Discovery Early Career Researcher Award - Grant ID: DE170100694
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Building resilience in wastewater infrastructure with self-healing bioconcrete. This project aims to develop a microbial self-healing bio-concrete to extend the service life of wastewater collection and treatment facilities. Water utilities worldwide struggle with asset management, because global warming and extreme weather age and corrode concrete infrastructure. This project will use microbially-induced calcium carbonate precipitation by bacteria to treat wastewater. The bacteria, added to bio ....Building resilience in wastewater infrastructure with self-healing bioconcrete. This project aims to develop a microbial self-healing bio-concrete to extend the service life of wastewater collection and treatment facilities. Water utilities worldwide struggle with asset management, because global warming and extreme weather age and corrode concrete infrastructure. This project will use microbially-induced calcium carbonate precipitation by bacteria to treat wastewater. The bacteria, added to bio-concrete, can fill cracks or reseal corroded areas by using organic substrates from wastewater to generate concrete, thus maintaining structural strength and preventing further damage. This project is expected to enhance the resilience and sustainability of wastewater infrastructure in ever more demanding environments.Read moreRead less
The LASE process - a new approach to cost effective thin solar cells. This project aims to develop a process to produce a new type of single
crystalline silicon solar cell. The cell is made on very thin slices of silicon that are detached from a conventional high quality silicon wafer. The wafer is gradually consumed as successive slices are harvested from it. Substantially less silicon is used in each solar cell, which allows significant cost reductions.
Low cost photovoltaic modules through reduced silicon consumption. Aims: The project aims to develop new methods and processes for the production of solar cells and photovoltaic modules. The modules will be made from very thin, narrow silicon solar cells. Because the modules use much less silicon than conventional modules, they are expected to be substantially cheaper.
Expected outcomes: It is expected that the project will lead to implementation of the proposed technology in a pilot plant and ....Low cost photovoltaic modules through reduced silicon consumption. Aims: The project aims to develop new methods and processes for the production of solar cells and photovoltaic modules. The modules will be made from very thin, narrow silicon solar cells. Because the modules use much less silicon than conventional modules, they are expected to be substantially cheaper.
Expected outcomes: It is expected that the project will lead to implementation of the proposed technology in a pilot plant and commercialisation thereafter.
Significance: Successful commercialisation will result in a significant reduction in the cost of photovoltaic modules as well as substantial economic benefits to the commercial partner and Australia.Read moreRead less
ARC Centre for Solar Energy Systems. The National Centre of Excellence for Solar Energy Systems will be an international leader in research, commercialisation and education in the area of solar energy conversion. Research will be conducted into solar cell and solar thermal technologies, including thin crystalline and amorphous silicon solar cells that use far less silicon than conventional cells; systems that concentrate sunlight by 50-500 times; and very efficient solar cells for use in concent ....ARC Centre for Solar Energy Systems. The National Centre of Excellence for Solar Energy Systems will be an international leader in research, commercialisation and education in the area of solar energy conversion. Research will be conducted into solar cell and solar thermal technologies, including thin crystalline and amorphous silicon solar cells that use far less silicon than conventional cells; systems that concentrate sunlight by 50-500 times; and very efficient solar cells for use in concentrator systems. Expected outcomes include long-term research, commercial research, publications, education, community outreach and commercialisation of solar energy technologies to benefit Australia's economy and environment.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
Advanced Particles and Systems for Photoinduced Processes. One of the most crucial challenges facing chemical scientists is the need for ecologically clean chemical processes and technology. Solar induced processes, such as photocatalysis, are adept at utilising more of our natural energy resources. However, these processes currently suffer from low efficiencies. The proposed research aims to address these issues. Successful implementation of this technology will help place Australian research a ....Advanced Particles and Systems for Photoinduced Processes. One of the most crucial challenges facing chemical scientists is the need for ecologically clean chemical processes and technology. Solar induced processes, such as photocatalysis, are adept at utilising more of our natural energy resources. However, these processes currently suffer from low efficiencies. The proposed research aims to address these issues. Successful implementation of this technology will help place Australian research at the forefront of sustainable methods for water treatment and material synthesis for functional applications. This will provide economic and social benefits due to improvements in processes with higher efficiencies and greater use of clean, natural resources.
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A Novel Approach for Color and Degradation Control in Post Consumer Polyethylene Terephthalate During Recycling. Discoloration is a critical problem in the manufacturing of post-consumer polyethylene terephthalate (PET) polymeric products in which optical clarity requirement is high. The inherent weakness of the PET demands highly efficient stabilisation of this polymer. The project aims to understand and eliminate the occurrence of such discoloration and improve the quality of the Visy product ....A Novel Approach for Color and Degradation Control in Post Consumer Polyethylene Terephthalate During Recycling. Discoloration is a critical problem in the manufacturing of post-consumer polyethylene terephthalate (PET) polymeric products in which optical clarity requirement is high. The inherent weakness of the PET demands highly efficient stabilisation of this polymer. The project aims to understand and eliminate the occurrence of such discoloration and improve the quality of the Visy products. New multifunctional additives will be developed, which when added to PET during processing, will not only quench the discoloration reaction but also yield high quality products with excellent optical properties. This project is of substantial strategic importance to the Australian/global polymer processing and recycling industries.
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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
Design of Advanced Geopolymeric Materials Based on Nanostructural Characterisation and Modelling. Geopolymers are a class of advanced aluminosilicate materials primarily utilised in the construction and building products industries, where their application as a replacement for ordinary Portland cement provides the potential for highly significant Greenhouse gas emission reductions. Australian research has led to the increasingly widespread commercial use of this technology in a range of areas. D ....Design of Advanced Geopolymeric Materials Based on Nanostructural Characterisation and Modelling. Geopolymers are a class of advanced aluminosilicate materials primarily utilised in the construction and building products industries, where their application as a replacement for ordinary Portland cement provides the potential for highly significant Greenhouse gas emission reductions. Australian research has led to the increasingly widespread commercial use of this technology in a range of areas. Development of a full understanding of the exact chemical structure of geopolymers is essential to finding and developing new applications for these materials as well as maximising their use in known applications.Read moreRead less
PREDICTING THE CLOGGING OF STORM WATER INFILTRATION SYSTEMS. Infiltration systems are widely used in sustainable management of stormwater in both urban and rural areas. They are also an integral part of large stormwater-harvesting facilities. However, they tend to fail due to clogging (infiltration medium gets filled by silt from runoff), and this phenomenon is far from being understood. The aim of this project is to develop a new prediction method of clogging of stormwater infiltration systems. ....PREDICTING THE CLOGGING OF STORM WATER INFILTRATION SYSTEMS. Infiltration systems are widely used in sustainable management of stormwater in both urban and rural areas. They are also an integral part of large stormwater-harvesting facilities. However, they tend to fail due to clogging (infiltration medium gets filled by silt from runoff), and this phenomenon is far from being understood. The aim of this project is to develop a new prediction method of clogging of stormwater infiltration systems. Extensive 1D and 2D laboratory experimental programmes will be carried out. Models of unit processes that occur in infiltration systems will be defined/developed and built into a physically based model of an infiltration system. This model could be used for reliable design of stormwater drainage and harvesting systems, bringing major benefits to the people of drier and more populated areas of Australia.Read moreRead less