The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
Better vibrations: controlling light with sound in semiconductor chips. Combining new concepts in the theory of nonlinear optics with advanced experiments, this project aims to develop smart waveguides that bind sound and light tightly together. Laser light and sound waves seem worlds apart, but in the right conditions we can make them interact: sound can change the colour of light. Harnessing this control of light in tiny waveguides on semiconductor chips would enable the development of unique ....Better vibrations: controlling light with sound in semiconductor chips. Combining new concepts in the theory of nonlinear optics with advanced experiments, this project aims to develop smart waveguides that bind sound and light tightly together. Laser light and sound waves seem worlds apart, but in the right conditions we can make them interact: sound can change the colour of light. Harnessing this control of light in tiny waveguides on semiconductor chips would enable the development of unique and useful optical devices, but trapping sound in chips is tremendously difficult. By exploiting untapped material properties, the project seeks to break limits on the freedom and strength of interactions between light and sound. Project outcomes may establish a new class of optical chips for optical sensing and analysis in fields from security to communications to the biosciences.Read moreRead less
Putting stimulated Brillouin scattering to work: tailored optical-phononic interactions for on-chip signal processing. Light interacts with sound via a phenomenon called Brillouin scattering, an effect which is of major importance in modern nonlinear optics but is very difficult to control. Our pioneering project will open the door to low power optical devices and other diverse innovations that will support Australia's needs in defence and communications.
Discovery Early Career Researcher Award - Grant ID: DE160100714
Funder
Australian Research Council
Funding Amount
$354,000.00
Summary
Shaping light – new frontiers in big fast data. This project aims to address the need for new technologies to tackle the bandwidth overload. Because of the basic human desire to communicate and interact, our society has an exponentially growing Internet data demand. The data capacity crunch is imminent. Data demand is rapidly approaching the nonlinear Shannon limit which governs the maximum data capacity of single-mode optical fibres. Bandwidth limitations may have severe implications for societ ....Shaping light – new frontiers in big fast data. This project aims to address the need for new technologies to tackle the bandwidth overload. Because of the basic human desire to communicate and interact, our society has an exponentially growing Internet data demand. The data capacity crunch is imminent. Data demand is rapidly approaching the nonlinear Shannon limit which governs the maximum data capacity of single-mode optical fibres. Bandwidth limitations may have severe implications for society and economy. This project aims to develop chip-scale mode-multiplexers based on innovative 3D integrated photonics and combine them with optical gain to shape light for space-division multiplexed optical communication networks. This is designed to break through the data capacity limit that currently prevents growth in Internet data rates.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100509
Funder
Australian Research Council
Funding Amount
$436,482.00
Summary
Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expe ....Going Fourth: ruling light with pure-quartic solitons. This project aims to develop a novel integrated high-energy light source through the combination of nanoscience and optics. The core research of this project addresses the energy limitation inherent to the current technology which has hindered its use in real applications. Expected outcomes include new knowledge, with publication in world-class scientific journals, and disruptive technological capabilities in miniaturized photonics. The expected benefit is to generate high-energy pulses from a battery powered micro-chip that could enhance spectroscopy sensing devices for real-world applications, outside laboratories. This project will strengthen Australian capabilities and expertise in cutting-edge nanotechnology and photonics.Read moreRead less
A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumptio ....A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumption reduced by half, as compared to current LC-based displays (e.g. LCD and LED). This novel technology will revolutionise the dimension and performance of displays and secure Australia's position in the billion dollar market of flat displays.
Read moreRead less
Unlocking the ultraviolet. This project will develop a new class of ultra-short-pulse and broadly tunable laser with performance in the ultraviolet that is unobtainable from current infrared-based laser technologies. Our invention will unlock the elusive ultraviolet part of the spectrum to allow new discoveries in fundamental science and to drive twenty-first-century technologies.
Discovery Early Career Researcher Award - Grant ID: DE120101721
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Probing the excited states of organic semiconductor systems with photoinduced absorption spectroscopy. Plastic semiconductors have the potential to revolutionise consumer electronics by enabling cheap, flexible and low power devices. The success of these devices depends on our understanding of the optical and electronic properties of the materials, which this project aims to address through the use of photoinduced absorption spectroscopy.
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.
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
Optics at the nanoscale: physics, devices and applications. This project aims to harness light-matter interactions at the nanoscale for the development of new photonic devices for imaging and optical manipulation. Novel photodetectors that operate from visible to infrared wavelengths will be developed, enabled by sub-wavelength nanostructures. These could form the basis for digital cameras with multispectral imaging capabilities, for example, for biomedical imaging, food quality control and remo ....Optics at the nanoscale: physics, devices and applications. This project aims to harness light-matter interactions at the nanoscale for the development of new photonic devices for imaging and optical manipulation. Novel photodetectors that operate from visible to infrared wavelengths will be developed, enabled by sub-wavelength nanostructures. These could form the basis for digital cameras with multispectral imaging capabilities, for example, for biomedical imaging, food quality control and remote sensing. Nanostructures will be developed that concentrate light to nanoscale spots, enabling the trapping of single molecules and nanoparticles. This project aims to educate the next generation of Australian optical scientists and engineers, building the human infrastructure for future advances in this field.Read moreRead less