quantum information theory, an exciting new area of fundamental physics that underpins the development of quantum technologies. Australia has already invested heavily in one particular quantum technology: computation. Our project, if successful, will enable an Australian research effort into other quantum technologies for communication, metrology, data storage and security. This project will assist in elevating Australia to a major international research centre in quantum information theory, complementing its existing strength in experiment, and will provide extensive training of early career researchers.Read moreRead less
Quantum control in mesoscopic condensed matter systems. Semiconductor devices are at the foundation of modern technology. Industrial nanofabrication techniques can now produce devices near the atomic scale, and state-of-the-art experiments have demonstrated the previously unimaginable ability to manipulate individual electrons. This project will develop new techniques to control such quantum circuits and couple them together to form useful devices. New experiments to test these schemes will be p ....Quantum control in mesoscopic condensed matter systems. Semiconductor devices are at the foundation of modern technology. Industrial nanofabrication techniques can now produce devices near the atomic scale, and state-of-the-art experiments have demonstrated the previously unimaginable ability to manipulate individual electrons. This project will develop new techniques to control such quantum circuits and couple them together to form useful devices. New experiments to test these schemes will be proposed. This project will provide a foundation for future information processing technologies such as quantum computers.Read moreRead less
Quantum-enhanced reference systems. Reference systems, such as gyroscopes and clocks, constructed out of individual atoms or photons can have an incredible precision limited only by the laws of quantum physics. This project will investigate how such reference systems can be constructed and will propose new state-of-the-art experiments which demonstrate their power. This project will provide a foundation for future technologies necessary for navigation and communication systems, and for high-prec ....Quantum-enhanced reference systems. Reference systems, such as gyroscopes and clocks, constructed out of individual atoms or photons can have an incredible precision limited only by the laws of quantum physics. This project will investigate how such reference systems can be constructed and will propose new state-of-the-art experiments which demonstrate their power. This project will provide a foundation for future technologies necessary for navigation and communication systems, and for high-precision measurements needed for scientific and engineering applications. It will resolve many pressing problems regarding the role of reference systems in quantum theory that are currently inhibiting progress in the field.Read moreRead less