Slow-light photonics. This project will introduce and demonstrate novel concepts for the manipulation of optical signals in ultra-compact photonics devices, making an essential step towards fast all-optical switching and processing of data streams. These developments underpin the next generation of high-performance networks, promising to revolutionize global communications. This project will keep Australia at the forefront of international research and provide training of students on breakthroug ....Slow-light photonics. This project will introduce and demonstrate novel concepts for the manipulation of optical signals in ultra-compact photonics devices, making an essential step towards fast all-optical switching and processing of data streams. These developments underpin the next generation of high-performance networks, promising to revolutionize global communications. This project will keep Australia at the forefront of international research and provide training of students on breakthrough applications of photonics and nanotechnology, contributing to the uptake of frontier technologies by Australian industries for successful operation in a competitive global environment.Read moreRead less
Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transfor ....Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transforming Australian Industries" by providing fundamental understanding of novel physical phenomena and underpinning technological advances in the fields of photonics, atom, and electron optics, where Australia has built strong expertise and plays a significant role in the international development.Read moreRead less
Nonlinear photonic crystals. Photonic crystals have recently became very attractive for photonic technology, that uses light instead of slow electrons as the information carriers replacing electronics in communications and information management. This project has the purpose to develop the fundamental concept of nonlinear photonic crystals and demonstrate their possible applications analysing the properties of the nonlinearity-induced light localization, nonlinear transmission, and frequency co ....Nonlinear photonic crystals. Photonic crystals have recently became very attractive for photonic technology, that uses light instead of slow electrons as the information carriers replacing electronics in communications and information management. This project has the purpose to develop the fundamental concept of nonlinear photonic crystals and demonstrate their possible applications analysing the properties of the nonlinearity-induced light localization, nonlinear transmission, and frequency conversion in band-gap materials with the intensity-dependent optical response. This will allow the possibility realising in practice nonlinear switching even for sharply bent waveguides, providing an effective way to control the flow of light in band-gap photonic circuits.Read moreRead less
Bifurcations of dissipative solitons. Fundamental research on the basic concepts of solitons in dissipative systems and their bifurcations is the next essential step for further progress in the science of optical pulse generators and amplifiers. Australia was the first country in the world to use self-organized ultra-short pulses, called solitons, in a commercially-deployed optical transmission line. This proposed new research will answer the question of how solitons behave at the ultimate limi ....Bifurcations of dissipative solitons. Fundamental research on the basic concepts of solitons in dissipative systems and their bifurcations is the next essential step for further progress in the science of optical pulse generators and amplifiers. Australia was the first country in the world to use self-organized ultra-short pulses, called solitons, in a commercially-deployed optical transmission line. This proposed new research will answer the question of how solitons behave at the ultimate limits of optics. New principles of ultra-short pulse generation and amplification, developed in our research, will provide the basis for an unprecedented increase in the capacity of optical transmission and processing of information.Read moreRead less
Dissipative soliton resonances and their applications. Many branches of science and technology, such as precise eye surgery, biological cell machinery, painless dentistry, optical data storage, material micro-machining and laser fusion, rely heavily on high power femtosecond pulse laser oscillators that deliver the necessary power, in a very short time, to nanometer scale targets within a tissue or a material. A further increase in the power of a pulse and a decrease in its duration, combined wi ....Dissipative soliton resonances and their applications. Many branches of science and technology, such as precise eye surgery, biological cell machinery, painless dentistry, optical data storage, material micro-machining and laser fusion, rely heavily on high power femtosecond pulse laser oscillators that deliver the necessary power, in a very short time, to nanometer scale targets within a tissue or a material. A further increase in the power of a pulse and a decrease in its duration, combined with a reduction in complexity and price can be achieved, but this advance depends strongly on the theory of dissipative solitons, and particularly on the idea of soliton resonances. Novel ideas developed within this project will put new productive tools in the hands of doctors, biologists and physicists.Read moreRead less
Solitons and localised structures in nonlocal nonlinear media. Solitons - localised waves existing in nonlinear media may propagate without changing their shape and interact with each other as real particles. They are ubiquitous in nature - exist in any system exhibiting dispersion and nonlinearity. This project aims to study theoretically and experimentally properties of beams and solitons in non-local nonlinear systems. It will lay out theoretical foundations of the nonlocal solitons and d ....Solitons and localised structures in nonlocal nonlinear media. Solitons - localised waves existing in nonlinear media may propagate without changing their shape and interact with each other as real particles. They are ubiquitous in nature - exist in any system exhibiting dispersion and nonlinearity. This project aims to study theoretically and experimentally properties of beams and solitons in non-local nonlinear systems. It will lay out theoretical foundations of the nonlocal solitons and demonstrate experimentally their unique features. This research will have an impact on understanding of the soliton phenomena in many fields including optics and matter waves, providing knowledge which may be subsequently transferred to practical technologies, such as in formation of optical circuits.Read moreRead less
Singular optics of polychromatic light. This project targets fundamental research in the emerging field of nonlinear singular optics with polychromatic light. It underpins new technological advances in the field of photonics, where Australia has built strong expertise and plays a significant role in the international development. This research will assist in the development of new type of photonic applications, where the spatial and spectral coherence of light plays a key role. Therefore our pro ....Singular optics of polychromatic light. This project targets fundamental research in the emerging field of nonlinear singular optics with polychromatic light. It underpins new technological advances in the field of photonics, where Australia has built strong expertise and plays a significant role in the international development. This research will assist in the development of new type of photonic applications, where the spatial and spectral coherence of light plays a key role. Therefore our project will contribute to the designated priority area 'Frontier Technologies for Building and Transforming Australian Industries' by providing fundamental understanding of novel physical phenomena and by building experimental and theoretical basis for new photonic technologies.Read moreRead less
Nanoscale nonlinear optics. Advances in nanotechnology have led to the realisation of nanoscale photonic components that enable integration within electronic chips. Now the challenge is to make these components perform computing functions themselves, thus providing ultra-high operation speeds and reducing power consumption. This project will utilize the intensity dependent interaction of light with metal-dielectric nanostructures to establish new processing functions of the photonic components. ....Nanoscale nonlinear optics. Advances in nanotechnology have led to the realisation of nanoscale photonic components that enable integration within electronic chips. Now the challenge is to make these components perform computing functions themselves, thus providing ultra-high operation speeds and reducing power consumption. This project will utilize the intensity dependent interaction of light with metal-dielectric nanostructures to establish new processing functions of the photonic components. Our research underpins integration of photonics in future generations of computers and enables novel applications in subwavelength optical imaging and sensing. This project will therefore strongly enhance the standing of Australia in the field of nanotechnology.Read moreRead less
Nonlinear optics of soft matter. This project will develop new strategies for the use and control of soft-matter systems by exploiting nonlinear interactions with light, and therefore falls into the Designated Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries - Breakthrough Science. With soft matter research being increasingly important for applications within industry and medicine, the emergence of new technology for control of nanoparticles could pr ....Nonlinear optics of soft matter. This project will develop new strategies for the use and control of soft-matter systems by exploiting nonlinear interactions with light, and therefore falls into the Designated Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries - Breakthrough Science. With soft matter research being increasingly important for applications within industry and medicine, the emergence of new technology for control of nanoparticles could provide significant benefits for the scientific community as well as Australian companies.
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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