Repurposing urban construction waste to create diverse wildflower meadows. Wildflower meadows have been planted extensively in European cities for aesthetic and biodiversity benefits. In SE Australia, they are stunning, but rare, features of critically endangered grassy woodlands because most native wildflowers cannot cope with intense grazing and high soil nutrients associated with agriculture. This project aims to develop a novel process for establishing native wildflower meadows in urban park ....Repurposing urban construction waste to create diverse wildflower meadows. Wildflower meadows have been planted extensively in European cities for aesthetic and biodiversity benefits. In SE Australia, they are stunning, but rare, features of critically endangered grassy woodlands because most native wildflowers cannot cope with intense grazing and high soil nutrients associated with agriculture. This project aims to develop a novel process for establishing native wildflower meadows in urban parks and degraded grassy woodlands by repurposing low nutrient mineral waste from the construction industry. It will have multiple benefits including restoring urban biodiversity, increasing people's mental well-being, developing new markets for recycled construction waste and reducing the amount of waste going to landfill. Read moreRead less
Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and benefici ....Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and beneficial in restoring the manufacturing capability of Australian industry, driving Australian industry towards the development of a circular economy for the appropriate management of solid waste, as well as for a seamless introduction of renewable and clean energy sources to address the pressing climate change.Read moreRead less
Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty ....Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty chemicals. The outcomes and further technology adoptions will extend the capacity of the Partner Organisation for producing specialty battery materials. The outcomes could help Australia’s battery industry switch to a more diversified pathway, which benefits the economic development of Australia in a long term.Read moreRead less
Chemicals in compostable food contact paper packaging materials. The aim of this project is to understand the presence of persistent chemicals in recyclable and compostable food contact materials (FCMs). These types of products are destined for recycling or biowaste streams that bridge the gap from take-make-dispose and into a circular economy. Currently, the knowledge of the chemicals in these products is limited but we need to ensure that they are safe and do not unnecessarily contaminate reso ....Chemicals in compostable food contact paper packaging materials. The aim of this project is to understand the presence of persistent chemicals in recyclable and compostable food contact materials (FCMs). These types of products are destined for recycling or biowaste streams that bridge the gap from take-make-dispose and into a circular economy. Currently, the knowledge of the chemicals in these products is limited but we need to ensure that they are safe and do not unnecessarily contaminate resource recovery streams. It is expected that this project will develop a framework that could be used by industry and government to prevent chemicals of concern persisting in a circular economy, providing environmental and economic benefits through reduced risk of chemical exposure and unnecessary remediation costs.Read moreRead less
Upcycling of mixed plastics from bioprocessed municipal solid waste. This project aims to develop a scalable catalytic process that can sustainably upcycle mixed plastics from bioprocessed municipal solid waste into hydrogen and valuable carbon nanotube products. The process will integrate pyrolysis, reforming, and carbon growth technology into a single reactor, enabled by the rational design of multifunctional catalysts. Through computational process simulation and optimization, life cycle anal ....Upcycling of mixed plastics from bioprocessed municipal solid waste. This project aims to develop a scalable catalytic process that can sustainably upcycle mixed plastics from bioprocessed municipal solid waste into hydrogen and valuable carbon nanotube products. The process will integrate pyrolysis, reforming, and carbon growth technology into a single reactor, enabled by the rational design of multifunctional catalysts. Through computational process simulation and optimization, life cycle analysis, and techno-economic assessment, investment and operational costs at larger scale are anticipated to be greatly reduced. By mitigating mixed waste plastics from going to landfills, the project will also provide significant benefits to clean energy production and advanced material manufacturing in Australia. Read moreRead less
Unlocking mine waste potential: carbon sequestration and metals extraction. This project aims to systematically investigate a proof-of-concept engineering process for transforming mine waste into value. The research will develop and employ state-of-the-art tools to advance our knowledge of efficiently sequestering carbon dioxide using ultramafic nickel mine tailings, while also enabling the extraction of critical metals—particularly nickel—and the production of value-added products, such as high ....Unlocking mine waste potential: carbon sequestration and metals extraction. This project aims to systematically investigate a proof-of-concept engineering process for transforming mine waste into value. The research will develop and employ state-of-the-art tools to advance our knowledge of efficiently sequestering carbon dioxide using ultramafic nickel mine tailings, while also enabling the extraction of critical metals—particularly nickel—and the production of value-added products, such as high-purity magnesium carbonate hydrate and silica. Successful outcomes from this research will provide benefits for mitigating global warming, supplying critical metals for renewable energy technologies, and facilitating the transition of Australia's mining industry towards sustainability.Read moreRead less