The development of novel and tunable metamaterials. Metamaterials are designed materials with properties that cannot be found in nature. This project uses a new disruptive design that allows broadband metamaterials to be made using mass production techniques. The design opens up a range of new applications in environmental and medical sensing, improved security screening and active devices.
Memory and light for integrated quantum systems. Optical quantum information technologies have the potential to change the way we work and play, but there are problems to be overcome: we lack both a memory for quantum information and reliable light sources that can be integrated into quantum networks. This project addresses both these issues and will bring quantum technologies closer to market.
Selective area nano-epitaxy. A new major program will be initiated to investigate the epitaxial growth of certain semiconductor nanowires on patterned substrates, without the use of a catalyst. It will result in the ability to produce nanowires of high quality and uniformity. This will lead the way for new and advanced concept nanowire-based devices for future applications.
Antimonide-based nanowires for infra-red and energy applications. This project will investigate and to understand the fundamental growth mechanisms of antimonide-based semiconductor nanowires. It will result in the ability to produce nanowires of high quality and uniformity for applications in infra-red technologies such as photodetectors and solar cells.
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
Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem d ....Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem device. The expected outcome is a solar cell that can convert more than 30 per cent of incident sunlight into electricity, compared to 20-25 per cent for current cells. Developing cheap, high efficiency solar cells should further reduce the cost of solar electricity, and accelerate the uptake of clean energy.Read moreRead less
Topological wave manipulation in hybrid integrated platforms. This project aims to establish a powerful toolkit for topological wave manipulation in photonic systems interfaced with layered 2D materials. This research will address a significant problem of miniaturising photonic components for reliable and compact signal processing. The reduction in size will be achieved by engineering coupling of topological photonic states with matter in judiciously structured materials at subwavelength scales. ....Topological wave manipulation in hybrid integrated platforms. This project aims to establish a powerful toolkit for topological wave manipulation in photonic systems interfaced with layered 2D materials. This research will address a significant problem of miniaturising photonic components for reliable and compact signal processing. The reduction in size will be achieved by engineering coupling of topological photonic states with matter in judiciously structured materials at subwavelength scales. The expected outcomes will include new methods of controlling light-matter waves on a chip via pattern distortions or twists of the 2D materials, without the use of strong magnetic and electric fields. These outcomes will benefit future development of high performance and energy-efficient integrated devices.Read moreRead less