Gamma-ray burst astronomy in the Swift era and beyond. The study of gamma-ray bursts is one of the most active and exciting fields in astrophysics, and touches on subjects that are of interest to all humans: e.g., to what extent was life on Earth shaped by cataclysmic explosions in our Galaxy? Australia's ROTSE-III telescope is the only facility in the southern hemisphere capable of rapidly (within 10 seconds) finding optical light from gamma-ray bursts. It will provide Australian astronomers ....Gamma-ray burst astronomy in the Swift era and beyond. The study of gamma-ray bursts is one of the most active and exciting fields in astrophysics, and touches on subjects that are of interest to all humans: e.g., to what extent was life on Earth shaped by cataclysmic explosions in our Galaxy? Australia's ROTSE-III telescope is the only facility in the southern hemisphere capable of rapidly (within 10 seconds) finding optical light from gamma-ray bursts. It will provide Australian astronomers with a competitive advantage in this high-profile field. The project will involve and inspire some of our best physics and engineering students.Read moreRead less
Structure-Activity Relationships in Silicon-based Photovoltaics Through Atomic Scale Microscopy. This project aims to develop new design principles for silicon-based photovoltaics (PVs) through a comprehensive study of atomic-scale structures and phenomena in PV materials. The development of more efficient photovoltaic materials is of major global importance, given the pressing need for clean and renewable sources of energy. Australia has international leadership in developing solar cell technol ....Structure-Activity Relationships in Silicon-based Photovoltaics Through Atomic Scale Microscopy. This project aims to develop new design principles for silicon-based photovoltaics (PVs) through a comprehensive study of atomic-scale structures and phenomena in PV materials. The development of more efficient photovoltaic materials is of major global importance, given the pressing need for clean and renewable sources of energy. Australia has international leadership in developing solar cell technologies, and the ideal natural environment to exploit these technologies. The fundamental insights derived in this project, such as detailed 3D maps of dopant distributions at the atomic scale, will bolster Australia's international reputation in the field and provide better control in the design of PV devices. Read moreRead less
Radiation detectors to better understand ion interactions. This project aims to build a Heavy Ion Therapy Research and Treatment Centre in Australia. Understanding how ions interact with matter and their radiobiological effectiveness (RBE) is important. The project will introduce an Australian detector technology platform to research ion interaction physics and their RBE. It will develop radiation detectors for ion measurement with a wide energy range, including a practical RBE quality assurance ....Radiation detectors to better understand ion interactions. This project aims to build a Heavy Ion Therapy Research and Treatment Centre in Australia. Understanding how ions interact with matter and their radiobiological effectiveness (RBE) is important. The project will introduce an Australian detector technology platform to research ion interaction physics and their RBE. It will develop radiation detectors for ion measurement with a wide energy range, including a practical RBE quality assurance tool with submillimetre spatial resolution. The proposed Australian radiation detection technology is expected to improve understanding of the scientific mechanisms underpinning the radiobiological effectiveness of heavy ion radiation.Read moreRead less
New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray s ....New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray scientists of tomorrow, whose expertise will allow Australia to capitalize on its investment in the Australian Synchrotron.Read moreRead less
Development of direct-write focussed electron beam processing techniques for nano-fabrication applications. The burgeoning disciplines of nanotechnology and biotechnology have the potential to deliver breakthroughs in science and engineering that will revolutionise many aspects of everyday life. Progress in these emerging fields, however, requires parallel advances in the techniques used to fabricate, manipulate and characterise materials and devices at the nanoscale. This project will provide s ....Development of direct-write focussed electron beam processing techniques for nano-fabrication applications. The burgeoning disciplines of nanotechnology and biotechnology have the potential to deliver breakthroughs in science and engineering that will revolutionise many aspects of everyday life. Progress in these emerging fields, however, requires parallel advances in the techniques used to fabricate, manipulate and characterise materials and devices at the nanoscale. This project will provide such enabling tools and fill a major gap in the research infrastructure urgently required by these exciting new technologies.Read moreRead less
High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high- ....High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high-energy experiments. This project will satisfy that role. The application of particle detector expertise to state-of-the-art X-ray imaging detectors for the Australian Synchrotron and medical imaging is a perfect example of fundamental science tools applied to other fields. Australian Synchrotron experiments stand to gain much.Read moreRead less
Frontier Experiments in High Energy Physics. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experiments probe two of the mo ....Frontier Experiments in High Energy Physics. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experiments probe two of the most significant questions in fundamental physics: what is the origin of mass, and why do we live in a universe composed of matter rather than antimatter?
Read moreRead less
Frontier Experiments in High Energy Physics. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. It will also search for particles to explain Dark Matter, which makes up 25% ....Frontier Experiments in High Energy Physics. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. It will also search for particles to explain Dark Matter, which makes up 25% of our Universe. ATLAS will search for undiscovered laws of nature to help us unify our understanding of the forces of nature. Excellent training and enhhancement of public interest, international cooperation and networking, and national pride will be provided by this project.Read moreRead less
Electro-active and migratory peptides in lipid bilayers: NMR and biophysical studies. All living things are characterized by the separation of inner space from the surrounding medium by a self-assembling membrane. Selective entry and exit of water, ions and solutes is a defining feature of each type of cell. Some proteins sense the voltage difference across the cell membrane and open or close in response to voltage changes. Others, like bacterial toxins assemble in the membrane as pores, while o ....Electro-active and migratory peptides in lipid bilayers: NMR and biophysical studies. All living things are characterized by the separation of inner space from the surrounding medium by a self-assembling membrane. Selective entry and exit of water, ions and solutes is a defining feature of each type of cell. Some proteins sense the voltage difference across the cell membrane and open or close in response to voltage changes. Others, like bacterial toxins assemble in the membrane as pores, while other peptides migrate across the membrane piggy-backing their peptide cargo. The aim is to understand the molecular mechanisms in examples of these membrane-active peptides and proteins with a view to enabling rational intervention into their operation in situ in normal and disease states.Read moreRead less
NMR studies of membrane proteins and peptides in novel amphiphilic mesophases. Membrane proteins are the next frontier in structural biology. Our goal is the structural and mechanistic characterization of the proteins and peptides from platypus venom and a cardiac potassium ion channel, HERG, that has a particular role in the suppression of cardiac arrhythmias. To do this we will refine and develop methods using amphiphilic mesophases and micelles and state-of-the-art NMR spectroscopy. Electrop ....NMR studies of membrane proteins and peptides in novel amphiphilic mesophases. Membrane proteins are the next frontier in structural biology. Our goal is the structural and mechanistic characterization of the proteins and peptides from platypus venom and a cardiac potassium ion channel, HERG, that has a particular role in the suppression of cardiac arrhythmias. To do this we will refine and develop methods using amphiphilic mesophases and micelles and state-of-the-art NMR spectroscopy. Electrophysiological analysis of ion channels and interactions with toxins will relate NMR structures to function. The NMR methodologies we develop will have broad applicability to membrane proteins in general.
Read moreRead less