Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668398
Funder
Australian Research Council
Funding Amount
$177,900.00
Summary
Advanced Microwave Facility for Quantum-Atom Optics. Atoms can be controlled using light in visible and infra-red regions, as well as electromagnetic waves of longer wavelength in the microwave (MW) and radiofrequency (RF) part of the spectrum. We presently use optical radiation to control atoms at the quantum level where they can behave like waves and can interact with light to store and manipulate information. The MW and RF facility will extend our abilities and enable more complete control of ....Advanced Microwave Facility for Quantum-Atom Optics. Atoms can be controlled using light in visible and infra-red regions, as well as electromagnetic waves of longer wavelength in the microwave (MW) and radiofrequency (RF) part of the spectrum. We presently use optical radiation to control atoms at the quantum level where they can behave like waves and can interact with light to store and manipulate information. The MW and RF facility will extend our abilities and enable more complete control of the atoms, which will help us develop the first generation quantum technology. This will enable the creation of quantum devices such as atom lasers, atom interferometers and quantum information networks for communication and ultra-sensitive measurement applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882580
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Laser facility for quantum optics, imaging, and fabrication. The laser facility will play a role in advancing high-profile leading-edge Australian research underpinning a diverse range of technologies, from quantum communications and quantum computing, to biomedical imaging, fibre sensing and nanofabrication.
Quantum and classical imaging with light and atoms. Powerful new methods will be developed to extract greater information from optical and quantum imaging systems. These methods will be applied to important problems in biomedical and industrial optical and x-ray imaging and to experiments which test the foundations of quantum physics. Our work will help maintain Australia's strong international profile in optics and in optical imaging, while providing a professional and broad training environm ....Quantum and classical imaging with light and atoms. Powerful new methods will be developed to extract greater information from optical and quantum imaging systems. These methods will be applied to important problems in biomedical and industrial optical and x-ray imaging and to experiments which test the foundations of quantum physics. Our work will help maintain Australia's strong international profile in optics and in optical imaging, while providing a professional and broad training environment for our best and brightest graduate students.Read moreRead less
Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniqu ....Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniques is critical to future opportunities of frontier discoveries of the biological, nano and atomic world. Its application includes structural biology, medical diagnosis, biomedicine, material sciences and many other fields.Read moreRead less
Microcharacterisation of rare-earth-doped optical fibres. Rare-earth-doped optical fibres continue to play a central role in optical telecommunication systems and are increasingly being used as elements in optical fibre sensing devices and as fibre lasers. The aim of this project is the application of new high spatial resolution techniques for determining the physical properties of such fibres. These methods will permit unprecedented knowledge of the precise distribution of rare-earth ions in th ....Microcharacterisation of rare-earth-doped optical fibres. Rare-earth-doped optical fibres continue to play a central role in optical telecommunication systems and are increasingly being used as elements in optical fibre sensing devices and as fibre lasers. The aim of this project is the application of new high spatial resolution techniques for determining the physical properties of such fibres. These methods will permit unprecedented knowledge of the precise distribution of rare-earth ions in the fibre and its relationship with the fibre's refractive index profile. This information is critical to understanding the performance of rare-earth-doped fibres in a variety of applications and the outcomes of this work will inform the design of fibres optimised for use in specific applications.Read moreRead less
Fabrication of complete photonic band gap structures by two-photon polymerization and subsequent infiltration with high refractive index materials. The ability to shrink photonic circuits by orders of magnitudes by the integration of photonic crystals offers many stimulating possibilities for novel device designs. A speculative view is that this miniaturisation can have a similar impact to that experienced in electronic components in the 1960s. However, the fabrication of 3D photonic crystals re ....Fabrication of complete photonic band gap structures by two-photon polymerization and subsequent infiltration with high refractive index materials. The ability to shrink photonic circuits by orders of magnitudes by the integration of photonic crystals offers many stimulating possibilities for novel device designs. A speculative view is that this miniaturisation can have a similar impact to that experienced in electronic components in the 1960s. However, the fabrication of 3D photonic crystals remains a major challenge and the development of new, flexible, and fast nano-fabrication techniques is vital. The realization of an innovative technique for the fabrication of 3D complete photonic band gap structures as it is suggested will make an essential contribution to the emerging field of all-optical tele- and data-communications and will deliver major economic benefit to Australia. Read moreRead less
Plasmonic nano-antennas for next-generation photon sources. Extending concepts from standard radio-frequency antenna technology down to the nanoscale will open up new applications in fields from biotechnology to telecommunications. This project will embed a light emitting particle in a nanostructured metallic device to produce an ultrabright, directional single-photon source.
Discovery Early Career Researcher Award - Grant ID: DE120101329
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ultra-stable photonic-chip pulse source. An ultra-low noise high repetition photonic-chip pulse source is proposed. This ultra-stable device offers orders-of-magnitude improvements over existing solutions and holds potential for strong improvements to analogue-to-digital converters. The laser will be a crucial component for photonic integrated circuits, enabling millimetre size processing.
Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multi ....Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multiple driving pulses with different carrier frequencies to control the spectral properties and time delay of the pulses. It will use the soft X-ray source to develop an ideal platform for studying multi-electronic and non-adiabatic processes, multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules. This is expected to advance materials science, paving the way to soft X-ray technologies.Read moreRead less
Quantum effects in photosynthesis: responsible for highly efficient energy transfer or trivial coincidence? Understanding the precise details of the highly efficient energy transfer processes in photosynthesis has the potential to impact the design of efficient solar energy solutions. This project will gain this understanding by exploring the nature of interactions between different components and the significance of quantum mechanics.