Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989127
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of ....A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of option to an existing spectrometer that will broaden its user-base from specialised applications in physics to more general applications in physics, chemistry, materials-science and biology. This additional option provides a totally new way for Australian scientists to study atomic and molecular motions. Read moreRead less
A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a labora ....A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a laboratory prototype of this sensor that is expected to have superior sensitivity and operational capabilities. Thus it will noticeably contribute to practical law enforcement, air quality and environmental monitoring, counter-terrorism, air safety, border security and customs service. It will also lead to further development of nano-optics and nanotechnology in Australia. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100023
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Australian high field electron paramagnetic resonance facility. This project aims to establish Australia’s first a high-field (3 T, 94 GHz) high-field pulse electron paramagnetic resonance (EPR) facility. EPR is a powerful technique to study chemical, biological and materials systems. It represents a sensitive, non-invasive, site-selective spectroscopy for the analysis of both molecular and macroscopic properties. This facility will allow the further development and implementation of new multidi ....Australian high field electron paramagnetic resonance facility. This project aims to establish Australia’s first a high-field (3 T, 94 GHz) high-field pulse electron paramagnetic resonance (EPR) facility. EPR is a powerful technique to study chemical, biological and materials systems. It represents a sensitive, non-invasive, site-selective spectroscopy for the analysis of both molecular and macroscopic properties. This facility will allow the further development and implementation of new multidimensional pulse EPR techniques, enabling domestic and international collaborations with diverse applications in structural biology, solvation science and catalysis.Read moreRead less
Methods for Protein Structure Analysis by Electron Paramagnetic Resonance. This highly interdisciplinary project aims to establish new tools to analyse the structure and motions of proteins that are otherwise difficult to study. A combination of advanced biochemistry, modern magnetic spectroscopy methods, and high-performance computing techniques will be applied to study proteins at physiological concentrations and in complex environments. New techniques will be developed and tested on proteins ....Methods for Protein Structure Analysis by Electron Paramagnetic Resonance. This highly interdisciplinary project aims to establish new tools to analyse the structure and motions of proteins that are otherwise difficult to study. A combination of advanced biochemistry, modern magnetic spectroscopy methods, and high-performance computing techniques will be applied to study proteins at physiological concentrations and in complex environments. New techniques will be developed and tested on proteins of high biochemical or biomedical importance, and the approach will be applied to established drug targets.Read moreRead less
Selectively targeting cancer and infectious disease with fragment-based drug discovery. Finding better compounds as starting points is one of the major challenges for drug discovery research. Fragments are small, weak binding molecules that can be upsized into drug leads with better properties when compared to starting with larger molecules. This project addresses two weaknesses of current fragment based drug discovery (FBDD) methods: first, the limitations associated with screening fragments; a ....Selectively targeting cancer and infectious disease with fragment-based drug discovery. Finding better compounds as starting points is one of the major challenges for drug discovery research. Fragments are small, weak binding molecules that can be upsized into drug leads with better properties when compared to starting with larger molecules. This project addresses two weaknesses of current fragment based drug discovery (FBDD) methods: first, the limitations associated with screening fragments; and second, the quality of commercial fragment libraries. This project anticipates that the findings will establish a commanding role for both mass spectrometry and three-dimensional fragments in advancing FBDD approaches. It also expects to identify fragments with favourable development prospects towards the next generation of therapeutics.Read moreRead less
Novel source of excited metastable atoms for Atom Trap Trace Analysis. This project aims to understand and to control light-induced processes in atoms by using finely shaped and tailored laser pulses, focusing on efficient production of excited metastable atoms. This is critical for efficient Atom Trap Trace Analysis, the most advanced technique for dating ground water and geological samples. Expected outcomes of this project include new and enhanced knowledge of physics of light-matter interact ....Novel source of excited metastable atoms for Atom Trap Trace Analysis. This project aims to understand and to control light-induced processes in atoms by using finely shaped and tailored laser pulses, focusing on efficient production of excited metastable atoms. This is critical for efficient Atom Trap Trace Analysis, the most advanced technique for dating ground water and geological samples. Expected outcomes of this project include new and enhanced knowledge of physics of light-matter interactions, developing an efficient, clean source of excited metastable atoms, and integrating that source into the Australian National Facility for dating geological samples. This should provide significant benefits, such as significant improvement of operational efficiency and productivity of that facility.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100009
Funder
Australian Research Council
Funding Amount
$455,000.00
Summary
Ultra-precision cutting and polishing machines for fabricating high-Q crystalline resonators. The proposed facility will equip Australian researchers with the capability to machine and polish optical crystalline materials down to atomic-level smoothness. The availability of this technology will enable the fabrication of ultra-sensitive metrological sensors, state-of-the-art photonic components, and quantum devices. Precision metrology is an integral component of many industries and it underpins ....Ultra-precision cutting and polishing machines for fabricating high-Q crystalline resonators. The proposed facility will equip Australian researchers with the capability to machine and polish optical crystalline materials down to atomic-level smoothness. The availability of this technology will enable the fabrication of ultra-sensitive metrological sensors, state-of-the-art photonic components, and quantum devices. Precision metrology is an integral component of many industries and it underpins a modern, technically advanced society. With this facility Australian researchers will lead the world in the fabrication of optical crystalline devices for a broad range of industrial and research applications.Read moreRead less
Chemical building block size principles for discovery chemists. This project aims to deliver an innovative platform of new fundamental molecules, and associated design principles that will assist discovery chemists (DCs) to sidestep outdated, caged hydrocarbon chemical building blocks (CHCBBs). The expanding global population places significant challenges on discovery chemistry, driven by an appetite for innovative chemical technologies for societal longevity such as pharmaceuticals, agrichemica ....Chemical building block size principles for discovery chemists. This project aims to deliver an innovative platform of new fundamental molecules, and associated design principles that will assist discovery chemists (DCs) to sidestep outdated, caged hydrocarbon chemical building blocks (CHCBBs). The expanding global population places significant challenges on discovery chemistry, driven by an appetite for innovative chemical technologies for societal longevity such as pharmaceuticals, agrichemicals, and microelectronics. In translating this new CHCBB technology into accessible commodity supply streams, the project hopes to provide DCs with tools to sustain chemical technology evolution in a multitude of key industries that underpin the longevity of society.Read moreRead less
Engineering a nanovaccine for cost-effective influenza poultry vaccination. The project aims to develop a new single-dose, room temperature-stable nanovaccine for cost-effective influenza poultry vaccination. The nanovaccine is based on viral protein assembly modularised to present multiple copies of influenza antigen. Particularly, this project focuses on the engineering of this vaccine manufacturing and formulation for a room temperature-stable vaccine. The resulting engineered vaccine would p ....Engineering a nanovaccine for cost-effective influenza poultry vaccination. The project aims to develop a new single-dose, room temperature-stable nanovaccine for cost-effective influenza poultry vaccination. The nanovaccine is based on viral protein assembly modularised to present multiple copies of influenza antigen. Particularly, this project focuses on the engineering of this vaccine manufacturing and formulation for a room temperature-stable vaccine. The resulting engineered vaccine would play an important role in preventing avian influenza outbreaks, which are currently affecting both developed and developing countries, costing millions of dollars due to the death and culling of infected poultry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989608
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
The Heron Island Climate Change Observatory: An In-Situ Ocean Acidification and Carbonate Chemistry Monitoring Platform. Climate change and ocean acidification are widely recognized as key threats to Australia's natural ecosystems, yet we are currently ill-equipped to respond due to poor knowledge of the scale/nature of the impacts. The Heron Island Climate Change Observatory will establish key infrastructure that will rapidly improve our understanding of the impacts of ocean acidification whic ....The Heron Island Climate Change Observatory: An In-Situ Ocean Acidification and Carbonate Chemistry Monitoring Platform. Climate change and ocean acidification are widely recognized as key threats to Australia's natural ecosystems, yet we are currently ill-equipped to respond due to poor knowledge of the scale/nature of the impacts. The Heron Island Climate Change Observatory will establish key infrastructure that will rapidly improve our understanding of the impacts of ocean acidification which is important to local communities and the nation given that coral reefs support over $6 billion in revenue (and employ 60,000 people) each year. This critically important information is essential to the management and protection of Australia's coral reefs, including the Great Barrier Reef.
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