Quantum spatial modes and their use in imaging, measurement, and communication. Quantum optics has the potential to provide highly accurate physical measurements, and to improve the speed and security of communication. The spatial modes of a light field provide a new and interesting basis for these investigations.
This fellowship proposes to generate spatially correlated quantum light beams, applying them to spatial positioning applications, such as atomic force microscopy, and to quantum ....Quantum spatial modes and their use in imaging, measurement, and communication. Quantum optics has the potential to provide highly accurate physical measurements, and to improve the speed and security of communication. The spatial modes of a light field provide a new and interesting basis for these investigations.
This fellowship proposes to generate spatially correlated quantum light beams, applying them to spatial positioning applications, such as atomic force microscopy, and to quantum communication protocols. I will experimentally develop general techniques to losslessly combine multiple quantum spatial modes, and demonstrate multi-mode quantum correlations in a light beam. I will investigate the potential of this light to cryptography, densecoding, and atomic force microscopy.
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Quantum Photonics and Imaging. Photonics is an expanding industry and its technology to date is essentially all classical, it uses light as a wave. In Quantum Photonics we want to carry out fundamental research that makes full use of the quantum properties of photons. We want to demonstrate novel and better ways to create, transfer, store and manipulate information both in space and time. This will lead to new applications such as quantum-cryptography, optical teleportation, and quantum-imagin ....Quantum Photonics and Imaging. Photonics is an expanding industry and its technology to date is essentially all classical, it uses light as a wave. In Quantum Photonics we want to carry out fundamental research that makes full use of the quantum properties of photons. We want to demonstrate novel and better ways to create, transfer, store and manipulate information both in space and time. This will lead to new applications such as quantum-cryptography, optical teleportation, and quantum-imaging, initially with a few, later with many pixel. All these are particularly suitable for our proven technology of nonclassical continuous laser beams.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
Optical technology for quantum science. This project aims to develop and commercialise optical cavity and frequency stabilisation technology to generate laser light at new and precise wavelengths. Australia plays a leading role internationally in quantum science, a burgeoning area of research where fundamental quantum mechanical principles underpin exciting new technological applications, such as ion-based quantum computing, ultracold atom sensing for geo-exploration and defence, and nanoscale i ....Optical technology for quantum science. This project aims to develop and commercialise optical cavity and frequency stabilisation technology to generate laser light at new and precise wavelengths. Australia plays a leading role internationally in quantum science, a burgeoning area of research where fundamental quantum mechanical principles underpin exciting new technological applications, such as ion-based quantum computing, ultracold atom sensing for geo-exploration and defence, and nanoscale imaging inside living human cells. This project aims to continue and develop this role.Read moreRead less
Advanced Quantum Sensors for Next-Generation Sensing Applications. The aim of this theoretical physics project is to develop ultra-precise sensing capabilities for two main applications: ultrastable inertial sensors for improved navigation and gravimetry, and to search for signatures of quantum gravity. This project expects to improve the performance of quantum sensors via the use of machine optimisation, and may lead to much-needed experimental data to help guide one of the most challenging pro ....Advanced Quantum Sensors for Next-Generation Sensing Applications. The aim of this theoretical physics project is to develop ultra-precise sensing capabilities for two main applications: ultrastable inertial sensors for improved navigation and gravimetry, and to search for signatures of quantum gravity. This project expects to improve the performance of quantum sensors via the use of machine optimisation, and may lead to much-needed experimental data to help guide one of the most challenging problems in theoretical physics: the quantisation of gravity. The expected outcomes of this project are enhanced quantum sensor design, leading to improved inertial sensing technology. This should provide benefits such as improved capabilities for minerals exploration and monitoring the movement of ground water.Read moreRead less
Quantum optical methods for entangled devices. This project aims to develop experimental quantum optics methods and techniques for enhancing the performance of sensitive devices. Entangled photons will be used to probe separate devices, yielding an improved detection of correlated signals. This new technique will benefit laboratory searches for new fundamental physics effects such as space-time fluctuations due to quantum gravity and exotic dark matter candidates. The project is expected to tr ....Quantum optical methods for entangled devices. This project aims to develop experimental quantum optics methods and techniques for enhancing the performance of sensitive devices. Entangled photons will be used to probe separate devices, yielding an improved detection of correlated signals. This new technique will benefit laboratory searches for new fundamental physics effects such as space-time fluctuations due to quantum gravity and exotic dark matter candidates. The project is expected to train scientists and students in advanced quantum methods, promoting and securing Australia's position as a leader in the development of quantum technologies. Read moreRead less
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.
The New Atom Laser: Theory of Quantum Atom Optical Sources. The atom laser is a new device which produces a coherent source of ultracold atoms. A practical atom laser will be a revolutionary source for atom optics. This project will develop a comprehensive and practical quantum theory of a new generation of atom lasers which can produce a continuous beam. This will require a different and more complicated theoretical approach to that which worked for optical lasers, but the result will be a d ....The New Atom Laser: Theory of Quantum Atom Optical Sources. The atom laser is a new device which produces a coherent source of ultracold atoms. A practical atom laser will be a revolutionary source for atom optics. This project will develop a comprehensive and practical quantum theory of a new generation of atom lasers which can produce a continuous beam. This will require a different and more complicated theoretical approach to that which worked for optical lasers, but the result will be a device with a spectral flux which is orders of magnitude better than the current state of the art.Read moreRead less
Storage of non-classical light in a solid. A new scheme for storing and recalling coherent light pulses based on 'slow light' has been demonstrated. The aim of this project is to show how this can best be achieved in a solid to enable practical applications. A range of materials will be investigated. The novel feature of the storage is the maintenace of the coherence information and a noise analysis will be made to determine whether it is experimentally possible to store non-classical light.
Observing Einstein-Podolsky-Rosen entanglement with ultracold atomic gases. As a fundamental test of quantum mechanics, the project will demonstrate for the first time the famous Einstein-Podolsky-Rosen paradox in the regime of a macroscopic number of entangled massive particles. As well as enabling the design of new gravitational sensors, the outcomes will give insights into the unification of quantum theory with gravity.