A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a labora ....A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a laboratory prototype of this sensor that is expected to have superior sensitivity and operational capabilities. Thus it will noticeably contribute to practical law enforcement, air quality and environmental monitoring, counter-terrorism, air safety, border security and customs service. It will also lead to further development of nano-optics and nanotechnology in Australia. Read moreRead less
Optically induced spin polarisation: the role of electron-vibration interactions. A defect in diamond has applications as a microscopic probe of magnetic fields, as a fluorescence probe of biological systems and for quantum information processing. These capabilities are to be enhanced by a thorough investigation of the intrinsic properties of the defect centre.
Quantum noise limited molecular spectrometry. This project will develop a new technology for chemical analysis using lasers. The research will produce more accurate instruments for analysing samples containing carbon dioxide and water. This technology has a surprisingly wide array of applications. For example, sensitive analysis of carbon dioxide will help law enforcement agencies identify the location of illicit drug manufacturing, test for performance enhancing drug use by elite athletes, and ....Quantum noise limited molecular spectrometry. This project will develop a new technology for chemical analysis using lasers. The research will produce more accurate instruments for analysing samples containing carbon dioxide and water. This technology has a surprisingly wide array of applications. For example, sensitive analysis of carbon dioxide will help law enforcement agencies identify the location of illicit drug manufacturing, test for performance enhancing drug use by elite athletes, and monitor greenhouse gases. The instrument for analysing water will improve water resource management in Australia. This program will result in commercial instruments that are sensitive, portable and affordable.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
Functional nonlinear nanophotonics. This project will uncover novel ways of controlling ultra-short optical pulses through the special structuring of materials at the nanoscale. New functionalities based on enhanced nonlinear light-matter interactions will underpin advances in future optical communication networks and computing systems, laser radars and sensing applications.
Resonant nanophotonics: tailoring resonant interaction of light with nanoclusters. This project will unlock new ways of controlling resonant light-matter interaction in nanostructured materials for the next generation of integrated nanophotonic devices. The project outcomes will support Australia's leadership in the development of energy efficient components for advanced photonic networks and optical communications.
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
Flexible nonlinear photonics with nanowire slow-light waveguides. This project will develop new approaches based on nanotechnologies to create flexible photonic chips in which deformations can be used to manipulate optical pulses transmitting information at the speed of light. This will serve to advance the speed, performance and energy efficiency of future optical communication networks and computing systems.
Nonlinear nano-photonic structures for frequency conversion: from classical to quantum applications. New methods for changing the colour of light will be developed through the use of nano-scale optical circuits, enabling manipulation of short pulses and single quanta of light. This will advance the performance, energy efficiency and security of future optical communication networks and computing systems.
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