Smart Bungs for wine monitoring. 'Smart Bung' sensors will use optical fibres to monitor wine production using only nano- to microlitre-scale volumes, significantly reducing wastage and improving quality. They will serve as 'early warning devices' and will ensure that Australia's wine industry maintains its outstanding international reputation for excellence and innovation.
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
Nanoparticle-enabled photorefractive digital holography: toward the next generation ultrafast and multi-colour three dimensional display technology. The cutting-edge knowledge in nanoparticle-enabled photorefractive polymers will provide an innovative material for green-photonics industry. The new generation ultrafast and multi-colour digital holographic three dimensional display technology will be potentially beneficial to entertainment sectors, remote education and medical diagnosis and photov ....Nanoparticle-enabled photorefractive digital holography: toward the next generation ultrafast and multi-colour three dimensional display technology. The cutting-edge knowledge in nanoparticle-enabled photorefractive polymers will provide an innovative material for green-photonics industry. The new generation ultrafast and multi-colour digital holographic three dimensional display technology will be potentially beneficial to entertainment sectors, remote education and medical diagnosis and photovoltaics.Read moreRead less
Optomechanical refrigeration of electronic circuits. The project aims to apply laser light to reduce the temperature of electronic circuits. This aims to greatly suppress electronic noise, and enable a new class of technologies for future telecommunication systems. By developing new techniques to confine light, electric fields and vibrations at sub-micron scale on a silicon chip, devices such as ultralow noise amplifiers, clocks and radio frequency receivers will be realised, along with ultra-ef ....Optomechanical refrigeration of electronic circuits. The project aims to apply laser light to reduce the temperature of electronic circuits. This aims to greatly suppress electronic noise, and enable a new class of technologies for future telecommunication systems. By developing new techniques to confine light, electric fields and vibrations at sub-micron scale on a silicon chip, devices such as ultralow noise amplifiers, clocks and radio frequency receivers will be realised, along with ultra-efficient optical modulators. In future, these technologies could reduce energy consumption and improve reliability in telecommunication networks. They could improve the range of satellite communication, robustness of GPS against cosmic radiation, and performance of surveillance systems such as radar and sonar.Read moreRead less
Ultraprecise sensing with microcavity optomechanics. New technologies will be developed to observe nanoscale motion with light confined on a silicon chip. Based on advances in integrated photonics and nanofabrication, these technologies will enable microscale magnetic field, mass, and gas sensing with precision surpassing today’s state-of-the-art. Important proof-of-principle applications will be realised, including ultrasensitive monitoring of greenhouse emissions, hydrogen absorption into fuel ....Ultraprecise sensing with microcavity optomechanics. New technologies will be developed to observe nanoscale motion with light confined on a silicon chip. Based on advances in integrated photonics and nanofabrication, these technologies will enable microscale magnetic field, mass, and gas sensing with precision surpassing today’s state-of-the-art. Important proof-of-principle applications will be realised, including ultrasensitive monitoring of greenhouse emissions, hydrogen absorption into fuel cell materials, space communication technologies, and magnetic resonance techniques for diagnosis of disease and airport security. The capacity to observe microscopic processes with record precision will further enable fundamental studies in areas such as condensed matter physics and photosynthesis.Read moreRead less
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
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.
Investigation into a graphene ultra-flat lens array for silicon solar cells breaking the Shockley-Queisser efficiency limit. Based on a recent discovery of the giant refractive index modulation associated with graphene oxide to graphene transition upon laser exposure and the breakthrough of graphene silicon solar cells. This project aims to investigate a new concept of an integratible, broadband, dispersionless, ultraflat lens array from nanostructured graphene oxide/graphene. This conceptually ....Investigation into a graphene ultra-flat lens array for silicon solar cells breaking the Shockley-Queisser efficiency limit. Based on a recent discovery of the giant refractive index modulation associated with graphene oxide to graphene transition upon laser exposure and the breakthrough of graphene silicon solar cells. This project aims to investigate a new concept of an integratible, broadband, dispersionless, ultraflat lens array from nanostructured graphene oxide/graphene. This conceptually new development of functional graphene oxide/graphene lens array in combination with a lumpy nanoparticle enabled back light trapping layer will allow for the non-reciprocal coupling of the broadband solar light into the photovoltaic devices with minimised entropy losses. Thus ultrahigh efficiency solar cells exceeding the conventional theoretical limit can be developed.Read moreRead less
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