THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the proj ....THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the project aims to elucidate the effects of catalyst doping and defects in the carbon nanotube walls on the adsorption mechanism and capacity of hydrogen. Such an understanding is crucial to developing the improved carbon nanotubes with high adsorption capacity.Read moreRead less
The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defect ....The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defects into the structures of carbon materials, with both theoretical and experimental methods. This project also aims to foster a long term linkage with the National Institute of Advanced Industrial Science and Technology, Japan thus enhancing Australian Universities's integration with the research institutions overseas in research and developmentRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882357
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering ....A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering/purifying water and gases. The dedicated computing facility will enable a fast interactive cycle between simulation and experiment in these areas, accelerating the pace of research and applications.Read moreRead less
Nanostrutured Magnesium-base Composites for High-density Hydrogen Storage. This project aims to develop nanocrstalline magnesium-based composites for effective hydrogen storage, overcoming two main technical barriers of current metal hydride systems: high charging/discharging temperature and slow kinetics. Nanoscale catalysts based on mesoporous carbons and metal nanoparticles will be introduced into the magnesium to increase storage capacity and increase the rate at low temperatures. Fundament ....Nanostrutured Magnesium-base Composites for High-density Hydrogen Storage. This project aims to develop nanocrstalline magnesium-based composites for effective hydrogen storage, overcoming two main technical barriers of current metal hydride systems: high charging/discharging temperature and slow kinetics. Nanoscale catalysts based on mesoporous carbons and metal nanoparticles will be introduced into the magnesium to increase storage capacity and increase the rate at low temperatures. Fundamental understanding on the effects of catalysts, and adsorption and desorption mechanisms will be obtained to optimise the composite materials. This project will lead to effective and practical technology for hydrogen storage that will meet the target of commercial fuel cell vehicles.Read moreRead less
Fundamental Characterization of Adsorption of Simple to Complex Fluids on Carbon Black and in Carbon Pores. The outcome of this project will help designing engineers with a molecular simulation model for adsorption of simple to complex fluids commonly used in industries. The success of this project translates to a significant saving because it requires minimum effort in experimentation.
Methane hydrate in carbon nanopores as a potential means for energy storage. This project deals with the innovative means to store methane (natural gas) in the form of methane hydrate in the nanospace of carbon pores. The significance of this project lies in the enhanced storage of methane at a moderate pressure, compared to the compressed natural gas technology. Expected outcome is the better and efficient utilization of natural gas in transportation industries, and the better understanding o ....Methane hydrate in carbon nanopores as a potential means for energy storage. This project deals with the innovative means to store methane (natural gas) in the form of methane hydrate in the nanospace of carbon pores. The significance of this project lies in the enhanced storage of methane at a moderate pressure, compared to the compressed natural gas technology. Expected outcome is the better and efficient utilization of natural gas in transportation industries, and the better understanding of the formation of methane hydrate in carbon nanopores.Read moreRead less
An integrated system for high-efficiency hydrogen assisted electricity generation from solar energy. Energy security and climate change have intensified the search for renewable energy technologies that will reduce the carbon footprint of our economies. This project will lead to a technology platform, enabling hydrogen production and electricity generation by a clean way, which is high potential in solar-abundance Australia. Its success will definitely benefit Australia both economically and env ....An integrated system for high-efficiency hydrogen assisted electricity generation from solar energy. Energy security and climate change have intensified the search for renewable energy technologies that will reduce the carbon footprint of our economies. This project will lead to a technology platform, enabling hydrogen production and electricity generation by a clean way, which is high potential in solar-abundance Australia. Its success will definitely benefit Australia both economically and environmentally. It will speed up the utilisation of solar energy and help Australia reduce greenhouse emissions. It would also lead to advanced technologies that can be commercialised and exported overseas, thus positioning Australia at the forefront of renewable energy development.Read moreRead less
Practical Hydrogen Storage for Fuel Cells Electrical Vehicles by Confined Ammonia Borane System. Practical hydrogen storage is critical to make the hydrogen economy a reality, in particular for fuel cells electrical vehicles (FCVE). However, currently there is no approach to satisfy the requirements of hydrogen storage for FCVE, e.g. fulfill the US Department of Energy target for practical hydrogen storage. This project is proposed to develop a new strategy to achieve the goal of practical hyd ....Practical Hydrogen Storage for Fuel Cells Electrical Vehicles by Confined Ammonia Borane System. Practical hydrogen storage is critical to make the hydrogen economy a reality, in particular for fuel cells electrical vehicles (FCVE). However, currently there is no approach to satisfy the requirements of hydrogen storage for FCVE, e.g. fulfill the US Department of Energy target for practical hydrogen storage. This project is proposed to develop a new strategy to achieve the goal of practical hydrogen storage which, if successful, will make FCVE possible in Australia in the near future. It will also be beneficial for reducing the dependence on exported oil and possibly solving critical environmental issues, and thus benefits the Australian economy.Read moreRead less
Functional Renewable Plastics: Developing Novel Polysaccharide, Protein and Natural Polyester Based Polymer Nanocomposites. Biopolymer based plastics (eg starch and proteins from plants; polylactic acid from wastes) are made from renewable sources and are readily biodegradable, making them good substitutes for synthetic plastics for uses like packaging and agricultural film.
Some biopolymer plastics properties (eg water migration barrier, strength) are not as high as synthetic plastics. Creat ....Functional Renewable Plastics: Developing Novel Polysaccharide, Protein and Natural Polyester Based Polymer Nanocomposites. Biopolymer based plastics (eg starch and proteins from plants; polylactic acid from wastes) are made from renewable sources and are readily biodegradable, making them good substitutes for synthetic plastics for uses like packaging and agricultural film.
Some biopolymer plastics properties (eg water migration barrier, strength) are not as high as synthetic plastics. Creating nano-biocomposites (biopolymer plastics mixed with low levels of nano particles) will improve the properties of biopolymer plastics, giving novel materials that can be substituted for synthetic plastics in a wider range of applications.
These products will reduce our environmental impact, and also create economic benefits from novel, high-value nano-biocomposites.Read moreRead less
Fundamental study on hydrogen desorption from nanoscale Magnesium (Mg) hydrides. Hydrogen storage is the most challenge in realizing the hydrogen economy, especially for on-board application in hydrogen-driving vehicles. Magnesium is among the few promising candidates of effective, safe, high density and cheap hydrogen storage, which has attracted tremendous interests of research. This project creates an innovative science and technology to solve the critical problem of hydrogen storage that wil ....Fundamental study on hydrogen desorption from nanoscale Magnesium (Mg) hydrides. Hydrogen storage is the most challenge in realizing the hydrogen economy, especially for on-board application in hydrogen-driving vehicles. Magnesium is among the few promising candidates of effective, safe, high density and cheap hydrogen storage, which has attracted tremendous interests of research. This project creates an innovative science and technology to solve the critical problem of hydrogen storage that will enhance the international reputation and impact of Australian research in nanoscience and nanothechnology. Realizing the practical hydrogen storage will also enable hydrogen vehicles soon in Australia that adds Australia great potential to reducing the reliance on fossil fuels and greenhouse emissions.Read moreRead less