First Principles Design of Second-Generation Protein Stains. Proteomics is an emerging technology which has the potential to revolutionize modern biology and medicine. Extremely sensitive protein stains are a key proteomics technology, and in conjunction with gel electrophoresis, they facilitate the rapid and quantitative detection of all polypeptides in a cell. However, the tools of proteomics must rapidly advance (cheaper, greater sensitivity, more reliable, safer to handle) before the techn ....First Principles Design of Second-Generation Protein Stains. Proteomics is an emerging technology which has the potential to revolutionize modern biology and medicine. Extremely sensitive protein stains are a key proteomics technology, and in conjunction with gel electrophoresis, they facilitate the rapid and quantitative detection of all polypeptides in a cell. However, the tools of proteomics must rapidly advance (cheaper, greater sensitivity, more reliable, safer to handle) before the technology can mature to the stage where its full potential is realized. We will enable the evolution of proteomics by devising second generation fluorescent protein stains, using the environmentally-friendly natural product, epicocconone, as our design platform.Read moreRead less
Persistent Triplet Carbenes. Viable or Not? Triplet carbenes have significant potential real world applications, such as in modern electronics. However, they are highly reactive (lifetimes typically < 1 day), and this has stymied their development. Can I design so called persistent triplet-carbenes, which have significant lifetimes? I will try to using computer chemistry. In doing so, I will provide synthetic chemists with 'high-value' targets for preparation, hence saving tax dollars and minimi ....Persistent Triplet Carbenes. Viable or Not? Triplet carbenes have significant potential real world applications, such as in modern electronics. However, they are highly reactive (lifetimes typically < 1 day), and this has stymied their development. Can I design so called persistent triplet-carbenes, which have significant lifetimes? I will try to using computer chemistry. In doing so, I will provide synthetic chemists with 'high-value' targets for preparation, hence saving tax dollars and minimizing creation of environmentally damaging waste. Read moreRead less
Many-body problems. The discovery of new superheavy elements, chemical evolution of the Universe, nuclear reactions deep under the Coulomb barrier in nuclear reactors, in stars and during the Big Bang Nucleosynthesis, accuracy of precise atomic clocks, consistency of the Standard Model in strong fields are among the most vital problems of modern science. This project suggests several new ideas in these areas, which are based on knowledge accumulated in different research fields. The outcomes of ....Many-body problems. The discovery of new superheavy elements, chemical evolution of the Universe, nuclear reactions deep under the Coulomb barrier in nuclear reactors, in stars and during the Big Bang Nucleosynthesis, accuracy of precise atomic clocks, consistency of the Standard Model in strong fields are among the most vital problems of modern science. This project suggests several new ideas in these areas, which are based on knowledge accumulated in different research fields. The outcomes of the research will help Australia to build up a "critical mass" of scientific expertise, which is necessary to place and keep it among leaders in these frontier areas of physics, and to train the next generation of experts in these fields.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347499
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the ....Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the next generation of computational research problems. In doing so, it will underpin innovation by world ranking groups in diverse fields such as photonics, complex/intelligent systems, nanotechnology, bioinformatics, quantum physics and chemistry, engineering, and environmental modelling.Read moreRead less
The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of ....The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of such rational materials design impact on the development of new, safer, more efficient, reusable materials in chemical, engineering, electronic and biological applications. Read moreRead less
Quantum chemical methods: From wavefunction to density functional theory. This project aims to address a major challenge in quantum chemistry - how to extend the applicability of high-level quantum chemical methods to larger molecules. High-level quantum chemical methods can consistently obtain reliable thermochemical and kinetic data, but due to their steep computational cost, they are only applicable to relatively small molecules. The project expects to introduce new concepts and methodologies ....Quantum chemical methods: From wavefunction to density functional theory. This project aims to address a major challenge in quantum chemistry - how to extend the applicability of high-level quantum chemical methods to larger molecules. High-level quantum chemical methods can consistently obtain reliable thermochemical and kinetic data, but due to their steep computational cost, they are only applicable to relatively small molecules. The project expects to introduce new concepts and methodologies that build on recent breakthrough research in the field of ab initio computational chemistry. The new methods should be capable of energetic predictions of unprecedented accuracy for relatively large systems across the Periodic Table and will be used for the development of better density functional theory procedures.Read moreRead less
Neutron Scattering in Biology. Australia's Replacement Research Reactor will be a world-class neutron source, and represents the country's largest single investment in scientific research infrastructure. It is now essential to stimulate its production of high-quality research in materials science, chemistry and biology. The applicant is a recognised world leader in the field of neutron scattering research, particularly in biology. His presence in the Bragg Institute, which manages the neutron ....Neutron Scattering in Biology. Australia's Replacement Research Reactor will be a world-class neutron source, and represents the country's largest single investment in scientific research infrastructure. It is now essential to stimulate its production of high-quality research in materials science, chemistry and biology. The applicant is a recognised world leader in the field of neutron scattering research, particularly in biology. His presence in the Bragg Institute, which manages the neutron scattering instruments on the reactor, will provide direction and impetus for the science that will be initiated there, advancing applications in materials science, medicine and biotechnology.Read moreRead less
Free Radicals in Chemistry and Biology: A Computational Quantum Chemistry Investigation. This proposal aims to carry out state-of-the-art chemistry research using computers rather than traditional laboratory techniques. Free radicals, which have widespread importance in the multibillion dollar polymer and health industries, form the centrepiece of the proposal. These are highly reactive substances that are difficult to study by conventional experimental techniques but ideal to study using compu ....Free Radicals in Chemistry and Biology: A Computational Quantum Chemistry Investigation. This proposal aims to carry out state-of-the-art chemistry research using computers rather than traditional laboratory techniques. Free radicals, which have widespread importance in the multibillion dollar polymer and health industries, form the centrepiece of the proposal. These are highly reactive substances that are difficult to study by conventional experimental techniques but ideal to study using computers. The increased understanding of free radicals that will stem from this research may help in dealing with ageing, and afflictions such as hardening of the arteries and vitamin B12 deficiency. It will also result in the training at the highest level of new generations of chemists in this exciting field of "chemistry with computers".Read moreRead less
Computational Quantum Chemistry Study of Molecular Structures, Stabilities and Reactions. Computational quantum chemistry is revolutionizing the study and practice of chemistry. We will use state-of-the-art computer calculations to investigate chemical structures, stabilities and reactions, particularly for free radicals. Radicals are of great importance in chemistry, biology and polymer science, but are difficult to study experimentally. We will use the computer calculations to determine how ....Computational Quantum Chemistry Study of Molecular Structures, Stabilities and Reactions. Computational quantum chemistry is revolutionizing the study and practice of chemistry. We will use state-of-the-art computer calculations to investigate chemical structures, stabilities and reactions, particularly for free radicals. Radicals are of great importance in chemistry, biology and polymer science, but are difficult to study experimentally. We will use the computer calculations to determine how to make radicals more stable, how they react to produce polymers, how they cause damage to proteins, and how they are involved in helping vitamin B12 make reactions go faster. We will create new methodologies in order to reliably achieve these goals.Read moreRead less
Hydrogen Bonding, Hydrogen Transfer, Hydrogenation and Hydrogenolysis: A Computational Quantum Chemistry Investigation. This proposal aims to carry out state-of-the-art chemistry research using computer modelling rather than traditional laboratory methods. The computer calculations are directed towards designing catalysts that will provide more efficient ways to convert environmentally harmful carbon dioxide to a valuable chemical fuel methanol, and to convert toxic polychlorinated hydrocarbon ....Hydrogen Bonding, Hydrogen Transfer, Hydrogenation and Hydrogenolysis: A Computational Quantum Chemistry Investigation. This proposal aims to carry out state-of-the-art chemistry research using computer modelling rather than traditional laboratory methods. The computer calculations are directed towards designing catalysts that will provide more efficient ways to convert environmentally harmful carbon dioxide to a valuable chemical fuel methanol, and to convert toxic polychlorinated hydrocarbon wastes to benign products. The increased understanding of free radicals that will stem from this research may ultimately help in dealing with problems associated with heart disease, some forms of cancer and vitamin B12 deficiency. New generations of chemists will be trained at the highest level in this burgeoning field of computational chemistry.Read moreRead less