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
Fill it, Squeeze it, Crush it: Extreme Gas Uptake in Microporous Materials . Porous materials have the potential to be used as exceptional carbon capture materials, as well as for trapping and releasing other useful gases, such as those used in medical applications. They work, because they contain small holes where these gases can be trapped. Unfortunately, finding gas inside these holes experimentally is incredibly difficult, making it challenging to make better porous materials. In this pro ....Fill it, Squeeze it, Crush it: Extreme Gas Uptake in Microporous Materials . Porous materials have the potential to be used as exceptional carbon capture materials, as well as for trapping and releasing other useful gases, such as those used in medical applications. They work, because they contain small holes where these gases can be trapped. Unfortunately, finding gas inside these holes experimentally is incredibly difficult, making it challenging to make better porous materials. In this project, I will use extreme pressures to saturate these holes with gas molecules, allowing us to ‘see’ them. Not only will this mean that better porous materials can be designed and made, but will provide a unique approach to storing and trapping gases to be used in a variety of applications, from the energy to medical sectors.Read moreRead less
Anomalous Structural Response in Porous Framework Materials. This project targets a key missing link in understanding the host-guest properties of porous framework materials, namely, the dynamic response of host lattices to their external environment and to the inclusion of molecular guests. By combining advanced chemical, physical and structural measurements the project expects to provide the first concerted picture of materials behaviour across an array of scientific and technological settings ....Anomalous Structural Response in Porous Framework Materials. This project targets a key missing link in understanding the host-guest properties of porous framework materials, namely, the dynamic response of host lattices to their external environment and to the inclusion of molecular guests. By combining advanced chemical, physical and structural measurements the project expects to provide the first concerted picture of materials behaviour across an array of scientific and technological settings, with particular focus given to industrially relevant ‘real world’ conditions. This promises to greatly inform the on-going chemical design, formulation and process engineering of these materials, in turn accelerating their development in gas separation, energy storage and device componentry applications.Read moreRead less
ARC Centre of Excellence in Optical Microcombs for Breakthrough Science. ARC Centre of Excellence in Optical Microcombs for Breakthrough Science. This Centre aims to explore the society wide transformations that will flow from optical frequency combs - thousands of highly pure light signals precisely spaced across the entire optical spectrum - by leveraging and building upon the latest breakthroughs in physics, materials science and nanofabrication. It expects to generate a wide new base of know ....ARC Centre of Excellence in Optical Microcombs for Breakthrough Science. ARC Centre of Excellence in Optical Microcombs for Breakthrough Science. This Centre aims to explore the society wide transformations that will flow from optical frequency combs - thousands of highly pure light signals precisely spaced across the entire optical spectrum - by leveraging and building upon the latest breakthroughs in physics, materials science and nanofabrication. It expects to generate a wide new base of knowledge in fields as diverse as astronomy, spectroscopy, chemical sensors, and precision measurement. Expected outcomes include the capability to realise complete comb systems on a chip the size of a fingernail, tailored to specific applications, with significant benefits spanning from imaging live cells to autonomous vehicles, satellite communications, and the search for exoplanets.Read moreRead less
Pathways for performance improvements of organic light emitting diodes . Organic light-emitting diodes (OLEDs) represent the next generation technology for displays and lighting. Despite their rapid uptake, one of the factors limiting their application in lighting is the efficiency roll-off at high brightness. This project aims to work towards solutions for this problem using an innovative combination of simulation studies and experimental work. Expected outcomes include improved theoretical and ....Pathways for performance improvements of organic light emitting diodes . Organic light-emitting diodes (OLEDs) represent the next generation technology for displays and lighting. Despite their rapid uptake, one of the factors limiting their application in lighting is the efficiency roll-off at high brightness. This project aims to work towards solutions for this problem using an innovative combination of simulation studies and experimental work. Expected outcomes include improved theoretical and experimental approaches leading to new design rules for OLEDs. This should provide significant benefits such as a pathway for development of improved efficient, high brightness OLEDs for applications in low energy consumption lighting and long-lasting, bright displays.Read moreRead less