Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100124
Funder
Australian Research Council
Funding Amount
$538,590.00
Summary
An Advanced Ultrafast Laser Spectroscopy Facility in Queensland. The project aims to establish a world-class ultrafast laser spectroscopy facility to investigate how molecules interact with visible or ultraviolet light. Light-matter interactions are key to energy generation in nature through photosynthesis as well as everyday technologies including optical communications and displays. This project expects to generate new knowledge in on how light interacts with matter at the molecular level. Exp ....An Advanced Ultrafast Laser Spectroscopy Facility in Queensland. The project aims to establish a world-class ultrafast laser spectroscopy facility to investigate how molecules interact with visible or ultraviolet light. Light-matter interactions are key to energy generation in nature through photosynthesis as well as everyday technologies including optical communications and displays. This project expects to generate new knowledge in on how light interacts with matter at the molecular level. Expected outcomes of the ultrafast spectroscopic measurements will be understanding the fate of light absorbed by or generated in different materials. Application of the knowledge gained will enable the design of materials for more efficient technologies such as solar cells, lighting, and sensors.Read moreRead less
Electronic-vibrational spectroscopy: A new probe for structure and function. This project aims to solve a major challenge in ultrafast spectroscopy: to identify and quantify competing reaction pathways in complex photochemical systems. Ultrafast Spectroscopy provides information on excited-state processes of photochemical reactions, however, unravelling heterogeneous systems with competing parallel processes remains difficult. Multidimensional electronic-vibrational spectroscopy, sensitive to el ....Electronic-vibrational spectroscopy: A new probe for structure and function. This project aims to solve a major challenge in ultrafast spectroscopy: to identify and quantify competing reaction pathways in complex photochemical systems. Ultrafast Spectroscopy provides information on excited-state processes of photochemical reactions, however, unravelling heterogeneous systems with competing parallel processes remains difficult. Multidimensional electronic-vibrational spectroscopy, sensitive to electronic dynamics and molecular structure, is expected to overcome this barrier. This new level of detail will profoundly enhance our understanding of energy and chemical conversion in complex systems and will reveal design targets for optimising next-generation light-energy harvesting, conducting, and emitting materials.Read moreRead less
All-solid-state: new hybrid materials for next-generation lithium batteries. The aim of the project is an economically viable design for “all-solid-state” rechargeable batteries. Eliminating organic liquid electrolytes from lithium-ion batteries will dramatically increase safety, range of operating conditions, lifetimes, and energy density. The key technical challenge is keeping solid-solid interfaces intact over thousands of charge/discharge cycles. We will address this by inserting inorganic i ....All-solid-state: new hybrid materials for next-generation lithium batteries. The aim of the project is an economically viable design for “all-solid-state” rechargeable batteries. Eliminating organic liquid electrolytes from lithium-ion batteries will dramatically increase safety, range of operating conditions, lifetimes, and energy density. The key technical challenge is keeping solid-solid interfaces intact over thousands of charge/discharge cycles. We will address this by inserting inorganic interfacial layers that change smoothly from hard ceramic to flexible glass and back again, through rigorous chemical design and synthetic control. This will reduce the stress that causes mechanical failure, while increasing chemical stability so that the latest generation of high-power electrodes can be brought into service.Read moreRead less
Quantitative multidimensional optical spectroscopy: revealing dynamics and structure in complex condensed matter systems. Understanding how quantum mechanics affects photosynthesis and how it can cause interactions between distant nanostructures are intriguing problems that may be of great significance for future smart technologies. This project will gain unprecedented insight into these processes using a novel technique to identify and resolve the mechanisms responsible.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100137
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Femtosecond broad wavelength range laser facility. This facility will provide a unique source of ultra-short laser pulses spanning the X-ray to the infrared regions. It will provide a powerful coherent X-ray source that will position Australia at the forefront of coherent imaging science and the ability to perform ultrafast infrared spectroscopic measurements.
Smart Molecular Materials for Sensors, Displays and Nanodevices. The aims of this project are to synthesise new smart molecular materials and elucidate the chemical origin of the physical properties they exhibit. Exposure of these transition metal-based compounds to heat or light will induce changes in colour and magnetic behaviour, affording potential roles as the smallest possible electronic components or addressable entities for high density data storage. It is expected that the materials wil ....Smart Molecular Materials for Sensors, Displays and Nanodevices. The aims of this project are to synthesise new smart molecular materials and elucidate the chemical origin of the physical properties they exhibit. Exposure of these transition metal-based compounds to heat or light will induce changes in colour and magnetic behaviour, affording potential roles as the smallest possible electronic components or addressable entities for high density data storage. It is expected that the materials will also exhibit tunable thermochromic and photochromic properties, which are important for applications in photoresponsive devices or temperature sensors. The structure-function relationships determined will inform the development of molecular materials for future nanodevices, sensors or displays.Read moreRead less
Double resonance spectroscopy for astrochemistry. We will use advanced laser techniques to probe simulated astrophysical environments with a view to identifying molecules in space. The types of molecules under study are also of direct relevance to other fields such as combustion, and will reveal details of the chemistry of pollution and atmospheres.
Discovery Early Career Researcher Award - Grant ID: DE120100467
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Unravelling the intrinsic structure and stability of multiply charged anions in the gas-phase using photoelectron spectroscopy and mass spectrometry. Molecules possessing multiple negative charges are common constituents in chemistry, influencing a range of processes ranging from photochemical smog formation to protein structure in vivo. This project will develop new technologies to probe their molecular structure in the gas-phase, leading to a more rigorous understanding of these species.
Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge ....Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge behaviours. Significant anticipated outcomes and benefits include the development of new material design approaches that optimise battery electrode performance across a diverse parameter space, and the generation of advanced new materials worthy of commercial development in low-cost, large-scale battery applications.Read moreRead less