Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this pro ....Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this project include a proof of concept RF sensor that has multi-Gigahertz real-rime instantaneous bandwidth with high-resolution that can be miniaturized on to a chip. This compact RF sensor, will play a vital role for situational awareness in space, defence and communications applications. Read moreRead less
Next generation lasers for short-reach optical fibre communication. This project aims to develop next-generation laser systems for multimode fibre-optic communication systems, by leveraging recently developed techniques for measuring and controlling the spatial properties of light. These techniques will provide new insights into the physics of the lasers themselves, as well as overcoming fundamental limitations which have traditionally hindered their operation at high speed. The expected outcome ....Next generation lasers for short-reach optical fibre communication. This project aims to develop next-generation laser systems for multimode fibre-optic communication systems, by leveraging recently developed techniques for measuring and controlling the spatial properties of light. These techniques will provide new insights into the physics of the lasers themselves, as well as overcoming fundamental limitations which have traditionally hindered their operation at high speed. The expected outcome of this project is the inclusion of these techniques in the development and operation of future generations of fibre communication systems. Creating new classes of laser systems, which can scale to large bit rates, will enable the growth in this area to be sustained into the future.Read moreRead less
Levitated Quantum Optomechanics with Trapped, Rotating Microparticles. This project will develop techniques for trapping, rotating and cooling microscopic particles in vacuum for exquisitely accurate studies of sensors and of fundamental physics at the classical-quantum interface - namely quantum vacuum friction. It will result in the establishment of an internationally recognised activity in rotational levitated optomechanics and expand Australia's presence in the field of quantum photonics. It ....Levitated Quantum Optomechanics with Trapped, Rotating Microparticles. This project will develop techniques for trapping, rotating and cooling microscopic particles in vacuum for exquisitely accurate studies of sensors and of fundamental physics at the classical-quantum interface - namely quantum vacuum friction. It will result in the establishment of an internationally recognised activity in rotational levitated optomechanics and expand Australia's presence in the field of quantum photonics. It has the potential for commercial benefit in areas including photonics, sensors and advanced manufacturingRead moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100934
Funder
Australian Research Council
Funding Amount
$439,082.00
Summary
Taming the light: full control in polarisation, space, and time. This project aims to develop two prototype optical beam shaping systems, culminating in the demonstration of new high-power optical fibre amplifiers. This novel ability to control all the properties of light enables the generation of optical beams that were only theoretical ideas but never previously implemented experimentally. This advanced technology can potentially open new ways in which objects can be probed using light. Expect ....Taming the light: full control in polarisation, space, and time. This project aims to develop two prototype optical beam shaping systems, culminating in the demonstration of new high-power optical fibre amplifiers. This novel ability to control all the properties of light enables the generation of optical beams that were only theoretical ideas but never previously implemented experimentally. This advanced technology can potentially open new ways in which objects can be probed using light. Expected outcomes include the creation of an optical platform that the optical community at large may utilise for their specific applications. Besides the intellectual property benefits of such optical devices directly, this project should bridge the gap between the developed knowledge and commercial opportunities.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100099
Funder
Australian Research Council
Funding Amount
$3,401,828.00
Summary
The Intelligent Microscope - novel optical imaging at depth. While optical methods for imaging are used extensively, achieving wide-field imaging through scattering media with high resolution and depth is a major challenge, due mainly to the limited penetration depth of light. This proposal aims to transform wide-field optical imaging through a new ‘intelligent’ microscopy able to capture 3D volumetric images. Innovations in shaping light in both space and time will be combined in a holistic wa ....The Intelligent Microscope - novel optical imaging at depth. While optical methods for imaging are used extensively, achieving wide-field imaging through scattering media with high resolution and depth is a major challenge, due mainly to the limited penetration depth of light. This proposal aims to transform wide-field optical imaging through a new ‘intelligent’ microscopy able to capture 3D volumetric images. Innovations in shaping light in both space and time will be combined in a holistic way with computational analysis to extract images from deep within the sample at extraordinary levels of detail. Major benefits of the research range from next-generation tools for enhanced discovery of biological and physical materials, to new Australian start-ups for new imaging and microscopy devices.Read moreRead less
Next generation photonic waveguide sensors enabled by machine learning. This project aims to establish the next frontier in photonic waveguide sensing, by using machine learning to shift the complexity out of conventional photonic-waveguide/optical-fibre sensors and into smart detection algorithms. The complexity and instability of multimode photonic waveguides, traditionally a hinderance to sensing, will be advantageously employed to train deep learning models for sensing. Expected outcomes inc ....Next generation photonic waveguide sensors enabled by machine learning. This project aims to establish the next frontier in photonic waveguide sensing, by using machine learning to shift the complexity out of conventional photonic-waveguide/optical-fibre sensors and into smart detection algorithms. The complexity and instability of multimode photonic waveguides, traditionally a hinderance to sensing, will be advantageously employed to train deep learning models for sensing. Expected outcomes include the creation of intelligent photonic sensors that can, in principle, measure any environmental parameter using any optical waveguide material. It will create new critically needed measurement capabilities for challenging harsh environments, such as extreme temperature and in-vivo biochemical sensing.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
Discovery Early Career Researcher Award - Grant ID: DE220100509
Funder
Australian Research Council
Funding Amount
$436,482.00
Summary
Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expe ....Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expected benefit is to generate high-energy pulses from a battery powered micro-chip that could enhance spectroscopy sensing devices for real-world applications, outside laboratories. This project will strengthen Australian capabilities and expertise in cutting-edge nanotechnology and photonics.Read moreRead less
High-brightness wavelength tuneable lasers for quantum science. This project aims to establish the capability to manufacture application-specific semiconductor lasers. The project will use existing facilities in Australia to enhance our world-leading quantum science research, and establish a viable export-dominated high-tech manufacturing business. Semiconductor lasers are a critical enabling technology for many scientific applications, particularly for quantum science including quantum computin ....High-brightness wavelength tuneable lasers for quantum science. This project aims to establish the capability to manufacture application-specific semiconductor lasers. The project will use existing facilities in Australia to enhance our world-leading quantum science research, and establish a viable export-dominated high-tech manufacturing business. Semiconductor lasers are a critical enabling technology for many scientific applications, particularly for quantum science including quantum computing and quantum sensing. This project is expected to enable the establishment of a high-tech manufacturing capability to support Australia's leading role in quantum science, and expand our scientific instrumentation exports to new and rapidly developing applications such as magnetic sensing and imaging at nanoscale, quantum communication and computation.Read moreRead less
Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ul ....Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ultra-compact, high-performance optical isolators and circulators that shield sensitive optical components, and a suite of theoretical tools for describing propagation and noise in these devices. These new high performance photonic circuits should benefit telecommunications, radar, defence, and sensing applications. Read moreRead less