Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipi ....Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipitation platform technology for making drug-core polymer-shell nanoparticles, and a new bio-inspired approach for making hybrid drug-core silica-shell nanocomposites, and new materials for applications in programmed release and delivery systems.Read moreRead less
Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without cau ....Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without causing any environmental damage. This unique technology will also help to address clean energy generation, which is in line with H2 economy plan by Australia government, and provide opportunities for new industries that will benefit Australian economy.Read moreRead less
Integrated composite electrodes for electrochemical synthesis of ammonia. This project aims to develop multifunctional composite electrodes for electrochemical synthesis of ammonia from water, nitrogen gas and renewable energy under ambient conditions. Hydrophobic subnanometre water channels will be integrated with an electrocatalyst to control supply of water as vapour, thereby effectively minimising hydrogen evolution reaction and enabling high-efficiency ammonia synthesis. Expected outcomes i ....Integrated composite electrodes for electrochemical synthesis of ammonia. This project aims to develop multifunctional composite electrodes for electrochemical synthesis of ammonia from water, nitrogen gas and renewable energy under ambient conditions. Hydrophobic subnanometre water channels will be integrated with an electrocatalyst to control supply of water as vapour, thereby effectively minimising hydrogen evolution reaction and enabling high-efficiency ammonia synthesis. Expected outcomes include enhanced capacity in developing electrochemical reaction systems, and new fundamental knowledge of electrocatalyst design and reaction engineering. This should provide significant economic and environmental benefits by developing a sustainable manufacturing technology to transform the century-old ammonia industry.Read moreRead less
Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of th ....Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of the project will underpin the development of green technologies for sustainable energy conversion and water treatment. This will provide significant benefits, putting Australia in a leading position in the sustainable development of nanotechnology for sustainable energy supply and transformation as well as environmental and biomedical applications.Read moreRead less
Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and ad ....Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and advance fundamental understanding of molecular structure of materials for catalyst design and process engineering for industrial applications. The outcomes will promote the development of chemical industry, waste recycle and green environment in Australia, making significant benefits to economics and society.Read moreRead less
Two-dimensional nanoporous structured high performance gas evolution electrocatalysts. This project aims to develop nano-catalysts with high catalytic activity and rapid gas detachment properties for efficient fuel gas production. Heterogeneous electrocatalytic gas evolution reactions are important for clean energy generation and storage technologies, but high overpotentials caused by slow gaseous products’ detachment from catalyst surface severely hinder their efficiencies. Expected outcomes in ....Two-dimensional nanoporous structured high performance gas evolution electrocatalysts. This project aims to develop nano-catalysts with high catalytic activity and rapid gas detachment properties for efficient fuel gas production. Heterogeneous electrocatalytic gas evolution reactions are important for clean energy generation and storage technologies, but high overpotentials caused by slow gaseous products’ detachment from catalyst surface severely hinder their efficiencies. Expected outcomes include insights into gas bubble formation and evolution during electrocatalysis, effective catalyst structures to mitigate negative effects of gas bubble formation, and improved catalytic efficiency of gas evolution reactions and develop high performance electrocatalysts for fuel gas production.Read moreRead less
New hierarchical electrode design for high-power lithium ion batteries. This project aims to develop new types of hierarchical electrodes for high-rate lithium ion batteries with long cycling life. The key concepts are the development of multi-shelled hollow structured silicon-based anode and Li-rich layered oxides cathode to achieve both high power and energy density, and the adoption of graphene to further improve rate capability and cycling stability. Effective energy storage systems play an ....New hierarchical electrode design for high-power lithium ion batteries. This project aims to develop new types of hierarchical electrodes for high-rate lithium ion batteries with long cycling life. The key concepts are the development of multi-shelled hollow structured silicon-based anode and Li-rich layered oxides cathode to achieve both high power and energy density, and the adoption of graphene to further improve rate capability and cycling stability. Effective energy storage systems play an important role in the development of renewable energies and electric vehicles. The project outcomes will lead to innovative technologies in low carbon emission transportation and efficient energy storage systems.Read moreRead less
Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include ne ....Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include new membrane compositions, design principles, fabrication techniques, and proof-of-concept production of scalable, high-performance composite membranes. This project should produce significant economic and environmental benefits in the development of advanced membranes, pharmaceuticals, and agrochemicals.Read moreRead less
Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significant ....Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significantly advance our understanding of extremely lightweight and multifunctional cellular materials as well as graphene-based bulk materials. Project outcomes are expected to help generate high value-added technological applications from natural graphite.Read moreRead less
Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane ....Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane into high-performance, flexible fuel cells. The outcomes of this research aim to provide a unique opportunity for Australia to become a world leader in the rapidly-emerging clean energy technology, and critical manufacturing of new energy generation systems for domestic uses and exports, thereby producing important economic benefits.Read moreRead less