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
Simulating chemical reactions on quantum computers. This project aims to enable a new capability for simulating practically relevant chemical dynamics and reactivity in regimes where conventional computational chemistry fails. It expects to do so by generating an extensive toolbox of quantum algorithms that would allow quantum computers to carry out otherwise intractable simulations of a wide range of chemical processes using existing quantum devices. As quantum technology matures, these algorit ....Simulating chemical reactions on quantum computers. This project aims to enable a new capability for simulating practically relevant chemical dynamics and reactivity in regimes where conventional computational chemistry fails. It expects to do so by generating an extensive toolbox of quantum algorithms that would allow quantum computers to carry out otherwise intractable simulations of a wide range of chemical processes using existing quantum devices. As quantum technology matures, these algorithms should enable quantum computers to accelerate computational screening of new chemical processes in a wide range of fields, enabling faster discovery of, for example, improved catalysts, batteries, medicines, fuels, and solar cells.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: 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
A Dual-species Ion Trap with Precision Optical Clocks. This project will enable new technological capabilities to overcome challenges in scaling up quantum computation and advancing quantum clocks. It will develop a versatile dual-species atomic instrumentation paired with precision laser systems. This advanced technological platform will be augmented by an extensive toolbox of quantum control engineering protocols to perform error-robust quantum operations for fault-tolerant quantum computation ....A Dual-species Ion Trap with Precision Optical Clocks. This project will enable new technological capabilities to overcome challenges in scaling up quantum computation and advancing quantum clocks. It will develop a versatile dual-species atomic instrumentation paired with precision laser systems. This advanced technological platform will be augmented by an extensive toolbox of quantum control engineering protocols to perform error-robust quantum operations for fault-tolerant quantum computation and high-precision spectroscopy. The expected outcomes will also benefit other disciplines: advanced quantum simulations for chemical dynamics, precision spectroscopy for astronomy, next-generation lasers, tests of fundamental physics, and quantum-enhanced positioning, navigation, and timing. Read moreRead less
Industry Laureate Fellowships - Grant ID: IL230100072
Funder
Australian Research Council
Funding Amount
$3,759,824.00
Summary
Unleashing the combined power of electrons and holes for quantum computing. Large scale quantum computers promise unprecedented power with applications ranging from searching large databases for images and video, to optimising traffic routing, cryptography, and simulating advanced new materials and drug designs. This Fellowship will partner with Diraq, a world-leading Australian company developing a revolutionary new silicon quantum computing technology, to solve key issues in the race to scale ....Unleashing the combined power of electrons and holes for quantum computing. Large scale quantum computers promise unprecedented power with applications ranging from searching large databases for images and video, to optimising traffic routing, cryptography, and simulating advanced new materials and drug designs. This Fellowship will partner with Diraq, a world-leading Australian company developing a revolutionary new silicon quantum computing technology, to solve key issues in the race to scale from small scale prototypes to industrially relevant quantum computers. It will integrate electrons and holes, semiconducting and superconducting functionalities, into a single platform, link with industrial partners, and reinforce Australia's leadership position in quantum computing technologies.Read moreRead less
If a spin could torque: quantum force sensing with levitated nanodiamonds. This project aims to detect the tiny twisting forces imparted by a single quantum spin on a host diamond nanocrystal levitating in vacuum. Our team will build both a hypersensitive detector of quantum rotations and the complex theoretical models for quantum spin systems coupled to the mechanical motion of nanometre-sized diamonds. The expected experimental capabilities and knowledge generated by this project will enable w ....If a spin could torque: quantum force sensing with levitated nanodiamonds. This project aims to detect the tiny twisting forces imparted by a single quantum spin on a host diamond nanocrystal levitating in vacuum. Our team will build both a hypersensitive detector of quantum rotations and the complex theoretical models for quantum spin systems coupled to the mechanical motion of nanometre-sized diamonds. The expected experimental capabilities and knowledge generated by this project will enable world-first measurements of quantum effects with unparalleled sensitivity and powerful new quantum sensing paradigms. The project should enable significant benefits, such as incisive tests of the limits of quantum theory and new Australian technology operating at the interface of the quantum and classical worlds.Read moreRead less
Quantum non-locality with mass-entangled metastable helium atoms atoms. The aim of this project is to use ultracold helium atoms to test aspects of quantum entanglement. The unique properties of metastable helium will provide significant new knowledge of this fundamental quantum property. Expected outcomes include measuring a Bell test between mass entangled atoms and testing the weak equivalence principle (the universality of free fall) using a quantum entangled state as the test masses. This s ....Quantum non-locality with mass-entangled metastable helium atoms atoms. The aim of this project is to use ultracold helium atoms to test aspects of quantum entanglement. The unique properties of metastable helium will provide significant new knowledge of this fundamental quantum property. Expected outcomes include measuring a Bell test between mass entangled atoms and testing the weak equivalence principle (the universality of free fall) using a quantum entangled state as the test masses. This should provide benefits including input into new theories that attempt to unify quantum mechanics with general relativity and will be relevant for emerging quantum technologies such as more powerful quantum computing or quantum simulation of complex systems.Read moreRead less
Quantum entanglement with atoms: from individual pairs to many-body systems. The aim of this project is to use ultracold helium atoms to test aspects of quantum entanglement. The unique properties of metastable helium will provide significant new knowledge of this fundamental quantum property. Expected outcomes include measuring a Bell test between momentum entangled atoms and showing how many-body entanglement builds up following a quantum quench. This should provide benefits including new theo ....Quantum entanglement with atoms: from individual pairs to many-body systems. The aim of this project is to use ultracold helium atoms to test aspects of quantum entanglement. The unique properties of metastable helium will provide significant new knowledge of this fundamental quantum property. Expected outcomes include measuring a Bell test between momentum entangled atoms and showing how many-body entanglement builds up following a quantum quench. This should provide benefits including new theories that attempt to unify quantum mechanics with general relativity and will be relevant for emerging quantum technologies such as more powerful quantum computing or quantum simulation of complex systems. Read moreRead less
Resonator-enhanced quantum levitation of macroscopic systems. This project aims to develop advanced technologies to optically levitate macroscopic (millimetre-sized) objects and nanoscopic (atomically thin) materials. Levitation platforms built by the investigatory team are based on the resonantly amplified radiation pressure of laser beams. This new type of optical levitation can provide ultimate isolation of the systems from external noise, making them extremely responsive to subtle environmen ....Resonator-enhanced quantum levitation of macroscopic systems. This project aims to develop advanced technologies to optically levitate macroscopic (millimetre-sized) objects and nanoscopic (atomically thin) materials. Levitation platforms built by the investigatory team are based on the resonantly amplified radiation pressure of laser beams. This new type of optical levitation can provide ultimate isolation of the systems from external noise, making them extremely responsive to subtle environmental changes. These platforms could be turned into sharp instruments for measuring metrological variables of interest and probing new physics. Quantum optical techniques could be developed to optimise the sensitivity of levitated systems to levels that allow the exploration of quantum and gravitational physics.Read moreRead less