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
Discovery Early Career Researcher Award - Grant ID: DE240100587
Funder
Australian Research Council
Funding Amount
$443,347.00
Summary
A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging wit ....A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging with resolution more than 20 times better than any existing telescope. This will provide significant benefits for astronomy, space situational awareness, and defence.Read moreRead less
Terahertz lasers in the fight against illicit substances. This project aims to investigate the application of cutting-edge terahertz laser technology with new spectroscopic methods, for detection of illicit substances. Using a collaborative approach, the project aims to bring together expertise in laser physics, spectroscopy, law enforcement and instrumentation, and seeks to develop new sources and detection protocols which will offer new capabilities to law enforcement, aiding in detection and ....Terahertz lasers in the fight against illicit substances. This project aims to investigate the application of cutting-edge terahertz laser technology with new spectroscopic methods, for detection of illicit substances. Using a collaborative approach, the project aims to bring together expertise in laser physics, spectroscopy, law enforcement and instrumentation, and seeks to develop new sources and detection protocols which will offer new capabilities to law enforcement, aiding in detection and identification protocols for illicit substances.Read moreRead less
Unshackling solitons through ultimate dispersion control. The project aims to generate and investigate several novel families of self-stabilising optical pulses by using a unique fibre laser we recently devised. By developing the associated theoretical models, the team will transform conceptual and experimental knowledge of nonlinear physics, providing deep insights into fibre lasers and the pulses they can emit. The expected outcomes are a complete understanding of entirely novel families of op ....Unshackling solitons through ultimate dispersion control. The project aims to generate and investigate several novel families of self-stabilising optical pulses by using a unique fibre laser we recently devised. By developing the associated theoretical models, the team will transform conceptual and experimental knowledge of nonlinear physics, providing deep insights into fibre lasers and the pulses they can emit. The expected outcomes are a complete understanding of entirely novel families of optical pulses, and of the degree to which the energy required to generate these pulses can be reduced. Reducing this energy means that these pulses can perform the same function at lower power, which will enable the emergence of new applications that will play powerful roles in the 21st-century economy.Read moreRead less
Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outc ....Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outcomes include highly developed theoretical insights into solid-state emitters and how to control their interactions with light and other fields. The expected benefit based on the ability to engineer optimised emitters for optical sensors and quantum technologies will transform material science from exploration to design.Read moreRead less
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
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
Agile synthesizers for quantum computing, simulation and sensing. The project aims to develop breakthrough technology for generating the complex radio and microwave pulses that underpin the revolution in quantum computing and quantum sensing. Quantum technologies are rapidly emerging from laboratory to real-world applications including neural imaging, defence surveillance, and mining exploration, but further advances require increased precision and flexibility in controlling the quantum states ....Agile synthesizers for quantum computing, simulation and sensing. The project aims to develop breakthrough technology for generating the complex radio and microwave pulses that underpin the revolution in quantum computing and quantum sensing. Quantum technologies are rapidly emerging from laboratory to real-world applications including neural imaging, defence surveillance, and mining exploration, but further advances require increased precision and flexibility in controlling the quantum states at the heart of these new capabilities. Our innovative and more flexible approach to signal generation requires a fraction of the size, weight, power and cost of conventional approaches, enabling the translation of quantum technology to commercial practicality.Read moreRead less
ARC Centre of Excellence in Quantum Biotechnology. ARC Centre of Excellence in Quantum Biotechnology. The ARC Centre of Excellence in Quantum Biotechnology aims to develop paradigm-shifting quantum technologies to observe biological processes and transform our understanding of life. It seeks to create technologies that go far beyond what is possible today, from portable brain imagers to super-fast single protein sensors, and to use them to unravel key problems including how enzymes catalyse reac ....ARC Centre of Excellence in Quantum Biotechnology. ARC Centre of Excellence in Quantum Biotechnology. The ARC Centre of Excellence in Quantum Biotechnology aims to develop paradigm-shifting quantum technologies to observe biological processes and transform our understanding of life. It seeks to create technologies that go far beyond what is possible today, from portable brain imagers to super-fast single protein sensors, and to use them to unravel key problems including how enzymes catalyse reactions and how higher brain function emerges from networks of neurons. By building a diverse, multidisciplinary, and industry-engaged ecosystem, the Centre means to develop our future leaders at the interface of quantum science and biology and drive Australian innovation across manufacturing, energy, agriculture, health, and national security.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100972
Funder
Australian Research Council
Funding Amount
$382,462.00
Summary
Reaching deeper into neuronal networks using optical physics. Understanding the functions and intricacies of the brain is a fundamental challenge in scientific research. This project aims to develop new technologies to construct a microscope able to alter and make sense of neuronal activity in situ. This project also aims to investigate the precise role of a key brain region involved in sensory processing: the locus coeruleus. The results will reveal how this brain region influences brain dynami ....Reaching deeper into neuronal networks using optical physics. Understanding the functions and intricacies of the brain is a fundamental challenge in scientific research. This project aims to develop new technologies to construct a microscope able to alter and make sense of neuronal activity in situ. This project also aims to investigate the precise role of a key brain region involved in sensory processing: the locus coeruleus. The results will reveal how this brain region influences brain dynamics as well as behaviour. Expected outcomes include state of the art microscopes, high impact publications, and international collaborations. The anticipated benefits are the high quality training of the Australian workforce and further establishment of Australia as a leader in microscopy and neuroscience.Read moreRead less