Function and evolution of optical structures in nature. Designing optical structures that simultaneously satisfy multiple and conflicting criteria and satisfy difficult manufacturing constraints is technologically challenging. However, Nature has been doing this for millions of years. This project is a systematic study of optical structures in one of Nature's most diverse range of species: butterflies. The microstructures inside butterfly scales have an amazing diversity of geometries that produ ....Function and evolution of optical structures in nature. Designing optical structures that simultaneously satisfy multiple and conflicting criteria and satisfy difficult manufacturing constraints is technologically challenging. However, Nature has been doing this for millions of years. This project is a systematic study of optical structures in one of Nature's most diverse range of species: butterflies. The microstructures inside butterfly scales have an amazing diversity of geometries that produce structural colour and are amongst the most complex naturally occurring optical structures produced by a single cell.Read moreRead less
Engineering phase and the flow of light in nanophotonics. Optical devices on the scale of only billionths of a meter impel photonic revolution in information technologies. The extraordinary sensitivity and tunability of light confined on nano-scale is caused by the yet unexplored and poorly understood world of tiniest flows of energy, the optical vortices. In this project we will learn to manipulate optical vortices with the light itself, introducing original concepts for intelligent engineering ....Engineering phase and the flow of light in nanophotonics. Optical devices on the scale of only billionths of a meter impel photonic revolution in information technologies. The extraordinary sensitivity and tunability of light confined on nano-scale is caused by the yet unexplored and poorly understood world of tiniest flows of energy, the optical vortices. In this project we will learn to manipulate optical vortices with the light itself, introducing original concepts for intelligent engineering of nano-elements of a photonic chip. This project will deliver underpinning knowledge, foremost practical expertise, and the prominent training of young researchers to secure Australia's international leadership in the rapidly growing and competitive field of nanophotonics.Read moreRead less
Singular photonics: twisted light and optical vortices.
This project will help to establish and support a world-leading research team in Australia in the field of singular photonics and the physics of twisted light; it will help to return the leading positions of the Australian physics in the field of singular optics, and it will initiate a design of a novel generation of photonic devices operating with vortex beams. The project will promote this field in order to enhance its rapid development ....Singular photonics: twisted light and optical vortices.
This project will help to establish and support a world-leading research team in Australia in the field of singular photonics and the physics of twisted light; it will help to return the leading positions of the Australian physics in the field of singular optics, and it will initiate a design of a novel generation of photonic devices operating with vortex beams. The project will promote this field in order to enhance its rapid development and facilitate the emergence of novel technologies in Australia; it will be combined with an extensive collaboration with top overseas groups attracting strong interest from industry.Read moreRead less
Imaging circumstellar matter at high resolution. Within contemporary astrophysics there is a particular fascination with matter in near-stellar environments. Studies of stellar and planetary systems from formation through to eventual destruction entail observation of material, principally dust and gas, playing their parts on a very remote stage. A new generation of telescopes, known as interferometers, deliver extremely high resolutions enabling our first direct glimpses of these phenomena. Here ....Imaging circumstellar matter at high resolution. Within contemporary astrophysics there is a particular fascination with matter in near-stellar environments. Studies of stellar and planetary systems from formation through to eventual destruction entail observation of material, principally dust and gas, playing their parts on a very remote stage. A new generation of telescopes, known as interferometers, deliver extremely high resolutions enabling our first direct glimpses of these phenomena. Here I propose using a number of these devices in concert in order to dramatically enhance their scientific payoff. In addition to enabling unique studies of stellar systems, new techniques for merging disparate data into powerful combined forms will be devised.Read moreRead less