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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
Functional nonlinear nanophotonics. This project will uncover novel ways of controlling ultra-short optical pulses through the special structuring of materials at the nanoscale. New functionalities based on enhanced nonlinear light-matter interactions will underpin advances in future optical communication networks and computing systems, laser radars and sensing applications.
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.
Resonant nanophotonics: tailoring resonant interaction of light with nanoclusters. This project will unlock new ways of controlling resonant light-matter interaction in nanostructured materials for the next generation of integrated nanophotonic devices. The project outcomes will support Australia's leadership in the development of energy efficient components for advanced photonic networks and optical communications.
Complex light and matter waves: merging nano-optics, quantum physics, and field theory. This project aims to address frontier problems at the confluence of nano-optics, plasmonics, electron microscopy, quantum weak measurements, and relativistic wave fields. Miniaturisation of devices, and ever-increasing amounts of processed information, lead to the increasing complexity of classical and quantum waves considered in fundamental science and exploited in applications. This project aims to develop ....Complex light and matter waves: merging nano-optics, quantum physics, and field theory. This project aims to address frontier problems at the confluence of nano-optics, plasmonics, electron microscopy, quantum weak measurements, and relativistic wave fields. Miniaturisation of devices, and ever-increasing amounts of processed information, lead to the increasing complexity of classical and quantum waves considered in fundamental science and exploited in applications. This project aims to develop novel methods and concepts, and unveil intriguing phenomena in physics of wave systems with nontrivial structure and internal degrees of freedom. This will provide deep insight into properties of complex classical and quantum waves, and new avenues for fine control of diverse light, matter, and mixed light-matter systems.Read moreRead less
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.
Optomechanical metrology: pushing optical sensing to its limit. This project aims to pioneer technologies to observe and control the microscopic world with unprecedented precision, and apply them to realise practical sensors with unrivalled performance. Nano- and micro-scale sensors will be developed that resolve motion smaller than an atomic nucleus, in a classical spin-off from international efforts to study quantum physics at the nanoscale. Record precision will be achieved in thermometry and ....Optomechanical metrology: pushing optical sensing to its limit. This project aims to pioneer technologies to observe and control the microscopic world with unprecedented precision, and apply them to realise practical sensors with unrivalled performance. Nano- and micro-scale sensors will be developed that resolve motion smaller than an atomic nucleus, in a classical spin-off from international efforts to study quantum physics at the nanoscale. Record precision will be achieved in thermometry and magnetometry. New tools will be developed for lab-on-a-chip medical diagnosis and thermal imaging, that in future could allow femtolitre diagnosis of blood diseases such as malaria, on-chip genomic analysis, more efficient airport screening, and more precise satellite maps of global and atmospheric temperature.Read moreRead less
Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded ....Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded nano-Radiators (SUPER) Dots), based on purpose-engineered up-conversion nanocrystals that are ultra-bright and have low background interference, high specificity, speed, and large-scale multiplexing capacity. These probes will allow microscopy and flow cytometry to measure hitherto undetectable rare-event molecules and cells, opening new frontiers for the discovery of new biomarkers.Read moreRead less
Quantum dot-sensitised solar cells: can efficiency beyond the Shockley-Queisser limit be achieved? The project will address key barriers to broader commercialisation of cost-effective titania-based solar cells by utilising novel physics of semiconductor quantum dot materials used as a sensitiser. The research outcomes will answer key questions about the ultimate efficiency of these cells, and help transform the Australian PV industry.
Ultrafast Photonic Electron Microscopy: Visualising dynamics at the nanoscale. The dynamics of molecular processes are too fast to observe with any microscope so science has instead relied on recording the static before and after states of these changes, inferring what happens in between. This project aims to combine the advantages of ultrafast photonic laser control and electron microscopy to allow the direct visualisation of dynamics at the nanoscale in physical and biological systems. By prov ....Ultrafast Photonic Electron Microscopy: Visualising dynamics at the nanoscale. The dynamics of molecular processes are too fast to observe with any microscope so science has instead relied on recording the static before and after states of these changes, inferring what happens in between. This project aims to combine the advantages of ultrafast photonic laser control and electron microscopy to allow the direct visualisation of dynamics at the nanoscale in physical and biological systems. By providing a view into how order emerges from the thermal chaos of molecular objects this project aims to help to reveal the physical basis for life.Read moreRead less