Enhanced interaction of electromagnetics and mechanics in structured media. This project will investigate the interaction between electromagnetic waves and mechanical motion in structured media. Enhancing this interaction will improve a number of modern technologies, such as nano-scaled motors, traps for biological samples and optical wrenches. Modern fabrication techniques will link the electromagnetic and mechanical properties of media, so that the electromagnetic forces will greatly increase, ....Enhanced interaction of electromagnetics and mechanics in structured media. This project will investigate the interaction between electromagnetic waves and mechanical motion in structured media. Enhancing this interaction will improve a number of modern technologies, such as nano-scaled motors, traps for biological samples and optical wrenches. Modern fabrication techniques will link the electromagnetic and mechanical properties of media, so that the electromagnetic forces will greatly increase, making such devices able to manipulate larger objects. Structured materials can also change their properties dynamically, enabling material properties to be altered in real time. This mechanism will form the basis of advanced tunable components to control waves at visible, infrared, terahertz and microwave wavelengths.Read moreRead less
Precision measurement to test fundamental physics. This project gives the University of Western Australia the opportunity to lead some of the world's best tests on fundamental physics by implementing their novel precision technology. It will also strengthen their collaboration between elite metrological institutes, including Paris Observatory, Ecole Normale Superior and Humboldt University.
Nonlinear and tunable topological states of light and sound. This project aims to provide deep theoretical insights into the physics of electromagnetic and mechanical topological states by bridging fundamental concepts of optics, optomechanics and nonlinear physics. The rapidly expanding digital world calls for a new generation of photonic devices to transmit and process information without losses. Recently discovered topological phases open unique opportunities to realise topological states of ....Nonlinear and tunable topological states of light and sound. This project aims to provide deep theoretical insights into the physics of electromagnetic and mechanical topological states by bridging fundamental concepts of optics, optomechanics and nonlinear physics. The rapidly expanding digital world calls for a new generation of photonic devices to transmit and process information without losses. Recently discovered topological phases open unique opportunities to realise topological states of light that are inherently immune to scattering losses. This multidisciplinary project aims to bridge fundamental topological physics with nonlinear nanophotonics and optomechanics by developing novel concepts of topological systems, dynamically tunable by nonlinearity. An expected outcome of this project is new approaches to control both light and sound dynamically in complex nanoscale structures, and uncover disorder-immune technologies for applications in on-chip communications and information processing.Read moreRead less
Functional metasurfaces and metadevices. This project aims to develop and use smart metadevices for light control, high-bandwidth wireless communication and security. Unique properties of metamaterials suggest several useful effects not yet used in real-life. Using electromagnetism, mechanics, colloidal chemistry and nanofabrication, this project will design user-friendly tuneable metadevices made of ultra-thin metasurfaces and three-dimensional liquid metamaterials, and demonstrate electromagne ....Functional metasurfaces and metadevices. This project aims to develop and use smart metadevices for light control, high-bandwidth wireless communication and security. Unique properties of metamaterials suggest several useful effects not yet used in real-life. Using electromagnetism, mechanics, colloidal chemistry and nanofabrication, this project will design user-friendly tuneable metadevices made of ultra-thin metasurfaces and three-dimensional liquid metamaterials, and demonstrate electromagnetic wave manipulation in microwave, terahertz and optical frequency ranges. The outcomes are expected to create opportunities for Australian industry to commercialise smart materials.Read moreRead less
Beam steering by Huygens metasurfaces for sensing applications. Beam steering by Huygens metasurfaces for sensing applications. This project aims to develop steerable radar systems for navigation sensors and surround monitoring in vehicles, using antennas operating in the millimetre-wave range, which have improved resolution and maintain long sensing distances. The boom in radar sensing technologies used for safety and comfort in cars has stimulated the need for cost-effective directional antenn ....Beam steering by Huygens metasurfaces for sensing applications. Beam steering by Huygens metasurfaces for sensing applications. This project aims to develop steerable radar systems for navigation sensors and surround monitoring in vehicles, using antennas operating in the millimetre-wave range, which have improved resolution and maintain long sensing distances. The boom in radar sensing technologies used for safety and comfort in cars has stimulated the need for cost-effective directional antennas for beam steering in sensing applications. This project will use the recently discovered concept of Huygens metasurfaces, which enable cost-effective devices with low transmission losses and strong tuning of beam-steering angle. The wider availability of such radars is expected to enhance collision prevention systems, adaptive cruise control and ultimately help create self-navigating cars.Read moreRead less
Topologically nontrivial electromagnetic states. Topological properties play a fundamental role in many physical phenomena. The best known examples are quantum Hall systems, where insensitivity to local properties manifests itself as conductance through edge states that is insensitive to disorder. While the traditional research focus has been on electronic systems, there has been a recent emergence of great interest in exploring topological orders with photons. Several novel intriguing theoretic ....Topologically nontrivial electromagnetic states. Topological properties play a fundamental role in many physical phenomena. The best known examples are quantum Hall systems, where insensitivity to local properties manifests itself as conductance through edge states that is insensitive to disorder. While the traditional research focus has been on electronic systems, there has been a recent emergence of great interest in exploring topological orders with photons. Several novel intriguing theoretical schemes have been proposed to explore topological orders in photonic systems, both in the linear and strongly interacting regimes. This project aims to develop innovative theoretical and experimental approaches to explore topologically non-trivial states, from microwaves to optical regimes.Read moreRead less
Functional metamaterials based on chiral structures. The project will develop a new class of metamaterials - artificial materials that twist light and synchronise multiple light sources. These structures will show intriguing physical properties with reduced absorption and external tunability, thus paving the way for novel optical technologies.
Triboelectric separation - fundamentals and practice. Triboelectric separation is a novel way to refine mineral ores without using scarce water resources, based on the familiar generation of electrostatic charge by friction. This project will provide a practical dry particle separation process, and a better understanding of a common and important problem in electrostatics.