Special Research Initiatives - Grant ID: SR0354741
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Quantum Many-Body Systems Network: Breakthrough Science and Frontier Technologies. This Initiative will bring together leading researchers with complementary expertise in mathematics and the enabling sciences to form a Network fostering world leading fundamental research and innovation in quantum many-body systems. The collaborative effort between mathematicians with powerful and sophisticated new techniques and physicists and chemists with deep insight into the challenges and opportunities of t ....Quantum Many-Body Systems Network: Breakthrough Science and Frontier Technologies. This Initiative will bring together leading researchers with complementary expertise in mathematics and the enabling sciences to form a Network fostering world leading fundamental research and innovation in quantum many-body systems. The collaborative effort between mathematicians with powerful and sophisticated new techniques and physicists and chemists with deep insight into the challenges and opportunities of the quantum realm will lead to breakthrough science of vital importance to the development of frontier technologies in Australia. This Network will also place a strong emphasis on research training, the mentoring of early career researchers and establishing collaborations with leading international research groups and networks.
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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
Inception of a Practical, Biomimetic, Flexible Photovoltaic Device. This project will design and synthesise new, complex, functional organic molecules and assemble them to create a new type of photovoltaic cell. This device will be designed using biomimetic principles to emulate many of the efficient photosynthetic solar energy conversion processes that occur in plants. A key feature is that near atomic-level control will be achieved over the entire device structure, facilitating the establish ....Inception of a Practical, Biomimetic, Flexible Photovoltaic Device. This project will design and synthesise new, complex, functional organic molecules and assemble them to create a new type of photovoltaic cell. This device will be designed using biomimetic principles to emulate many of the efficient photosynthetic solar energy conversion processes that occur in plants. A key feature is that near atomic-level control will be achieved over the entire device structure, facilitating the establishment of a clear path towards the commercial production of solar cells that are simultaneously highly efficient, long lasting, flexible, and very cheap to manufacture.Read moreRead less
Special Research Initiatives - Grant ID: SR0354591
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Ma ....New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Mapping, Molecular and Cluster computations and Powder Diffraction for fundamental research, biomedical and industrial applications. These breakthroughs will be invaluable for the development of Australia's major research infrastructure (the synchrotron, electron microscopes, and the research reactor). This will develop Australian expertise and collaboration at the cutting edge of a variety of interdisciplinary fields.Read moreRead less
Quantum algorithms for quantum chemistry. This project aims to develop more efficient algorithms to simulate quantum chemistry on quantum computers. Quantum computers have the potential to perform calculations that would be intractable for even the largest supercomputers, but need to be programmed in a radically different way to achieve this speed. One of the most important applications of quantum computers is to simulate quantum mechanics to predict the properties of molecules and materials, an ....Quantum algorithms for quantum chemistry. This project aims to develop more efficient algorithms to simulate quantum chemistry on quantum computers. Quantum computers have the potential to perform calculations that would be intractable for even the largest supercomputers, but need to be programmed in a radically different way to achieve this speed. One of the most important applications of quantum computers is to simulate quantum mechanics to predict the properties of molecules and materials, and thereby design them. Current quantum algorithms are very resource intensive, making them impractical for the foreseeable future. The expected outcome of this project is to provide much more efficient algorithms that can be run on quantum processors in the near future.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668467
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
A large memory, high performance computing system for the ac3 Research Consortium. The installation of this new supercomputing facility is an important addition to the nation's foundation research infrastructure, and a further key system in the national computational grid. Of particular importance to research groups in NSW is the much needed boost in computational research and research training capacity that it will provide, enabling world leading research teams to continue their ground breakin ....A large memory, high performance computing system for the ac3 Research Consortium. The installation of this new supercomputing facility is an important addition to the nation's foundation research infrastructure, and a further key system in the national computational grid. Of particular importance to research groups in NSW is the much needed boost in computational research and research training capacity that it will provide, enabling world leading research teams to continue their ground breaking work in what is an increasingly competitive international environment. Much of the research to be supported lies in areas of national priority, including frontier technologies and Australian environmental sustainability.Read moreRead less
Enhancing control capabilities and robustness in the engineering of quantum ensembles. This project will develop novel fundamental quantum ensemble control approaches and methodologies that are important to emerging quantum technology. The expected outcomes are new theories and powerful quantum control algorithms which will play an important role in establishing Australian industries based on quantum technology.
A priori simulations of condensed-phase molecular spectroscopy. Molecular spectroscopy is used to probe phenomena in chemistry, biology, and nanoscience, but interpretation of the results often requires simulation of the spectra. While most applications involve condensed phases, until recently most accurate computations could only be performed for gas-phase molecules. Last year, a major advance has started to emerge, stemming from the production of analytical atomic forces for molecules in exc ....A priori simulations of condensed-phase molecular spectroscopy. Molecular spectroscopy is used to probe phenomena in chemistry, biology, and nanoscience, but interpretation of the results often requires simulation of the spectra. While most applications involve condensed phases, until recently most accurate computations could only be performed for gas-phase molecules. Last year, a major advance has started to emerge, stemming from the production of analytical atomic forces for molecules in excited states obtained using density-functional theory. We will adapt these methods to solve fundamental chemical problems involving the intermolecular interactions of molecules that have absorbed light- in particular, hydrogen-bonding interactions in water, studying, eg., chemical solvation and optical damage to DNA.Read moreRead less
Engineering quantum matter atom-by-atom. This project aims to engineer artificial quantum matter that mimics conventional materials in the most direct way to date, by building them atom-by-atom. The ability to directly control interactions and measure correlations in quantum matter at the atomic scale could provide the most direct method to date to tailor the properties of an entirely new class of technologically relevant quantum materials. The peculiar electronic and magnetic properties of such ....Engineering quantum matter atom-by-atom. This project aims to engineer artificial quantum matter that mimics conventional materials in the most direct way to date, by building them atom-by-atom. The ability to directly control interactions and measure correlations in quantum matter at the atomic scale could provide the most direct method to date to tailor the properties of an entirely new class of technologically relevant quantum materials. The peculiar electronic and magnetic properties of such materials put them in a leading position to revolutionise energy, information, and communication technologies.Read moreRead less
Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cel ....Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cell, develop the synthesis method, synthesize arrays of the memory cells, and develop new molecular addressing technologies.Read moreRead less