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Routing shapes of light for the next generation of fibre optic networks. In 2016, the United Nations declared access to the Internet as basic human right. Our communication networks are facing a capacity crunch, which will transform a basic human right for everyone into a privilege for a few. This project aims to avoid a capacity crunch by creating innovative solutions for the next generation of optical fibre communication networks. This project stands to generate new knowledge in photonics, opt ....Routing shapes of light for the next generation of fibre optic networks. In 2016, the United Nations declared access to the Internet as basic human right. Our communication networks are facing a capacity crunch, which will transform a basic human right for everyone into a privilege for a few. This project aims to avoid a capacity crunch by creating innovative solutions for the next generation of optical fibre communication networks. This project stands to generate new knowledge in photonics, optical communication and advanced manufacturing. The expected benefits are new academic collaborations, enhancing Australia’s international standing and economic benefit through commercialisation and training of students for the growing photonics industry in Australia.Read moreRead less
Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes inc ....Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes include understanding the interaction between THz signals and phase change materials, tuneable metamaterials, and devices that can steer and modulate THz signals with unprecedented agility and compactness, enabling future high-bandwidth Bluetooth-like data transfer.Read moreRead less
Nonlinear optical effects with low-power non-laser light. This project aims to allow the use of low-cost, low-intensity light sources, such as light-emitting diodes and discharge lamps, to generate nonlinear optical signals in photonic devices. Nonlinear optical effects are vital for telecommunication and signal processing technologies and are presently possible only when the light is produced by a high-power laser. The expected outcome of this project is a theoretical and experimental framework ....Nonlinear optical effects with low-power non-laser light. This project aims to allow the use of low-cost, low-intensity light sources, such as light-emitting diodes and discharge lamps, to generate nonlinear optical signals in photonic devices. Nonlinear optical effects are vital for telecommunication and signal processing technologies and are presently possible only when the light is produced by a high-power laser. The expected outcome of this project is a theoretical and experimental framework that would underpin the development of a new nonlinear photonic technology that does not require lasers, representing a paradigm shift in how photonic devices are designed. This should benefit sensing, telecommunications and defence by cheaper and more efficient transmission of information via media such as the National Broadband Network.Read moreRead less
Producing optimally short pulses at long wavelengths. This project aims to make the fluoride glass fibre platform the preferred material for generating ultrashort pulses at 2.8 nm and beyond. High power and efficiency from simple device architectures are essential for industry, medicine and defence. Modern sources of short pulses of light emitting mid-infrared wavelengths are complicated and inefficient. This project will improve fibre sources emitting short pulses and create the essential build ....Producing optimally short pulses at long wavelengths. This project aims to make the fluoride glass fibre platform the preferred material for generating ultrashort pulses at 2.8 nm and beyond. High power and efficiency from simple device architectures are essential for industry, medicine and defence. Modern sources of short pulses of light emitting mid-infrared wavelengths are complicated and inefficient. This project will improve fibre sources emitting short pulses and create the essential building blocks for future all-fibre arrangements that will be more robust. The sources are expected to have applications in non-linear optics and materials modification.Read moreRead less
Pumping up the volume on sound-light interactions. This project aims to create a new class of integrated microwave information processors on a single optical chip. Using electro-acoustic coupling in semiconductors, we expect to reduce optical power requirements hundredfold, enabling the emergence of practically deployable processors using ordinary telecom lasers. The expected project outcomes are inexpensive, compact, stable and energy efficient microwave photonic processors, a key requirement f ....Pumping up the volume on sound-light interactions. This project aims to create a new class of integrated microwave information processors on a single optical chip. Using electro-acoustic coupling in semiconductors, we expect to reduce optical power requirements hundredfold, enabling the emergence of practically deployable processors using ordinary telecom lasers. The expected project outcomes are inexpensive, compact, stable and energy efficient microwave photonic processors, a key requirement for reference standards and precision measurements of time and frequency. This technology has the potential to create a multitude of opportunities for commercial development in the fields of defence, information security, autonomous vehicles, sensing, and ultra-high bandwidth mobile communications.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
Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this pro ....Catching the fast waves: high speed RF sensing using Brillouin scattering. This project aims to develop a room temperature approach to fast sensing of microwave electromagnetic waves by harnessing stimulated Brillouin Scattering (SBS), simultaneously achieving high frequency range, high resolution and high-speed performance. This project expects to generate new knowledge in microwave photonics and SBS, specifically elucidating the transient temporal response of SBS. Expected outcomes of this project include a proof of concept RF sensor that has multi-Gigahertz real-rime instantaneous bandwidth with high-resolution that can be miniaturized on to a chip. This compact RF sensor, will play a vital role for situational awareness in space, defence and communications applications. Read moreRead less
Plasmon mode lasers; smaller, faster, better. High speed Information Technology (IT) communication is using more and more of our global energy. Energy efficiency of IT hardware can be improved by incorporating small, high performance lasers for short distance optical communication. New metallic and plasmonic nano-lasers lasers are indeed smaller and in theory can have performance advantages over current dielectric cavity lasers. This project looks at developing new electrically pumped plasmonic ....Plasmon mode lasers; smaller, faster, better. High speed Information Technology (IT) communication is using more and more of our global energy. Energy efficiency of IT hardware can be improved by incorporating small, high performance lasers for short distance optical communication. New metallic and plasmonic nano-lasers lasers are indeed smaller and in theory can have performance advantages over current dielectric cavity lasers. This project looks at developing new electrically pumped plasmonic lasers with nano scale semiconductors that satisfy requirements for short distance optical communications. Complex systems of these small, fast lasers will also be investigated, with the aim of providing high speed digital processing capabilities exceeding those of electronics.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.
Australian Laureate Fellowships - Grant ID: FL100100099
Funder
Australian Research Council
Funding Amount
$2,340,409.00
Summary
An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gi ....An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gigabytes. The ground-breaking Petabyte data storage technology we will research will result in the storage capacity of 10,000 DVDs in one disc and thus underpin every sector of our modern life such as remote education, portable banking, global e-security and telemedicine as well as lead to enormous economic benefits in Australia.Read moreRead less