Discovery Early Career Researcher Award - Grant ID: DE200101041
Funder
Australian Research Council
Funding Amount
$423,573.00
Summary
On-Chip Terahertz Nanophotonics for Single Molecule Spectroscopy. This project aims to address fundamental limitations of in-vivo terahertz spectroscopy by developing modular, low-cost, efficient chip-based devices that concentrate and generate intense terahertz fields in nanometer volumes. This project expects to develop new knowledge in the areas of terahertz physics, nonlinear optics and biospectroscopy using several innovative terahertz nano-focusing techniques. Expected outcomes of this pro ....On-Chip Terahertz Nanophotonics for Single Molecule Spectroscopy. This project aims to address fundamental limitations of in-vivo terahertz spectroscopy by developing modular, low-cost, efficient chip-based devices that concentrate and generate intense terahertz fields in nanometer volumes. This project expects to develop new knowledge in the areas of terahertz physics, nonlinear optics and biospectroscopy using several innovative terahertz nano-focusing techniques. Expected outcomes of this project include providing improved techniques to interface terahertz fields to photonic nanostructures and performing in-vivo terahertz spectroscopy of single molecules. This should provide significant benefits in biochemistry and drug research, as well as telecommunications.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
Synthetic multi-dimensional integrated photonics. This project aims to develop and realise experimentally integrated circuits where light propagation mimics dynamics in arbitrarily complex imaginary photonic lattices. The project puts forward a universal and mass-fabrication compatible design concept of planar optical structures featuring unconventional synthetic multi-dimensional properties, which can also be reconfigured in real time. This underpins expected outcomes in optical detection with ....Synthetic multi-dimensional integrated photonics. This project aims to develop and realise experimentally integrated circuits where light propagation mimics dynamics in arbitrarily complex imaginary photonic lattices. The project puts forward a universal and mass-fabrication compatible design concept of planar optical structures featuring unconventional synthetic multi-dimensional properties, which can also be reconfigured in real time. This underpins expected outcomes in optical detection with fundamentally enhanced sensitivity and optical signal switching with ultra-low threshold. The benefits of such breakthrough improvements can have broad applications spanning from future optical communication networks to optical sensors for monitoring and health applications.Read moreRead less
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
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.
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
Optically-activatable nanolithography for ultralow energy long data storage. This project aims to investigate greenphotonic long data storage. Optically-activated nanolithography that adopts earth abundant lanthanide-doped nanoparticles and vectorial holography could enable the development of ultra-long lifetime, ultra-low energy consumption, and ultra-fast access speed technology platforms for exabyte big data centres. The research discoveries from this project will enable the greenphotonic lon ....Optically-activatable nanolithography for ultralow energy long data storage. This project aims to investigate greenphotonic long data storage. Optically-activated nanolithography that adopts earth abundant lanthanide-doped nanoparticles and vectorial holography could enable the development of ultra-long lifetime, ultra-low energy consumption, and ultra-fast access speed technology platforms for exabyte big data centres. The research discoveries from this project will enable the greenphotonic long data storage technology, reducing energy consumption. Such a breakthrough would provide a key platform for the emerging industry revolution 4.0 and build Australia’s international leadership in green and smart digital economies in the big data era.Read moreRead less
Tuning the multiplexing of optical angular momentum with graphene photonics. This project aims to develop a conceptually new graphene nano-device that allows for tuning the multiplexing of optical angular momentum from the near-infrared to mid-infrared wavelength regions. The innovation of this project is nano-engineering of the cutting-edge graphene-on-silicon technology in designing the world-first tunable optical-angular-momentum multiplexer for on-chip integration. This project will result i ....Tuning the multiplexing of optical angular momentum with graphene photonics. This project aims to develop a conceptually new graphene nano-device that allows for tuning the multiplexing of optical angular momentum from the near-infrared to mid-infrared wavelength regions. The innovation of this project is nano-engineering of the cutting-edge graphene-on-silicon technology in designing the world-first tunable optical-angular-momentum multiplexer for on-chip integration. This project will result in a new horizon of ultra-high-capacity chip-scale devices which can enable the new applications including wireless optical communications and thus accelerate the realisation of the emerging LiFi-based big data technology platform.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL120100029
Funder
Australian Research Council
Funding Amount
$2,913,510.00
Summary
Nonlinear optical phononics: harnessing sound and light in nonlinear nanoscale circuits. This project will open a new field of physics by building the first integration platform in which light and sound interact in nonlinear nanoscale circuits. This interaction will be harnessed for new signal processing applications, leading to dramatic improvements in microwave technologies for radar, communications and sensing at the nanoscale.
Deep-ultraviolet light source by frequency doubling of blue or green light for disinfection. Current ultraviolet light sources are inefficient and often bulky. By an alternative approach, in which the wavelength of blue or green light is halved, this project will design and build compact, efficient sources of ultraviolet light, which can be used for disinfection and sterilization. Such devices can be fabricated by Australian industry in Australia.