Quantum Coherences in Artificial Light-Harvesting Complexes. The aim of this project is to relate efficient energy and electron transfer processes in molecular materials to the presence of quantum coherences. The ongoing debate on the role of quantum coherences in the efficient harvesting of sunlight of photosynthesis appears to be limited by the complexity of the biological systems and a lack of high instrumentation sensitivity. Using molecular systems and a highly sensitive method, this projec ....Quantum Coherences in Artificial Light-Harvesting Complexes. The aim of this project is to relate efficient energy and electron transfer processes in molecular materials to the presence of quantum coherences. The ongoing debate on the role of quantum coherences in the efficient harvesting of sunlight of photosynthesis appears to be limited by the complexity of the biological systems and a lack of high instrumentation sensitivity. Using molecular systems and a highly sensitive method, this project aims to reveal the effects of molecular conformation and geometry on quantum coherences. The outcome is likely to improve our understanding of nature's remarkable ability to harvest energy efficiently from the sun and foster new approaches that increase the efficiency of light-harvesting systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100131
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Laser facility for ultra-sensitive molecular characterisation. Lasers are indispensable tools for the characterization and photochemical modification of molecular systems. Powerful lasers produce intense bursts of light across the electromagnetic spectrum, from the infrared to the ultraviolet. This versatility allows chemists to observe the dynamical behaviour of single molecules on ultra-fast timescales, to probe the shape of molecules relevant to the action of therapeutic drugs, to explore the ....Laser facility for ultra-sensitive molecular characterisation. Lasers are indispensable tools for the characterization and photochemical modification of molecular systems. Powerful lasers produce intense bursts of light across the electromagnetic spectrum, from the infrared to the ultraviolet. This versatility allows chemists to observe the dynamical behaviour of single molecules on ultra-fast timescales, to probe the shape of molecules relevant to the action of therapeutic drugs, to explore the characteristics of molecules found in space, and to initiate laser-activated chemical processes in microscopic dimensions to modify sensor surfaces. The proposed laser facility will enable progress in these areas and will help maintain Australia's research edge in nanotechnology and biotechnology.
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Laser spectroscopy of functional molecules. Frontier techniques of molecular laser spectroscopy and mass spectrometry will be developed and deployed to investigate the structure and function of molecules that underpin biological processes, drugs, and single molecule devices, including molecular motors, molecular switches, and energy harvesting systems.
Getting the drift - new frontiers in ion spectroscopy. This project will develop and harness ultra-sensitive techniques to understand the action of photo-active molecules involved in human vision, molecular motors and molecular memory. The new techniques will also help explore and exploit the properties of carbon and silicon nanoparticles, and may assist detection of exotic molecules in space.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100051
Funder
Australian Research Council
Funding Amount
$755,000.00
Summary
Ultrafast Laser Spectroscopy Facility. The Ultrafast Laser Spectroscopy Facility will provide a comprehensive range of new spectroscopic techniques that cover all energies (from the ultraviolet to infrared regions of the spectrum) and timescales relevant to the absorption, emission and transformation of light in advanced photo-active materials. Expected outcomes and benefits are more efficient light harvesting, lighting and optical sensing processes; control over light-induced activity in new m ....Ultrafast Laser Spectroscopy Facility. The Ultrafast Laser Spectroscopy Facility will provide a comprehensive range of new spectroscopic techniques that cover all energies (from the ultraviolet to infrared regions of the spectrum) and timescales relevant to the absorption, emission and transformation of light in advanced photo-active materials. Expected outcomes and benefits are more efficient light harvesting, lighting and optical sensing processes; control over light-induced activity in new materials, and enhanced chemical reactivity. This will provide a platform to enhance capacity in materials characterisation, and will increase institutional and cross-disciplinary collaborations involving Universities, defence organisations and industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100158
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Supercontinuum fibre laser consortium for the chemical and materials sciences. A supercontinuum fibre laser facility will be established across nodes at The University of Adelaide and The University of Melbourne, and used to probe the chemical basis of photosynthesis, explore the properties of organic solar cell materials and biomaterials, develop efficient metal catalysts, and detect metal vapours in gases.
Discovery Early Career Researcher Award - Grant ID: DE200101578
Funder
Australian Research Council
Funding Amount
$393,116.00
Summary
Quantitative structure-property relations for molecular crystals. Most of the known molecular compounds exist in crystalline form, and their stability and properties depend upon the structure and interactions in crystals. This project aims to develop methods in the field of quantum crystallography to accurately estimate the electronic properties of molecular crystals, their stability, and associated energetics. The outcomes will be directly applicable in the design of new solid-state forms of ph ....Quantitative structure-property relations for molecular crystals. Most of the known molecular compounds exist in crystalline form, and their stability and properties depend upon the structure and interactions in crystals. This project aims to develop methods in the field of quantum crystallography to accurately estimate the electronic properties of molecular crystals, their stability, and associated energetics. The outcomes will be directly applicable in the design of new solid-state forms of pharmaceutical drugs with enhanced solubility and efficacy and hence reduced drug dosage. Understanding the electronic properties in molecular semiconductor crystals, and the strategies to tune and control these properties will contribute to future generation electronic device material manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100151
Funder
Australian Research Council
Funding Amount
$302,154.00
Summary
Near infrared imaging and spectroscopy facility. This project will establish a cutting-edge optical microscopy platform using light just beyond our vision, in the near-infrared. Recent developments in near-infrared camera technology have opened up new opportunities for applications in this under-explored spectral region. Expected outcomes include the development of new methods for harvesting near-infrared sunlight and for photocatalysis of solar fuels, new biomimetic coatings for thermal managem ....Near infrared imaging and spectroscopy facility. This project will establish a cutting-edge optical microscopy platform using light just beyond our vision, in the near-infrared. Recent developments in near-infrared camera technology have opened up new opportunities for applications in this under-explored spectral region. Expected outcomes include the development of new methods for harvesting near-infrared sunlight and for photocatalysis of solar fuels, new biomimetic coatings for thermal management, new security signatures invisible to the naked eye, new materials for phototherapy, and improved techniques for imaging biological samples. It will benefit Australian renewable energy, security, building, and biomedical industries, and train our next generation of optical science researchers.Read moreRead less
Advanced functional properties in metal-organic frameworks. The design and construction of advanced nanomaterials is a key step in the push towards more efficient energy systems and smarter technologies. Through the strategic assembly of new classes of molecular nanomaterials this project will lead to important fundamental advances in nanoscience and will underpin a range of new high-level technologies.
Functional molecular nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards more efficient energy systems and smarter technologies. Through the strategic assembly of new classes of molecular nanomaterials, this project will lead to important fundamental advances in nanoscience and will underpin a range of new high-level technologies.