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Laser threshold sensing. This project aims to create a new class of room-temperature ultra-sensitive magnetometers based on laser threshold magnetometry. By using nitrogen-vacancy colour centres in diamond, these magnetometers will demonstrate at least femto-Tesla per root Hertz sensitivity, and could replace SQUID magnetometers. This project aims to develop its theoretical concept into a platform for advanced sensing with applications in magneto-encephalography, nerve sensing, MRI imaging, mini ....Laser threshold sensing. This project aims to create a new class of room-temperature ultra-sensitive magnetometers based on laser threshold magnetometry. By using nitrogen-vacancy colour centres in diamond, these magnetometers will demonstrate at least femto-Tesla per root Hertz sensitivity, and could replace SQUID magnetometers. This project aims to develop its theoretical concept into a platform for advanced sensing with applications in magneto-encephalography, nerve sensing, MRI imaging, mining and aircraft guidance systems.Read moreRead less
Unconditional photonic entanglement verification and quantum metrology using fast, ultra-high-efficiency photon detectors. Scientists can currently only give in-principle demonstrations of the powerful advantages offered by the quantum physics of photons – particles of light. A true quantum technology revolution, that genuinely exploits photons’ exotic nature, requires methods and apparatus that work unconditionally. The main barrier is the extreme fragility of quantum properties due to unavoida ....Unconditional photonic entanglement verification and quantum metrology using fast, ultra-high-efficiency photon detectors. Scientists can currently only give in-principle demonstrations of the powerful advantages offered by the quantum physics of photons – particles of light. A true quantum technology revolution, that genuinely exploits photons’ exotic nature, requires methods and apparatus that work unconditionally. The main barrier is the extreme fragility of quantum properties due to unavoidable losses. This project will overcome this barrier by developing innovative loss-tolerant protocols and devices that unconditionally show and exploit quantum effects, both for long-distance applications and ultra-precise measurement technologies. This collaboration will bring the world’s best photon detectors to Australia, as a key resource for this work and for future research.Read moreRead less
Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology th ....Diamond lasers for precision applications. Diamond lasers for precision applications. The project aims to create single mode lasers of ultrahigh spectral brightness. Single-mode lasers could improve many areas of science and technology, but existing technologies do not meet all performance requirements. This project will harness the intrinsic properties of diamond Raman lasers to increase the wavelength reach, power and stability of single mode lasers. The expected outcome is laser technology that satisfies the needs of emerging markets, for example in gas sensing and atom cooling.Read moreRead less
Building Schrodinger's cat: large-scale entanglement of trapped ions. Where does the microscopic quantum world leave off and the normal world begin? The project will expand the boundaries of the quantum realm by building the largest quantum objects ever assembled and put them to work in computing and cryptography. These quantum devices will help Australia lead the race for future information technologies.
Australian Laureate Fellowships - Grant ID: FL100100099
Funder
Australian Research Council
Funding Amount
$2,340,409.00
Summary
An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gi ....An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gigabytes. The ground-breaking Petabyte data storage technology we will research will result in the storage capacity of 10,000 DVDs in one disc and thus underpin every sector of our modern life such as remote education, portable banking, global e-security and telemedicine as well as lead to enormous economic benefits in Australia.Read moreRead less
A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficie ....A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficiency, and significantly reducing the cost of high-energy ultrafast lasers. The project aims to provide benefits in ultrafast science, industrial materials processing, laser surgery, and molecular spectroscopy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL150100019
Funder
Australian Research Council
Funding Amount
$3,041,282.00
Summary
Precision laser levitation for quantum metrology and gravitational sensing. Precision laser levitation for quantum metrology and gravitational sensing: This fellowship project aims to levitate macroscopic objects using only laser beams, to provide a new tool to test physics theories. Strong laser beams can exert sufficient force to counteract gravity and make an object levitate. In contrast to other forms of levitation, laser levitation is scatter-free and can preserve system coherence. It has s ....Precision laser levitation for quantum metrology and gravitational sensing. Precision laser levitation for quantum metrology and gravitational sensing: This fellowship project aims to levitate macroscopic objects using only laser beams, to provide a new tool to test physics theories. Strong laser beams can exert sufficient force to counteract gravity and make an object levitate. In contrast to other forms of levitation, laser levitation is scatter-free and can preserve system coherence. It has superior optical and mechanical quality factors and complete information of the system dynamics is retained. This allows laser levitation to be turned into a highly controllable and ultra-sensitive device capable of detecting minute environmental changes. This research aims to probe the relationship between quantum and gravitational physics and develop laser levitation into a precision instrument for the sensing of gravity. Laser levitation has the potential to be developed into technology for mineral exploration and environmental sensing.Read moreRead less
Coherent Laser Levitation for Precision Sensing and Enabling Science. When light collides with matter, it may exert a force called radiation pressure. This project aims to use radiation pressure to levitate a small mirror. Using a tripod of laser beams, it is possible to levitate and trap the mirror in a stable position. Radiation pressure has been used before to levitate, but previous work has always involved scattering light from the levitating object. This project proposes the use of a high q ....Coherent Laser Levitation for Precision Sensing and Enabling Science. When light collides with matter, it may exert a force called radiation pressure. This project aims to use radiation pressure to levitate a small mirror. Using a tripod of laser beams, it is possible to levitate and trap the mirror in a stable position. Radiation pressure has been used before to levitate, but previous work has always involved scattering light from the levitating object. This project proposes the use of a high quality mirror, allowing the collection of the reflected light and the accurate measurement and control of the position of the mirror as it floats on the laser beams. Using the unique properties of the floating mirror, it will be possible to search for signatures of quantum gravity and develop tools for ultra-precision metrology.Read moreRead less
Targeted light - optical mode control at the nanoscale. Nanophotonics provides a path for controlling the interaction of light and matter at the nanoscale. Using spatially tailored laser beams to address nano-particles, this project aims to create new approaches for specifically targeting light with nano-scale precision, which has valuable potential applications in biosensing and communications.
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