All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoar ....All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoarchitectures to reduce platinum content and to improve electrocatalytic performance. Nanoporous systems in electrocatalysts can provide more active sites and effective surface permeability, which should enhance catalytic activity. Project outcomes may also contribute to our understanding of the relationships among morphologies, pore structures, surface atomic structures and catalytic activities to guide the development of other kinds of high performance nanoporous catalysts.Read moreRead less
Improving solar energy utilisation by splitting water with visible light. The project seeks to improve solar-hydrogen fuel production via water splitting by addressing a fundamental scientific roadblock. By engineered nanostructures with controlled charge transfer abilities, the most desirable route to water splitting will be promoted; granting Australia an opportunity to develop a solar-based renewable fuel.
Design of novel nanoporous semiconductor materials for clean environment and energy. This project will develop a low cost nanoporous semiconductor device for the capture and conversion of CO2 into fuels by using water and sunlight. This novel approach will deliver a low cost technology that offers clean energy and will help to mitigate global warming.
Discovery Early Career Researcher Award - Grant ID: DE120101890
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Purification of contaminated wastewaters by modified Bayer layered double hydroxides. This project intends to develop enhanced adsorbent materials, prepared from industrial wastewater and seawater, for the decontamination of environments affected by Australian industries. This inexpensive novel material will be applicable to a wide range of purification applications and will reduce the environmental impact of Australian industries.
Open framework organic materials for CO2 capture and conversion. The reduction of CO2 emissions from coal-fired power plants is a technological challenge of global significance. This project will address this challenge by developing a unique system, based upon open framework materials, that will selectively capture CO2 from gas streams and then catalyse its transformation into industrially useful chemicals.
On-demand visible light degradable dental materials. This project aims to break new ground in the field of advanced adhesives by pioneering a unique system that can be cleaved with a defined visible light trigger, enabling the removal of previously bonded material without mechanical force. This would allow two materials to be strongly bonded, including dental crowns, braces and implants. The project will advance on-demand degradable materials design, introducing an advanced class of responsive n ....On-demand visible light degradable dental materials. This project aims to break new ground in the field of advanced adhesives by pioneering a unique system that can be cleaved with a defined visible light trigger, enabling the removal of previously bonded material without mechanical force. This would allow two materials to be strongly bonded, including dental crowns, braces and implants. The project will advance on-demand degradable materials design, introducing an advanced class of responsive networks for applications where reversible bonding is critical. It will have flow on benefits in future dental material applications and also have applications where simple-to-remove, temporary adhesives are required.Read moreRead less
Advanced adsorbents for gas separations. Efficient purification of natural gas and separation of similarly-sized molecules in gas mixtures is increasingly important in our drive to develop a more sustainable way of living in an energy-constrained world. This project will develop a new class of adsorbents to deliver a level of separation efficiency much higher than that currently in use.
Janus particles and nanorattles: new materials for paint technology. This project will pave the way for self cleaning paints that achieve opacity with greatly reduced titanium dioxide levels. Painted surfaces will maintain their clean and new look for longer and a clean town look will be much more readily maintained. More efficient use of titanium dioxide will reduce the need for sand mining and reduce the cost of quality paint.
New high performance zinc bromine batteries with novel electrode/electrolyte systems. Renewable sources of energy are of particular interest in the era of diminishing fossil fuels. Efficient energy storage is a missing link for renewable energy. Zinc-bromine batteries have great potential as energy storage. This project will aim to fundamentally re-design the existing first generation systems to improve power density by 300-400 per cent.