Discovery Early Career Researcher Award - Grant ID: DE190100430
Funder
Australian Research Council
Funding Amount
$404,000.00
Summary
Active topological photonics with all-dielectric nanostructures. This project aims to address the challenges of topological protection in active and tunable photonic elements utilised for compact optical transmitting devices by designing dielectric nanostructures. The rapidly growing demands of information processing have launched a race for compact optical devices transmitting signals without scattering losses. The recent emergence of topological phases of light provides unique opportunities to ....Active topological photonics with all-dielectric nanostructures. This project aims to address the challenges of topological protection in active and tunable photonic elements utilised for compact optical transmitting devices by designing dielectric nanostructures. The rapidly growing demands of information processing have launched a race for compact optical devices transmitting signals without scattering losses. The recent emergence of topological phases of light provides unique opportunities to create new photonic systems immune to scattering losses and disorder increasing the efficiency of light transmission in optical devices. The project expects to advance knowledge in fundamental nanoscale optics and benefit globally important photonic applications, ranging from high-speed data processing and communications to optical storage and low-power nanolasing. This project will provide benefits by uncovering disorder-immune technologies for emerging photonic industries in Australia.Read moreRead less
Meta-optics systems for driver-fatigue monitoring. The project aims to develop novel miniaturised optical systems for driver fatigue monitoring, which provide increased sensitivity, eliminate reflections from eyeglasses and enable accurate depth measurements of facial features. The unique performance of our optical systems is derived from the concept of optical nanostructured surfaces to allow for efficient control of light wavefront and polarisation. The project aims to apply this concept to de ....Meta-optics systems for driver-fatigue monitoring. The project aims to develop novel miniaturised optical systems for driver fatigue monitoring, which provide increased sensitivity, eliminate reflections from eyeglasses and enable accurate depth measurements of facial features. The unique performance of our optical systems is derived from the concept of optical nanostructured surfaces to allow for efficient control of light wavefront and polarisation. The project aims to apply this concept to develop six different optical elements with new functionalities and performance well beyond what is possible with conventional components. This development will enable the construction of high-performance driver monitoring systems, thus facilitating a safer driving experience for all.Read moreRead less
Functional metamaterials based on chiral structures. The project will develop a new class of metamaterials - artificial materials that twist light and synchronise multiple light sources. These structures will show intriguing physical properties with reduced absorption and external tunability, thus paving the way for novel optical technologies.
Insight from Darkness: Nanophotonics for real-time phase imaging. This project aims to develop ultrathin surfaces patterned on the nanoscale for extracting information from optical wavefields. These devices can be designed to provide real-time phase contrast imaging of transparent objects. This capability would open up the possibility of live-cell imaging with no expensive optical components and no, or minimal, computational post-processing. The planar configuration is designed to be compatible ....Insight from Darkness: Nanophotonics for real-time phase imaging. This project aims to develop ultrathin surfaces patterned on the nanoscale for extracting information from optical wavefields. These devices can be designed to provide real-time phase contrast imaging of transparent objects. This capability would open up the possibility of live-cell imaging with no expensive optical components and no, or minimal, computational post-processing. The planar configuration is designed to be compatible with next-generation lab-on-a-chip technologies and permit rapid throughput diagnostics with potential applications in biomedicine and materials science. Expected project outcomes may also underpin fundamental advances in understanding the interaction of light with nanostructures.Read moreRead less
ARC Centre of Excellence for Ultrahigh Bandwidth Devices for Optical Systems. The Centre will take the next big step in optical systems by transforming photonic integrated circuits into a technology that will have a profound effect on economies and lifestyles around the world. This will enable the Internet to transfer vast amounts of data with significantly improved energy efficiency; it will lead to secure transmission using quantum photonics-based devices, and to the detection of mid-infrared ....ARC Centre of Excellence for Ultrahigh Bandwidth Devices for Optical Systems. The Centre will take the next big step in optical systems by transforming photonic integrated circuits into a technology that will have a profound effect on economies and lifestyles around the world. This will enable the Internet to transfer vast amounts of data with significantly improved energy efficiency; it will lead to secure transmission using quantum photonics-based devices, and to the detection of mid-infrared signatures of light from distant stars and complex molecules of environmental or biochemical importance. We will achieve this by developing new materials with optical properties to control light and engineering them into miniature photonic processors.Read moreRead less
ARC Centre of Excellence for Transformative Meta-Optical Systems. The ARC Centre of Excellence for Transformative Meta-Optical Systems will develop the next-generation of miniaturised optical systems with functionalities beyond what is conceivable today. By harnessing the disruptive concept of meta-optics, the Centre will overcome complex challenges in light generation, manipulation and detection at the nanoscale. The Centre brings together a trans-disciplinary team of world-leaders in science, ....ARC Centre of Excellence for Transformative Meta-Optical Systems. The ARC Centre of Excellence for Transformative Meta-Optical Systems will develop the next-generation of miniaturised optical systems with functionalities beyond what is conceivable today. By harnessing the disruptive concept of meta-optics, the Centre will overcome complex challenges in light generation, manipulation and detection at the nanoscale. The Centre brings together a trans-disciplinary team of world-leaders in science, technology and engineering to deliver scientific innovations in optical systems for the Fourth Industrial Revolution. The research outcomes will underpin future technologies, including real-time holographic displays, artificial vision for autonomous systems to see the invisible, and ultra-fast light-based WiFi.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100250
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Opto-acoustic metasurfaces. This project aims to develop efficient nanoscale light and sound sources and merge them on an extra-thin surface. Interactions between light and sound waves at the macroscopic scale are used every day, such as in non-destructive testing and contact-less imaging. However, research into nanoscale light-sound interactions is new and has not realised its full potential. This project intends to develop ultra-compact sources of light and sound, tune them effectively, harnes ....Opto-acoustic metasurfaces. This project aims to develop efficient nanoscale light and sound sources and merge them on an extra-thin surface. Interactions between light and sound waves at the macroscopic scale are used every day, such as in non-destructive testing and contact-less imaging. However, research into nanoscale light-sound interactions is new and has not realised its full potential. This project intends to develop ultra-compact sources of light and sound, tune them effectively, harness them simultaneously, and convert one to another efficiently, all crucial for real-world applications. This research is expected to improve technologies that use light and sound, including microscopy and spectroscopy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100383
Funder
Australian Research Council
Funding Amount
$344,446.00
Summary
Plasmonic hot-electron technologies for nanoscale energy conversion. This project aims to improve the efficiency of plasmonically enhanced hot-electron photodiodes for solar fuel generation and targeted photo-detection. This project is expected to make advances towards the development of effective devices which will directly impact a range of applications of local and global importance including alternative energy production, and the next generation of imaging and sensing technologies for the bi ....Plasmonic hot-electron technologies for nanoscale energy conversion. This project aims to improve the efficiency of plasmonically enhanced hot-electron photodiodes for solar fuel generation and targeted photo-detection. This project is expected to make advances towards the development of effective devices which will directly impact a range of applications of local and global importance including alternative energy production, and the next generation of imaging and sensing technologies for the biomedical and health industries.Read moreRead less
Nonlinear topological photonics . The rapidly growing demands of information processing have launched a race for compact optical devices transmitting signals without losses. Topological phases of light provides unique opportunities to create new photonic systems with functionalities and efficiencies well beyond current capabilities. This project aims to develop new ways to generate and guide light at the nanoscale by merging fundamental concepts of nonlinear photonics and topological physics. Th ....Nonlinear topological photonics . The rapidly growing demands of information processing have launched a race for compact optical devices transmitting signals without losses. Topological phases of light provides unique opportunities to create new photonic systems with functionalities and efficiencies well beyond current capabilities. This project aims to develop new ways to generate and guide light at the nanoscale by merging fundamental concepts of nonlinear photonics and topological physics. The outcomes of this project will result in experimental demonstration of the world-first, highly efficient, compact, and lossless nonlinear photonic devices for advanced optical technologies.Read moreRead less
ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to unde ....ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to understand how single cells react to and communicate with their surroundings. This science will underpin a new generation of devices capable of probing the response of cells within individuals to environmental conditions or treatment, creating innovative and powerful new sensing platforms.Read moreRead less