High-brightness wavelength tuneable lasers for quantum science. This project aims to establish the capability to manufacture application-specific semiconductor lasers. The project will use existing facilities in Australia to enhance our world-leading quantum science research, and establish a viable export-dominated high-tech manufacturing business. Semiconductor lasers are a critical enabling technology for many scientific applications, particularly for quantum science including quantum computin ....High-brightness wavelength tuneable lasers for quantum science. This project aims to establish the capability to manufacture application-specific semiconductor lasers. The project will use existing facilities in Australia to enhance our world-leading quantum science research, and establish a viable export-dominated high-tech manufacturing business. Semiconductor lasers are a critical enabling technology for many scientific applications, particularly for quantum science including quantum computing and quantum sensing. This project is expected to enable the establishment of a high-tech manufacturing capability to support Australia's leading role in quantum science, and expand our scientific instrumentation exports to new and rapidly developing applications such as magnetic sensing and imaging at nanoscale, quantum communication and computation.Read moreRead less
Rogue waves in oceans and optical fibres. Rogue waves can sink large ships in the ocean. They appear more commonly than previously thought. Optical rogue waves, the laboratory counterparts of extreme ocean waves, will allow the project to study the main features of the phenomenon, provide the theoretical explanation for their existence and potentially help to eliminate these catastrophic events.
Integration of III-V semiconductor nanowires on silicon platform. This proposal is at the forefront of nanoscience and nanotechnology. The outcomes are expected to be of great interest to a broad spectrum of industry sectors and academic researchers, including optical communications and microelectronics industries, biological and chemical sensing and national health. This novel material system will be used for the next generation of photonic/electronic devices and to develop advanced 3D optoelec ....Integration of III-V semiconductor nanowires on silicon platform. This proposal is at the forefront of nanoscience and nanotechnology. The outcomes are expected to be of great interest to a broad spectrum of industry sectors and academic researchers, including optical communications and microelectronics industries, biological and chemical sensing and national health. This novel material system will be used for the next generation of photonic/electronic devices and to develop advanced 3D optoelectronic integrated circuits. The success of this project will enhance Australia's international scientific reputation, stimulate local expertise, and help create vibrant new industries.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE120101036
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Integrated mid-infrared optical microcavity sensors. Toxic or illicit substances such as poisons, drugs and explosives can be identified from the way they absorb specific frequencies of light in the mid-infrared. This project will develop a new kind of molecule-specific, optical sensor capable of detecting trace quantities of such materials.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100121
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
Equipment for International Collaboration in Gravitational Wave Detection. Equipment for international collaboration in gravitational wave detection: This project will allow the Australian Consortium for Gravitational Astronomy to install optical equipment at its dedicated research facility, and to install data analysis pipelines on new iVEC Pawsey Centre GPU-enabled supercomputers. The equipment is required for research aimed at stabilising instabilities in the new international gravitational w ....Equipment for International Collaboration in Gravitational Wave Detection. Equipment for international collaboration in gravitational wave detection: This project will allow the Australian Consortium for Gravitational Astronomy to install optical equipment at its dedicated research facility, and to install data analysis pipelines on new iVEC Pawsey Centre GPU-enabled supercomputers. The equipment is required for research aimed at stabilising instabilities in the new international gravitational wave detectors currently being commissioned in the USA and Europe. Real time data from the new detectors will be analysed using innovative new techniques. Scientists across Australia will be able to rapidly localise potential gravitational wave sources to direct robotic telescope observations. This could enable the first detection of gravitational waves.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.
Integration of broadband microwave photonic frequency convertors. This project aims to develop microwave photonic processors with increased bandwidth and unprecedented radio frequency signal processing. The new technology will enhance radar systems and electronic-warfare capabilities, and allow more flexible delivery of bandwidth for mobile communication systems. Benefits for Australian end-users and industry include improved surveillance for defence and revenue growth in companies working with ....Integration of broadband microwave photonic frequency convertors. This project aims to develop microwave photonic processors with increased bandwidth and unprecedented radio frequency signal processing. The new technology will enhance radar systems and electronic-warfare capabilities, and allow more flexible delivery of bandwidth for mobile communication systems. Benefits for Australian end-users and industry include improved surveillance for defence and revenue growth in companies working with the Australian defence forces.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100024
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Optical profiler with dynamic micro electro-mechanical systems capability. This facility will allow Australian researchers to access the world's best capability in dynamic, time resolved, optical three-dimensional profiling of surfaces and devices. It will advance a raft of science research and industry applications characterising natural and artificial materials and underpinning next generation optical, photonic and microelectronic devices.