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Integrating quantum hyperpolarisation in nuclear magnetic resonance systems. This project aims to integrate quantum hyperpolarisation technology into state-of-the-art nuclear magnetic resonance (NMR) systems, potentially boosting the signal by several orders of magnitude. Understanding the structure and function of membrane bound peptides and proteins in cells in their native environments is critical in drug development. However, studying these biomolecules by conventional NMR under ambient cond ....Integrating quantum hyperpolarisation in nuclear magnetic resonance systems. This project aims to integrate quantum hyperpolarisation technology into state-of-the-art nuclear magnetic resonance (NMR) systems, potentially boosting the signal by several orders of magnitude. Understanding the structure and function of membrane bound peptides and proteins in cells in their native environments is critical in drug development. However, studying these biomolecules by conventional NMR under ambient conditions is challenging due to sensitivity limitations. The technology developed by this project will be a significant step forward in NMR and the new science enabled may have far reaching consequences for the study of peptides and proteins of live cells for the development of new drugs and anti-biotics, with direct societal benefits and flow-on economic benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101785
Funder
Australian Research Council
Funding Amount
$424,978.00
Summary
Viewing Chemistry through Diamond: Quantum Sensors for Realtime in situ NMR. This project aims to develop a new analytical method and integrated platform technology for time dependent, in situ monitoring of chemical reactions. The proposed research will capitalise on recent developments made in the field of diamond-based quantum sensing to enable the resolution of chemical species and their concentrations within the timescales associated with many important reaction systems. This project thus ex ....Viewing Chemistry through Diamond: Quantum Sensors for Realtime in situ NMR. This project aims to develop a new analytical method and integrated platform technology for time dependent, in situ monitoring of chemical reactions. The proposed research will capitalise on recent developments made in the field of diamond-based quantum sensing to enable the resolution of chemical species and their concentrations within the timescales associated with many important reaction systems. This project thus expects to generate knowledge in both quantum metrology and physical chemistry. Moreover, the realisation of this technology has significant potential to improve the design and manufacture of important advanced materials, ranging from clean energy production and storage, to pharmaceutical development and drug discovery.Read moreRead less
Quantum phases of matter driven by strong electronic correlations in complex molecular crystals. This project will provide understanding of organic materials where the physical properties are determined by the interactions between electrons rather than by the behaviour of individual electrons (as in the current generation of electronic devices). Such fundamental understanding would allow us to create radical new technologies that might change lives comparably to the benefits that silicon based t ....Quantum phases of matter driven by strong electronic correlations in complex molecular crystals. This project will provide understanding of organic materials where the physical properties are determined by the interactions between electrons rather than by the behaviour of individual electrons (as in the current generation of electronic devices). Such fundamental understanding would allow us to create radical new technologies that might change lives comparably to the benefits that silicon based technologies have brought us in the last few decades. This project will generate fundamental new understanding of the deep physical principles at play in strongly correlated organic molecular materials (with implications for technologies on the timescale of decades).Read moreRead less
A study of ultracold atom interferometry and interactions through high-performance computing. This project involves a design and study of hyper-sensitive machines to detect changes in motion based on using clouds of atoms near absolute zero temperature. Matter at these ultracold temperatures can be harnessed to detect variations of both space and time, enabling novel quantum measurement devices to be built.
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
Quantum effects in photosynthesis: responsible for highly efficient energy transfer or trivial coincidence? Understanding the precise details of the highly efficient energy transfer processes in photosynthesis has the potential to impact the design of efficient solar energy solutions. This project will gain this understanding by exploring the nature of interactions between different components and the significance of quantum mechanics.
Discovery Early Career Researcher Award - Grant ID: DE140101700
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Integrated photonic quantum simulators for quantum chemistry. This project aims to develop the first generation quantum processors specifically designed to efficiently solve problems in quantum chemistry that are intractable on conventional computers. To remove the major limitations that plague current approaches, and achieve devices of unprecedented size and complexity, this project will use photonic technology and integrate, for the first time, all the critical components on a single chip. The ....Integrated photonic quantum simulators for quantum chemistry. This project aims to develop the first generation quantum processors specifically designed to efficiently solve problems in quantum chemistry that are intractable on conventional computers. To remove the major limitations that plague current approaches, and achieve devices of unprecedented size and complexity, this project will use photonic technology and integrate, for the first time, all the critical components on a single chip. These components are single photon sources, processing circuits and single photon detectors. The outputs of this project will have applications ranging from the design of new materials and drugs to determining the results of internet search engines.Read moreRead less
Heavy atoms and ions and precision tests of fundamental physics. This project aims to further the understanding of the structure of heavy atoms through development and application of state-of-the-art many-electron methods. Atomic physics is undergoing a period of rapid growth with a new generation of experiments underway across different areas in fundamental physics. This includes testing particle physics at low energies, opening a new realm of discovery with the synthesis and interrogation of s ....Heavy atoms and ions and precision tests of fundamental physics. This project aims to further the understanding of the structure of heavy atoms through development and application of state-of-the-art many-electron methods. Atomic physics is undergoing a period of rapid growth with a new generation of experiments underway across different areas in fundamental physics. This includes testing particle physics at low energies, opening a new realm of discovery with the synthesis and interrogation of superheavy elements, and the development of atomic clocks of ever-increasing precision. The expected benefit will be to increase capability in fundamental physics tests and in the development of precision atomic instruments.Read moreRead less
Optically induced spin polarisation: the role of electron-vibration interactions. A defect in diamond has applications as a microscopic probe of magnetic fields, as a fluorescence probe of biological systems and for quantum information processing. These capabilities are to be enhanced by a thorough investigation of the intrinsic properties of the defect centre.
Spin detection and control in molecular nanomagnets at surfaces. One fact of computing life is that there's never enough storage. Storing information on single molecules would improve storage density by a factor of 10,000. A promising strategy is to arrange magnetic molecules on a surface, so that their spin can be accessed from one side in read/write operations. While much is known of magnetic molecules in crystals, their behaviour on a surface is still a puzzle. Using mathematical models and s ....Spin detection and control in molecular nanomagnets at surfaces. One fact of computing life is that there's never enough storage. Storing information on single molecules would improve storage density by a factor of 10,000. A promising strategy is to arrange magnetic molecules on a surface, so that their spin can be accessed from one side in read/write operations. While much is known of magnetic molecules in crystals, their behaviour on a surface is still a puzzle. Using mathematical models and synchrotron experiments, the project will explore which combinations of molecules and surfaces exhibit the best magnetic behaviour. The expected results will be crucial for the development of a new generation of high-capacity and high-performing computers.Read moreRead less