Worldwide Collaboration for the Creation of New Frequency Standards, and their Application to testing the Foundations of Physics. Frequency standards are crucial for the highest precision scientific measurements as well as in modern communication and information technology (C&IT). Having already achieved world-best performance for short-term frequency stability, our research team is seeking support to participate in a broad international program with three particular objectives:
(i) create ne ....Worldwide Collaboration for the Creation of New Frequency Standards, and their Application to testing the Foundations of Physics. Frequency standards are crucial for the highest precision scientific measurements as well as in modern communication and information technology (C&IT). Having already achieved world-best performance for short-term frequency stability, our research team is seeking support to participate in a broad international program with three particular objectives:
(i) create new frequency standards based on laser-cooled atoms,
(ii) develop femtosecond laser technology for generating low noise microwave and optical signals,
(iii) develop microwave technology suitable for operation in space.
Improved frequency standards will allow decisive measurements on several fundamental scientific questions, as well as leading to commercial applications in C&IT.
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Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain thei ....Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain their behaviour, and use this knowledge to create bio-compatible hi-tech materials and devices. We anticipate significant benefits from the perspectives of basic science and utilisation of biomaterials for new green technologies.Read moreRead less
Slow light in nanostructured materials. This project will introduce and demonstrate novel concepts for dynamically controlling the speed of light and manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices performing fast switching and processing of optical signals. These developments underpin the next generation of high-performance networks, promising to revolutionize global communications. This project will ke ....Slow light in nanostructured materials. This project will introduce and demonstrate novel concepts for dynamically controlling the speed of light and manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices performing fast switching and processing of optical signals. 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
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
SILICON BASED PHOTONIC CRYSTALS FOR MONITORING BIOMOLECULAR INTERACTIONS. Two great goals of biomolecular science are to monitor biomolecular interactions in real time and with sufficient sensitivity to allow small amounts of biological material to be investigated. The achievement of these goals is limited by the methods of transducing these reactions. The aim of this multidisciplinary proposal is to overcome this limitation by developing photonic devices that exploit the unique properties of na ....SILICON BASED PHOTONIC CRYSTALS FOR MONITORING BIOMOLECULAR INTERACTIONS. Two great goals of biomolecular science are to monitor biomolecular interactions in real time and with sufficient sensitivity to allow small amounts of biological material to be investigated. The achievement of these goals is limited by the methods of transducing these reactions. The aim of this multidisciplinary proposal is to overcome this limitation by developing photonic devices that exploit the unique properties of nanoporous silicon. The hybridisation of DNA will be used as a model biorecognition reaction. Potential applications of these photonic devices are as highly sensitive affinity sensors and as tools for investigating the kinetics of biomolecular interactions.Read moreRead less
Targeted light - optical mode control at the nanoscale. Nanophotonics provides a path for controlling the interaction of light and matter at the nanoscale. Using spatially tailored laser beams to address nano-particles, this project aims to create new approaches for specifically targeting light with nano-scale precision, which has valuable potential applications in biosensing and communications.
Insight from Darkness: Nanophotonics for real-time phase imaging. This project aims to develop ultrathin surfaces patterned on the nanoscale for extracting information from optical wavefields. These devices can be designed to provide real-time phase contrast imaging of transparent objects. This capability would open up the possibility of live-cell imaging with no expensive optical components and no, or minimal, computational post-processing. The planar configuration is designed to be compatible ....Insight from Darkness: Nanophotonics for real-time phase imaging. This project aims to develop ultrathin surfaces patterned on the nanoscale for extracting information from optical wavefields. These devices can be designed to provide real-time phase contrast imaging of transparent objects. This capability would open up the possibility of live-cell imaging with no expensive optical components and no, or minimal, computational post-processing. The planar configuration is designed to be compatible with next-generation lab-on-a-chip technologies and permit rapid throughput diagnostics with potential applications in biomedicine and materials science. Expected project outcomes may also underpin fundamental advances in understanding the interaction of light with nanostructures.Read moreRead less
Sensing single electrons with single molecules. The focus of this project is on optical detection of single electron transport in solids and in large/bio molecules. Successful experimental demonstration of the proposed technique will considerably enhance Australia's standing in high profile areas of natural sciences. In practical terms, it can contribute to development of new generation solar cells, artificial photosynthetic centres, and a new generation of nanoprobes for biomedical application ....Sensing single electrons with single molecules. The focus of this project is on optical detection of single electron transport in solids and in large/bio molecules. Successful experimental demonstration of the proposed technique will considerably enhance Australia's standing in high profile areas of natural sciences. In practical terms, it can contribute to development of new generation solar cells, artificial photosynthetic centres, and a new generation of nanoprobes for biomedical applications. Because the single-molecule technique is a new and dynamic field, opportunities exist for significant commercial property development. The project will also train a number of students in several fields of high technology, all of which are likely to have high demand in the future.Read moreRead less
Enhancing the science reach of second generation interferometric gravitational wave detectors through innovative mirror design and control. Predicted by Einstein, gravitational waves promise to unlock the secrets of the universe just as seismic measurements unlocked the secrets of the Earth's interior. Scientists are on the brink of detecting these waves. This research aids that effort by developing Australian technologies which allow specific gravitational wave sources to be targeted.
Probing nanoscale disorder in 3D with x-ray free-electron lasers. This project aims to reveal the 3D nanostructure of disordered matter with x-rays for the first time. Existing x-ray scattering techniques for disordered structures currently provide limited, one-dimensional information only. The expected outcomes of the project include an enhanced new capability for the Australian Synchrotron and international x-ray laser facilities, and new insights into the microscopic origins of the properties ....Probing nanoscale disorder in 3D with x-ray free-electron lasers. This project aims to reveal the 3D nanostructure of disordered matter with x-rays for the first time. Existing x-ray scattering techniques for disordered structures currently provide limited, one-dimensional information only. The expected outcomes of the project include an enhanced new capability for the Australian Synchrotron and international x-ray laser facilities, and new insights into the microscopic origins of the properties of liquids and biological membranes. This should benefit research areas that use x-ray scattering to probe the nanostructure of materials for diverse applications such as nanotechnology, fuel cells and drug design.Read moreRead less