A silicon-compatible light source on a silicon-on-insulator platform. Silicon is emerging as an important photonic material owing to the cheap processing methods developed for electronics. This project aims to capture key technology for integrating photonic components onto silicon. It can bring social and commercial benefits to Australia such as high-level research as well as opportunities for commercialisation.
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
A versatile optical wavelength and mode switching device for future telecommunication networks. This project will develop a next generation switching device for future fibre optical communication networks that will divide their information among several modes of specialty fibre. This device will be a key component for allowing network operators to move to these novel mode-multiplexed networks in order to overcome the looming capacity crunch.
Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote ....Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote this attractive field and will facilitate the emergence of novel technologies. It will also lead to important international collaborations and bring important new expertise to Australia, complementing the core research program of the ARC Centre of Excellence CUDOS.Read moreRead less
Tunable shaping and switching of polychromatic light for integrated photonics. This project will help to promote in Australia novel field of polychromatic and white-light photonics, which is currently being very actively explored at the leading research centres around the globe. It will introduce and demonstrate innovative concepts for efficient manipulation of multi-color light in integrated photonic structures, which will keep Australia at the forefront of the international research and will c ....Tunable shaping and switching of polychromatic light for integrated photonics. This project will help to promote in Australia novel field of polychromatic and white-light photonics, which is currently being very actively explored at the leading research centres around the globe. It will introduce and demonstrate innovative concepts for efficient manipulation of multi-color light in integrated photonic structures, which will keep Australia at the forefront of the international research and will contribute to the uptake of frontier technologies by Australian industries. This project will lead to international collaborations which will bring important new expertise to Australia. It will also provide training for students in breakthrough applications of photonics and nanotechnology.Read moreRead less
NONLINEAR SURFACE MODES IN PHOTONIC AND PLASMONIC METAMATERIALS. This project will underpin the development of frontier technologies of manipulating light on subwavelength scale, which has a potential of delivering revolutionary advances in nanotechnology and photonics. The project is therefore of national benefit for its advances in the innovative cutting-edge research of nano-optics. The project will initialize collaboration with world leading experts in the area, bringing important expertise ....NONLINEAR SURFACE MODES IN PHOTONIC AND PLASMONIC METAMATERIALS. This project will underpin the development of frontier technologies of manipulating light on subwavelength scale, which has a potential of delivering revolutionary advances in nanotechnology and photonics. The project is therefore of national benefit for its advances in the innovative cutting-edge research of nano-optics. The project will initialize collaboration with world leading experts in the area, bringing important expertise to Australia. It will also strengthen Australia's international competitive ability and reputation in the field of nanophotonics.Read moreRead less
ARROW - the route to better Photonic Crystal Fibres. The Frontier Technology based on Photonic crystal fibres (PCFs) will be a vital component of next generation photonic networks and devices. Australia is among the 5 leading nations in PCF research. However we are now at a pivotal stage in the development of PCFs: their production is close to maturity, and it is now up to PCF designers to make the difference. The proposed project will provide the Australian scientific community as well as Austr ....ARROW - the route to better Photonic Crystal Fibres. The Frontier Technology based on Photonic crystal fibres (PCFs) will be a vital component of next generation photonic networks and devices. Australia is among the 5 leading nations in PCF research. However we are now at a pivotal stage in the development of PCFs: their production is close to maturity, and it is now up to PCF designers to make the difference. The proposed project will provide the Australian scientific community as well as Australian photonics companies with advanced PCF designing capabilities, giving Australia an opportunity to take a leading position in PCF development and commercialisation. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100116
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
100 Gbit to 1 Terabit per second optical communication test bed facility. This facility will develop and demonstrate novel optical technologies that will underpin the generation and transmission of a higher-speed Ethernet at 100 Gb/s to 1Terabit/s, and will lead to better broadband and more energy efficient internet. At the foundation of this research will be a test bed with multiple signal sources at data rates above 50 Gbaud.
Discovery Early Career Researcher Award - Grant ID: DE120102069
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Optical solitons on a photonic chip: unprecedented light control at the nanoscale. Solitons, waves that maintain their shape as they travel, exist in systems as diverse as water waves, molecular biology, and optics. This project explores previously unobservable light propagation regimes in two-dimensional periodic media, photonic crystals. These studies provide unprecedented control of light-matter interaction at the nanoscale.
Broadband compensation of nonlinear signal distortion in optical fibre communications. This project will investigate novel optical technologies for overcoming the approaching data capacity limits of global optical communication networks that are caused by transmission errors from nonlinear signal distortion in optical fibre. The research will show that light propagation through specially designed waveguides can cancel the distortion.