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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453320
Funder
Australian Research Council
Funding Amount
$347,886.00
Summary
Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable ....Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable of full spectrum imaging. This new spectroscopic infrastructure will enable the knowledge-based development of new materials by allowing complete characterisation of structure-composition-property relationships at the nanometre level.Read moreRead less
Nonlinear optics of soft matter. This project will develop new strategies for the use and control of soft-matter systems by exploiting nonlinear interactions with light, and therefore falls into the Designated Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries - Breakthrough Science. With soft matter research being increasingly important for applications within industry and medicine, the emergence of new technology for control of nanoparticles could pr ....Nonlinear optics of soft matter. This project will develop new strategies for the use and control of soft-matter systems by exploiting nonlinear interactions with light, and therefore falls into the Designated Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries - Breakthrough Science. With soft matter research being increasingly important for applications within industry and medicine, the emergence of new technology for control of nanoparticles could provide significant benefits for the scientific community as well as Australian companies.
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All-optical reconfigurable interconnects in nematic liquid crystals. This project aims to explore the unique features of nematic liquid crystals with giant non-local nonlinearity for shaping, routing, and guiding light for all-optical photonic devices, aiming to uncover and realise the potential of long range interaction between laser light and liquid crystals for all-optical computing.
Carrier dynamics in III-V semiconductor quantum dots and nanostructures. Quantum dots and related nanostructures are one of the most attractive topics in the recently years. This project will investigate the role of carrier dynamics in these nanostructures by using state-of-the-art ultrafast spectroscopy techniques. The wealth of information obtained from this study will not only enhance our knowledge base but also allow us to design high performance QD lasers and detectors and to demonstrate in ....Carrier dynamics in III-V semiconductor quantum dots and nanostructures. Quantum dots and related nanostructures are one of the most attractive topics in the recently years. This project will investigate the role of carrier dynamics in these nanostructures by using state-of-the-art ultrafast spectroscopy techniques. The wealth of information obtained from this study will not only enhance our knowledge base but also allow us to design high performance QD lasers and detectors and to demonstrate innovative optoelectronic devices for optical communication systems as well as quantum information processing. It will ensure that Australia is at the cutting edge of nanotechnology and optoelectronics research.Read moreRead less
Quantum technologies based on crystalline rare-earth ion doped optical waveguides and resonators. Quantum information processing is a powerful emerging technology that aims to fully exploit the properties of quantum mechanics to perform computations and securely transmit information. This project will develop an essential component for this technology that will enable for the first time the direct and reversible transfer of quantum information between solid-state quantum systems and light. Succ ....Quantum technologies based on crystalline rare-earth ion doped optical waveguides and resonators. Quantum information processing is a powerful emerging technology that aims to fully exploit the properties of quantum mechanics to perform computations and securely transmit information. This project will develop an essential component for this technology that will enable for the first time the direct and reversible transfer of quantum information between solid-state quantum systems and light. Successful completion of this project will provide a route to fully scalable quantum computing and long range quantum networks. This project will help secure Australia's leading role in this strategically important new generation technology.Read moreRead less
Early-Stage Medical Diagnostics by Plasmon-Mediated Gas Sensing. This project will investigate the use plasmonic absorption of light in metal nanostructures to activate the selective oxidation/reduction of a gas molecule on a semiconductor nanoparticle. This concept will be used with the aim of developing a sensing technique capable of measuring ultra-low concentrations (ppb) of breath markers for lung cancer detection. It is expected that porous sensing films of semiconductor and metal nanopart ....Early-Stage Medical Diagnostics by Plasmon-Mediated Gas Sensing. This project will investigate the use plasmonic absorption of light in metal nanostructures to activate the selective oxidation/reduction of a gas molecule on a semiconductor nanoparticle. This concept will be used with the aim of developing a sensing technique capable of measuring ultra-low concentrations (ppb) of breath markers for lung cancer detection. It is expected that porous sensing films of semiconductor and metal nanoparticles with well-defined light absorption properties will be fabricated. Superior selectivity will be achieved by matching the wavelength of the absorbed light with the required activation energy for oxidation/reduction. Successful outcomes will enable multi-analyte fingerprint identification by on-chip devices with applications ranging from portable medical diagnostics to national security.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL130100044
Funder
Australian Research Council
Funding Amount
$2,965,000.00
Summary
Controlling light to understand and drive nanoscale processes. This project aims to develop a suite of light-based sensing technologies capable of quantifying the dynamic environment within a living cell. These technologies will extend our capacity to harness light-matter interactions at the nanoscale, providing new insights in fields ranging from plant biology to medicine.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100067
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A femtosecond Mmd-IR optical parametric amplifier source for waveguide nonlinear optics. The mid-infrared is an immensely important region of the optical spectrum for sensing toxic or illicit molecules or pollutants using their spectral fingerprints. The equipment will facilitate the development of new techniques for sensing based on nonlinear processes in waveguides.
Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact w ....Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact with intense THz laser fields. Experimentally, we plan to use Beijing FELs in China to study optoelectronic properties in GaAs-and GaN based systems. Theoretically, we intend developing fundamental new approaches to theory of electron interactions with intense laser fields in semiconductors and relating theoretical results to experiments and experimental findings.Read moreRead less