Relationship of retinal directionality to human retinal anatomy variations. This project aims to improve measurement of retinal directionality, which is the reduction in brightness when a light beam’s entry into the human eye is shifted from the centre to the edge of the pupil. This influences retinal image quality and can be used to measure changes in shape of the peripheral eye. This project will apply advanced technologies in holography, and heads-up displays to explore how retinal directiona ....Relationship of retinal directionality to human retinal anatomy variations. This project aims to improve measurement of retinal directionality, which is the reduction in brightness when a light beam’s entry into the human eye is shifted from the centre to the edge of the pupil. This influences retinal image quality and can be used to measure changes in shape of the peripheral eye. This project will apply advanced technologies in holography, and heads-up displays to explore how retinal directionality changes during accommodation (focusing). The expected outcome is improved understanding of retinal stretching changes during focusing. The benefit is that the project will lead to advancements in retinal imaging.Read moreRead less
Planet Formation at Solar System Scales with the James Webb Space Telescope. Planetary systems like our own form within vast disks of primordial gas and dust around newborn stars. This project will observe such disks spanning a range of ages with the James Webb Space Telescope to reveal the detailed in-situ physics of planet-forming disks themselves. We will deliver the sharpest-ever infrared images in astronomy, exploiting the only Australian-designed instrument on the spacecraft: the Aperture ....Planet Formation at Solar System Scales with the James Webb Space Telescope. Planetary systems like our own form within vast disks of primordial gas and dust around newborn stars. This project will observe such disks spanning a range of ages with the James Webb Space Telescope to reveal the detailed in-situ physics of planet-forming disks themselves. We will deliver the sharpest-ever infrared images in astronomy, exploiting the only Australian-designed instrument on the spacecraft: the Aperture Masking Interferometer. This yields new physics for actively growing protoplanets, carved rings and gaps in disks, and gravitationally sculpted patterns of leftover cometary debris. Confronting state-of-the-art models with these data will immediately yield profound insights into planetary system formation, including our own.Read moreRead less
Engineering the Next Generation of Broadband Terahertz Technologies. This project proposes a new broadband, high-power, laser technology for THz sensing. This semiconductor laser based THz technology is crucial for a wide range of applications requiring the acquisition of THz spectral signatures of materials and high-frame rate hyper-spectral THz imaging. We propose two pathways to engineer this novel THz technology: using a tuneable, coupled-cavity quantum cascade semiconductor laser and by c ....Engineering the Next Generation of Broadband Terahertz Technologies. This project proposes a new broadband, high-power, laser technology for THz sensing. This semiconductor laser based THz technology is crucial for a wide range of applications requiring the acquisition of THz spectral signatures of materials and high-frame rate hyper-spectral THz imaging. We propose two pathways to engineer this novel THz technology: using a tuneable, coupled-cavity quantum cascade semiconductor laser and by creating the broad emission spectra through active mode locking in a THz semiconductor laser. The THz laser coupled with the self-detection technique is the key to realising this, and will be explored both in model and experiment.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.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
Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability ....Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability and band gap tunability across the required range, enabled by quantum confinement. The outcome is the development of integrated self-powered IoT devices potentially impacting Advanced Manufacturing growth in Energy, Cyber Security, Food and Agribusiness, as all of these will ultimately rely on networked smart devices.Read 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
Novel devices for spatial light transformation. The aim of this project is to develop new optical instrumentation for spatially transforming light. This research expects to find solutions to problems that have thus far been out of reach by replacing what would traditionally be a human optical systems designer with computer algorithms. The expected outcomes include the development of three new devices as well as a set of design, fabrication and characterisation procedures that offer higher perfor ....Novel devices for spatial light transformation. The aim of this project is to develop new optical instrumentation for spatially transforming light. This research expects to find solutions to problems that have thus far been out of reach by replacing what would traditionally be a human optical systems designer with computer algorithms. The expected outcomes include the development of three new devices as well as a set of design, fabrication and characterisation procedures that offer higher performance, increased robustness and scalability. This should improve accessibility of this technology and provide benefits to a wide range of applications, including astronomical and biomedical imaging, telecommunications, as well as quantum and classical optical signal processing.Read moreRead less
Time reversed optics. The development of technology to precisely control how light travels through space and time yields the ability to deliver light through objects in ways which would not traditionally be possible and hence opens new applications. This project aims to develop new programmable optical systems for transforming the spatial and temporal properties of light, leveraging recent advances in optical beam shaping. Expected outcomes of this project include the construction and testing of ....Time reversed optics. The development of technology to precisely control how light travels through space and time yields the ability to deliver light through objects in ways which would not traditionally be possible and hence opens new applications. This project aims to develop new programmable optical systems for transforming the spatial and temporal properties of light, leveraging recent advances in optical beam shaping. Expected outcomes of this project include the construction and testing of two new types of optical systems. This should provide significant benefits in the areas of biomedical imaging, telecommunications, advanced manufacturing and both classical and quantum optical information processing.Read moreRead less