Controlling ultracold atomic gases. This project will develop ways to control the quantum state of ultracold atomic gases. These experimentally accessible systems will be used to investigate and understand a huge range of scientific phenomena from stars to superconductors, and enable critical quantum technologies that will revolutionise communications and precision measurement.
Harnessing genuine quantum nonlocality. This project aims to develop the science and tools behind device-independent quantum security for information networks. These gold-standard protocols rely on genuine quantum nonlocality but, to date, the strict performance requirements have been unachievable for general practical cases. Further, the theory of nonlocality in multiparty networks is almost completely undeveloped. The project’s anticipated outcomes are novel experiment and theory to bypass bar ....Harnessing genuine quantum nonlocality. This project aims to develop the science and tools behind device-independent quantum security for information networks. These gold-standard protocols rely on genuine quantum nonlocality but, to date, the strict performance requirements have been unachievable for general practical cases. Further, the theory of nonlocality in multiparty networks is almost completely undeveloped. The project’s anticipated outcomes are novel experiment and theory to bypass barriers and open up nonlocal network protocols. It is also expected to rigorously establish that a single-photon wavefunction after a beamsplitter is truly nonlocal. Likely future benefits include secure random numbers, secure distributed information technology and world-best photon sources.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101082
Funder
Australian Research Council
Funding Amount
$433,182.00
Summary
Heralded entangled photons to enable quantum networking and computation. This project aims to advance quantum networking and quantum computation by developing the science of new heralded, i.e. nondestructively verified, entangled states of photons. Despite great potential, photonic quantum technologies have been held back by the lack of key resources in the form of heralded entangled states of photons. Expected outcomes of the project include novel experimental capabilities of heralded state gen ....Heralded entangled photons to enable quantum networking and computation. This project aims to advance quantum networking and quantum computation by developing the science of new heralded, i.e. nondestructively verified, entangled states of photons. Despite great potential, photonic quantum technologies have been held back by the lack of key resources in the form of heralded entangled states of photons. Expected outcomes of the project include novel experimental capabilities of heralded state generation and powerful new theoretical methods for photonic circuit design. This should enable the realisation of quantum protocols with a genuine advantage, a critical step towards practical quantum technologies underlying the next generation of cybersecurity.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100009
Funder
Australian Research Council
Funding Amount
$455,000.00
Summary
Ultra-precision cutting and polishing machines for fabricating high-Q crystalline resonators. The proposed facility will equip Australian researchers with the capability to machine and polish optical crystalline materials down to atomic-level smoothness. The availability of this technology will enable the fabrication of ultra-sensitive metrological sensors, state-of-the-art photonic components, and quantum devices. Precision metrology is an integral component of many industries and it underpins ....Ultra-precision cutting and polishing machines for fabricating high-Q crystalline resonators. The proposed facility will equip Australian researchers with the capability to machine and polish optical crystalline materials down to atomic-level smoothness. The availability of this technology will enable the fabrication of ultra-sensitive metrological sensors, state-of-the-art photonic components, and quantum devices. Precision metrology is an integral component of many industries and it underpins a modern, technically advanced society. With this facility Australian researchers will lead the world in the fabrication of optical crystalline devices for a broad range of industrial and research 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.
Discovery Early Career Researcher Award - Grant ID: DE130100304
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Lithium niobate integrated quantum photonics for cluster state quantum information with continuous variables. A quantum computer capable of solving important problems exponentially faster than any classical machine will have a huge impact in science, technology and society. This project targets this goal using photons as quantum information carriers and miniaturising state of the art quantum optics experiments with innovative micron-size waveguide devices.
Large Scale and Ultrafast Integrated Quantum Photonics in Silicon Carbide. This project will establish a new technological platform for the fabrication of ultra-compact, reconfigurable integrated quantum optical devices in silicon carbide. With this new architecture the project will demonstrate large, reconfigurable optical circuits and integrated single photon detectors where tens of photons can interfere, be manipulated and measured in miniaturised optical devices. The fabrication process will ....Large Scale and Ultrafast Integrated Quantum Photonics in Silicon Carbide. This project will establish a new technological platform for the fabrication of ultra-compact, reconfigurable integrated quantum optical devices in silicon carbide. With this new architecture the project will demonstrate large, reconfigurable optical circuits and integrated single photon detectors where tens of photons can interfere, be manipulated and measured in miniaturised optical devices. The fabrication process will be compatible with current electronic and optical telecommunication technology and will support a new generation of optical devices with a high level scalability and complexity. Finally the project will investigate cavity type structures for the efficient coupling between single photons and atom-like single defects in silicon carbide. Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100045
Funder
Australian Research Council
Funding Amount
$3,245,263.00
Summary
Energy-efficient artificial intelligence using quantum technologies. Artificial intelligence (AI) is transforming society but standard technologies come with significant hidden costs: training even a single, common, learning model can emit 5 times more carbon dioxide than the lifetime emissions of the average car. This Fellowship aims to develop artificial intelligence platforms using Australia’s significant investment in quantum technologies to bypass traditional approaches to AI. The expected ....Energy-efficient artificial intelligence using quantum technologies. Artificial intelligence (AI) is transforming society but standard technologies come with significant hidden costs: training even a single, common, learning model can emit 5 times more carbon dioxide than the lifetime emissions of the average car. This Fellowship aims to develop artificial intelligence platforms using Australia’s significant investment in quantum technologies to bypass traditional approaches to AI. The expected outcomes are neuromorphic computers that operate efficiently—with low-energy cost—and rapidly—achieving speeds impossible with conventional electronic approaches. The anticipated benefits are transformative technologies for AI, new applications across society, and new tools for exploring brain function and cognition.Read moreRead less
New high aspect ratio roll-to-roll compatible ultraviolet polysiloxane nanoimprinting for low cost consumer, medical, and quantum devices. This project will explore materials and processes for the creation of low cost optical waveguide devices from hybrid polysiloxane materials with applications in consumer products, sensing, health monitoring and fundamental physics. The outcome will pave the way for new approaches to manufacturing opening up new markets for the technology.
Fundamental quantum science for advancing optical quantum technologies. Quantum science promises a technology revolution comparable to the emergence of the information age. This project will advance the quantum technology revolution by uncovering new concepts in fundamental quantum science, and applying them to the development of absolutely secure communications, ultraprecise measurements, and ultrafast information processing.