Special Research Initiatives - Grant ID: SR0354658
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of ....The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of nanoparticle based technologies through an integrated network of scientists and engineers in conjunction with industry partners and government research institutions.
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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
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