Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100076
Funder
Australian Research Council
Funding Amount
$155,000.00
Summary
The first Australian high pressure Synchrotron facility for geoscience research. In high-pressure mineral physics and chemistry, mineral properties, stress-strain relationships and processes like partial melting are applied to geophysical research about the deep Earth. This project will provide a large volume, high pressure capability at the Australian Synchrotron which will allow these mineral properties to be measured under conditions which simulate the deep earth.
Geometry variation and coupling of single gold nanorods for highly efficient, one-photon and two-photon luminescent markers. The search for highly efficient, non toxic and stable luminescence markers is continuing for many applications in bio- and nano-photonics. The project's study of gold nanorod luminescence is designed to fundamentally understand and control the luminescence quantum efficiency of gold nanorod and ultimately unveil its potential as the future marker.
Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multi ....Multi-colour ultrashort soft X-ray pulses. This project aims to create multi-colour, ultrashort, highly coherent, bright pulses of soft X-rays based on high-harmonic generation in a table-top multiple-section gas cell. Studying multi-electronic and non-adiabatic processes and other fundamental aspects such as multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules is a major challenge in current ultrafast photochemistry research. This project will use multiple driving pulses with different carrier frequencies to control the spectral properties and time delay of the pulses. It will use the soft X-ray source to develop an ideal platform for studying multi-electronic and non-adiabatic processes, multi-electronic correlations and non-Born-Oppenheimer vibronic couplings in complex molecules. This is expected to advance materials science, paving the way to soft X-ray technologies.Read moreRead less
Locating Atoms by Observing Crystallographic Phase. Atomic structures are determined by measuring how they scatter radiation. However half of the necessary information, the crystallographic phase, cannot be measured from the scattered intensity. For a century the only option has been to deduce the phase via the statistical analysis of thousands of intensity measurements. This project aims to develop a method to determine atomic structures from the direct observation of phase. From a handful of o ....Locating Atoms by Observing Crystallographic Phase. Atomic structures are determined by measuring how they scatter radiation. However half of the necessary information, the crystallographic phase, cannot be measured from the scattered intensity. For a century the only option has been to deduce the phase via the statistical analysis of thousands of intensity measurements. This project aims to develop a method to determine atomic structures from the direct observation of phase. From a handful of observations and no formal measurements, atoms can be located with picometre precision. It is predicted that this method will be direct, rapid and unequivocal, sensitive to light atoms and applicable to nanostructures, which will represent a paradigm shift in crystallography.Read moreRead less
The Quantum Dot SPASER. Can we replace electrons with photons in future computers? This project provides two steps toward this goal. By combining advanced materials with ultra-small metallic structures, a new nano-sized form of a laser, called the spaser will be realised. Furthermore, a key component of a computer, a nanoscale modulator, will be demonstrated.
Chemical mapping of materials at the atomic scale. This project will develop a method for measuring the chemical composition of technologically important nanomaterials. This capability will provide Australian scientists with an advanced method for the characterisation of materials and will help them to develop new and better materials for future applications.
Ultra-fast serialised all optical image processing: addressing the electronic bottleneck in the world's fastest camera. Serial time encoded amplified microscopy can capture over a million frames per second. At this rate, a megapixel image would fill a terabyte hard disk in a second. We will use photonics to condense and manipulated the video stream so that only the important features are 'seen', making it practical to process and store on a computer.
Australian Laureate Fellowships - Grant ID: FL100100117
Funder
Australian Research Council
Funding Amount
$2,713,582.00
Summary
Molecular Plasmonics - From Single Electrons to Quantum Catalysis and Optical Logic Gates. After a decade of basic research, Nanotechnology is now entering its most disruptive phase. New nanoscale phenomena are being exploited and converted into viable technologies. Plasmonics - the manipulation of light using metal nanostructures - is one of the most promising of these. Plasmonics will enable scientists to achieve optical computing, reach higher data storage densities, and synthesize better cat ....Molecular Plasmonics - From Single Electrons to Quantum Catalysis and Optical Logic Gates. After a decade of basic research, Nanotechnology is now entering its most disruptive phase. New nanoscale phenomena are being exploited and converted into viable technologies. Plasmonics - the manipulation of light using metal nanostructures - is one of the most promising of these. Plasmonics will enable scientists to achieve optical computing, reach higher data storage densities, and synthesize better catalysts. Other applications include bio-sensing and rapid pathogen detection. To realise these potential outcomes, a leading international cluster focussing on plasmonics will be set up and this cluster will link state-of-the-art materials science, instrumentation and theory.Read moreRead less
Nanoparticle inks for electronic applications employing nanostructured thin-films. The development of next-generation technologies requires careful engineering of materials at the nanoscale. Using nanoparticle inks, many of the engineering difficulties which exist at these length scales can be overcome, thus allowing for technologies such as thin-film solar cells to become cheaper and more efficient.