Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100153
Funder
Australian Research Council
Funding Amount
$497,264.00
Summary
Integrated In situ Characterisation Facilities for Energy Studies. This project aims to establish a new capability to reveal catalytic behaviour of materials under practical working conditions at multi-scale levels. Through in situ monitoring of surface, interface and structural properties of catalysts, this unique integrated facility will overcome current limitations due to a lack of understanding of reaction mechanism, by ex situ and/or individual in situ characterisations. This world-class fa ....Integrated In situ Characterisation Facilities for Energy Studies. This project aims to establish a new capability to reveal catalytic behaviour of materials under practical working conditions at multi-scale levels. Through in situ monitoring of surface, interface and structural properties of catalysts, this unique integrated facility will overcome current limitations due to a lack of understanding of reaction mechanism, by ex situ and/or individual in situ characterisations. This world-class facility will significantly advance a range of electrocatalysis, photocatalysis and battery applications for renewable energy-storage and clean-fuel generation. This will be Australia’s only platform; it will benefit a number of innovative research projects in energy, catalysis and environmental and materials science.Read moreRead less
Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of the ....Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of these reactions, and the effect of catalyst composition and morphology on their performance. The resulting nanostructured catalysts are of great importance for feasible clean fuel generation and carbon dioxide reduction.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100187
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano in ....SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano infrared thermal analysis facility is essential to meet the demands of a large number of innovative projects conducted by multidisciplinary consortia of researchers. Located in state-of-the art laboratories and managed as open access resources, the facility will enable and advance research in the areas of energy harvesting, environmental monitoring, biomedical devices, food and pharmaceuticals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100137
Funder
Australian Research Council
Funding Amount
$358,275.00
Summary
Integrated thin film facility for catalysis and energy materials research. This project aims to establish thin film fabrication with catalytic/gas sorption characterisation needed for energy research. This project will overcome current limitations in advanced energy materials design via wet chemical methods. It will enable materials synthesis and characterisation toward thermal/photo/electro-catalytic, hydrogen storage, and battery technologies. The facility is expected to drive fundamental conc ....Integrated thin film facility for catalysis and energy materials research. This project aims to establish thin film fabrication with catalytic/gas sorption characterisation needed for energy research. This project will overcome current limitations in advanced energy materials design via wet chemical methods. It will enable materials synthesis and characterisation toward thermal/photo/electro-catalytic, hydrogen storage, and battery technologies. The facility is expected to drive fundamental concepts, and enable combinatorial search and new thin film technology. It is anticipated that this facility will increase Australia’s international competitiveness in the development of advanced energy materials.Read moreRead less
Conducting polymer materials. This project aims to understand the optical, electrical and optoelectronic properties of conductive polymers by studying how ions influence the charge transport through the polymeric structure. The discovery of conductive polymers in the 1970s led to smartphone and laptop touch displays and solar cells. These materials promise even more still – but how they operate at the atomic level is not understood. This project could lead to an ability to harness and control th ....Conducting polymer materials. This project aims to understand the optical, electrical and optoelectronic properties of conductive polymers by studying how ions influence the charge transport through the polymeric structure. The discovery of conductive polymers in the 1970s led to smartphone and laptop touch displays and solar cells. These materials promise even more still – but how they operate at the atomic level is not understood. This project could lead to an ability to harness and control these properties for energy storage and wearable displays. These materials’ biological neutrality could lead to drug delivery and sensing applications in the agriculture and healthcare spaces.Read moreRead less
Tailoring nanocomposites with controllable structural-property relationship. This project aims to process and fabricate graphene-based materials into useful devices. Understanding nanocomposite structure-property relationships are crucial to rapidly develop functional devices. This project will use graphene in the form of nanocomposites and precisely construct them in devices via three-dimensional printing. This will be achieved through the polymer chemistry and interfacial engineering of graphe ....Tailoring nanocomposites with controllable structural-property relationship. This project aims to process and fabricate graphene-based materials into useful devices. Understanding nanocomposite structure-property relationships are crucial to rapidly develop functional devices. This project will use graphene in the form of nanocomposites and precisely construct them in devices via three-dimensional printing. This will be achieved through the polymer chemistry and interfacial engineering of graphene for enhanced dispersibility and self-assembly in the targeted polymer matrix, thus affording maximum synergistic properties. The project expects to develop three-dimensional printing techniques and control and understand the effect of micro-patterning and nano-structuring on printed graphene nanocomposites.Read moreRead less
The development of flexible, graded plasma surface engineered coatings for superior interfacial performance. The next generation of intraocular lenses, medical devices to treat patients with cataracts, will be developed through application of advanced surface engineering technologies. These superior coated lenses will improve biocompatibility and function, leading to additional benefit for the forecasted 2.7 million Australians with cataracts by 2021.
Nanostructured non-precious metal and metal-free catalysts for sustainable clean energy generation. The innovative technologies for substitution of precious metal catalysts will be developed and used in fuel cells for clean energy generation in a highly efficient and sustainable form. This effort will lead to the reduction in carbon dioxide emissions and the alleviation of environmental and climate change problems.
Photocatalysts for solar hydrogen production. This project aims to develop photocatalysts with adjustable nano-structures and compositions to efficiently and stably catalyse water splitting for hydrogen production using sunlight. This project will include theoretical computations to predict the electronic band structure, adsorption energetics and active sites of photocatalysts, and to guide the design and synthesis of high-performance photocatalysts. These photocatalysts are important for clean ....Photocatalysts for solar hydrogen production. This project aims to develop photocatalysts with adjustable nano-structures and compositions to efficiently and stably catalyse water splitting for hydrogen production using sunlight. This project will include theoretical computations to predict the electronic band structure, adsorption energetics and active sites of photocatalysts, and to guide the design and synthesis of high-performance photocatalysts. These photocatalysts are important for clean and cost-effective solar hydrogen production with zero-emission of greenhouse gases. This project could help resolve Australia and the world’s energy and environmental challenges.Read moreRead less
Blue energy harvesting and storage technology for wearable electronics. This project aims to develop new self-charging power devices that can harvest and store body energy generated during body motions, and power smart and implantable medical electronics. The project will develop new Piezo-supercapacitors by designing new electrode materials and cell designs. The charge storage and transport kinetics will be uncovered using advanced in-situ characterisation techniques and modern simulation metho ....Blue energy harvesting and storage technology for wearable electronics. This project aims to develop new self-charging power devices that can harvest and store body energy generated during body motions, and power smart and implantable medical electronics. The project will develop new Piezo-supercapacitors by designing new electrode materials and cell designs. The charge storage and transport kinetics will be uncovered using advanced in-situ characterisation techniques and modern simulation methods. The project expects to generate new knowledge in blue energy harvesting and storage systems, training for young scientists, and generate intellectual property with potential commercialised products to be used in implantable devices, placing Australia at the forefront of new technology.Read moreRead less