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Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on t ....Brillouin processing for carrier recovery in optical communications. This project aims to apply Brillouin processing to the development of an innovative, self-tracking optical filter for isolating optical carriers in the coherent receiver of future ultrahigh bit-rate optical communication systems. By recovering a needle-like optical carrier with great precision from a drifting sea of wide-band noise and data channels, the project expects to minimise the effect of optical carrier distortions on the data-carrying signals. The project should advance knowledge in optical signal processing and communications technologies, with outcomes that increase the data-carrying capacity of optical networks. Future telecommunication networks should benefit through improved transmission rates and extended fibre links.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100160
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Distributed ultra-fast optical clocks for terabit/s communications. The project aims to enable experiments with full spectrum occupation for transmission over field-deployed optical fibre. Future optical communication systems will have to use the full available spectral bandwidth and advanced multiplexing and modulation to achieve ultimate data capacity over a fibre link. To realistically test such links, experiments must be performed over "real-world" fibre links. By linking three telecoms rese ....Distributed ultra-fast optical clocks for terabit/s communications. The project aims to enable experiments with full spectrum occupation for transmission over field-deployed optical fibre. Future optical communication systems will have to use the full available spectral bandwidth and advanced multiplexing and modulation to achieve ultimate data capacity over a fibre link. To realistically test such links, experiments must be performed over "real-world" fibre links. By linking three telecoms research laboratories, the project will create a close collaboration optical network that enables this research. Anticipated outcomes are the opportunity to conduct research over field-deployed fibre links and to prototype and test communication technology over real-world links, creating a simplified path to commercialisation.Read moreRead less
Low-energy electro-photonics: novel materials, devices and systems. This project aims to develop low-power technologies for programming and tuning photonic integrated circuits (PICs). By replacing thermal tuning, the project will reduce power consumption from watts to milliwatts, which also eliminates the thermal crosstalk that limits the complexity of today's PICs. The expected outcome will be the basis for a generic field-programmable photonic chip, which can be used to rapidly prototype desig ....Low-energy electro-photonics: novel materials, devices and systems. This project aims to develop low-power technologies for programming and tuning photonic integrated circuits (PICs). By replacing thermal tuning, the project will reduce power consumption from watts to milliwatts, which also eliminates the thermal crosstalk that limits the complexity of today's PICs. The expected outcome will be the basis for a generic field-programmable photonic chip, which can be used to rapidly prototype designs for production as full custom chips as part of a new Australian industry capability. The expected benefits will be a faster innovation cycle, greater adoption of photonic technologies, and support of research into, for example, neuromorphic optical processing, and advanced communications and sensing systems.Read moreRead less
Energy resolving photodetection through extracting hot carrier photocurrent. The project will develop infrared metallic hot-electron photodetectors for energy and wavelength resolving photodetection. With the varied applications of infrared photodetectors in Australia, the project aims to establish a novel photodiode architecture that harnesses thermal energy through hot-electrons for high speed and broadband photodetection. By enabling energy resolving photodetection, the photodiode will combi ....Energy resolving photodetection through extracting hot carrier photocurrent. The project will develop infrared metallic hot-electron photodetectors for energy and wavelength resolving photodetection. With the varied applications of infrared photodetectors in Australia, the project aims to establish a novel photodiode architecture that harnesses thermal energy through hot-electrons for high speed and broadband photodetection. By enabling energy resolving photodetection, the photodiode will combine research laboratory scale capabilities into a single optical element. Advanced hot-electron absorber materials will be studied. The research outcomes have applications from telecommunications to biotechnology where photodetectors are a critical sensing component, and for metallic hot electrons utilised in photocatalysis.Read moreRead less
Photon-sorting nanopixels for multispectral & polarisation-resolved imaging. Recent years have seen staggering growth in the prevalence of digital cameras. Conventional digital cameras are designed to mimic the response of the human eye, and therefore record the intensities of three spectral channels: red, green and blue (RGB). This project aims to harness recent advances in nano-optics for the realisation of a new generation of digital cameras. Rather than performing simple colour (RGB) imaging ....Photon-sorting nanopixels for multispectral & polarisation-resolved imaging. Recent years have seen staggering growth in the prevalence of digital cameras. Conventional digital cameras are designed to mimic the response of the human eye, and therefore record the intensities of three spectral channels: red, green and blue (RGB). This project aims to harness recent advances in nano-optics for the realisation of a new generation of digital cameras. Rather than performing simple colour (RGB) imaging, these will be capable of multispectral and polarisation-resolved imaging, whose richer information will be beneficial for applications from medical diagnostics to industrial quality control. These capabilities will be enabled by optical nanostructures that deflect light in a wavelength- and polarisation-dependent manner.Read moreRead less
Luminescence-based imaging system for industrial tandem solar cells. This project aims to develop an Australian-made inspection system for next-generation solar cells. Besides allowing, for the first time, fast measurements of large-size tandem solar cells, the system will also enable the determination of key parameters that cannot be measured by current methods. This capability is expected to generate new knowledge in the areas of perovskite and tandem solar cells.
The expected outcomes include ....Luminescence-based imaging system for industrial tandem solar cells. This project aims to develop an Australian-made inspection system for next-generation solar cells. Besides allowing, for the first time, fast measurements of large-size tandem solar cells, the system will also enable the determination of key parameters that cannot be measured by current methods. This capability is expected to generate new knowledge in the areas of perovskite and tandem solar cells.
The expected outcomes include the development of new characterisation methods for advanced solar cells and improvement of their quality, as well as enhancing Australian capabilities in building sophisticated characterisation instruments. This should provide benefits such as cheaper solar energy and the development of local inspection industry.Read moreRead less
Teaching old dogs new tricks: making ordinary glass both guide and modulate light in photonic chips. The continued revolution of telecoms, and other industries, by photonics demands active integrated photonics: chips that can switch, modulate and modify light. Currently this requires problematic materials. This project will innovatively combine breakthroughs in two areas: poling and laser writing, to produce active devices in standard silicate glass chips.
Nanophotonic tandem designs for high efficiency solar cells. This project will develop high-efficiency tandem solar cells that combine established silicon cell technology with novel low-cost thin-film solar cells. It will incorporate nanostructured layers between the cells that selectively trap different wavelengths of light, maximising light absorption in the top cell. This will make it possible to use a very thin top cell, reducing the requirements on electronic quality of the material. This p ....Nanophotonic tandem designs for high efficiency solar cells. This project will develop high-efficiency tandem solar cells that combine established silicon cell technology with novel low-cost thin-film solar cells. It will incorporate nanostructured layers between the cells that selectively trap different wavelengths of light, maximising light absorption in the top cell. This will make it possible to use a very thin top cell, reducing the requirements on electronic quality of the material. This project will also develop self-assembly techniques to enable the new nanostructures to be fabricated quickly and cheaply but with a high degree of control. Such cells will allow open the door to higher efficiencies, and lower costs, than is achievable with conventional solar cells.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100453
Funder
Australian Research Council
Funding Amount
$442,408.00
Summary
Nervous tissue stimulation using Multi-Junction Silicon Photodiodes. Currently, in order to stimulate different areas in nervous tissue, brain-machine-interfaces (BMIs) usually rely on multi electrode arrays where each electrode is connected to a wire, that connects to other electronics, all of which has to be safely encapsulated, thus increasing the size of the devices and complicating the surgical procedure for implanted devices. This project aims to develop a silicon multi-junction photodiode ....Nervous tissue stimulation using Multi-Junction Silicon Photodiodes. Currently, in order to stimulate different areas in nervous tissue, brain-machine-interfaces (BMIs) usually rely on multi electrode arrays where each electrode is connected to a wire, that connects to other electronics, all of which has to be safely encapsulated, thus increasing the size of the devices and complicating the surgical procedure for implanted devices. This project aims to develop a silicon multi-junction photodiode that can provide a photovoltage high enough to efficiently excite nervous tissue. A BMI based on this approach could be much smaller and could be powered optically via thin fibres, thus in the long run enabling smaller and safer implants for restoring function in disabled people.Read moreRead less
Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and rob ....Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and robust systems for generating a comb of coherent laser lines. These photonic chip comb sources will be inexpensive, compact and energy efficient with transformative impact in spectroscopy, microscopy, precision measurement, quantum computing and ultra-fast optical fibre communications.Read moreRead less