Creating pH-sensitive self-healing concrete using sludge waste for sewers. In Australia, our 117,000 km of concrete sewer pipes are currently internally corroding at a depth rate of 1-3 mm per annum. The repair of deteriorated concrete is costly and often short-lived. Based on an advanced composite technology, this project will develop a pH-sensitive self-healing concrete that can repair itself without human intervention at the early stage of corrosion. Sludge waste from drinking water treatment ....Creating pH-sensitive self-healing concrete using sludge waste for sewers. In Australia, our 117,000 km of concrete sewer pipes are currently internally corroding at a depth rate of 1-3 mm per annum. The repair of deteriorated concrete is costly and often short-lived. Based on an advanced composite technology, this project will develop a pH-sensitive self-healing concrete that can repair itself without human intervention at the early stage of corrosion. Sludge waste from drinking water treatment will be utilised as a healing agent to mitigate the corrosion. Combined experiments and molecular dynamics simulation will uncover all aspects of the healing process to enable the practical application of this technology. The findings will extend the lifetime of concrete structures and promote a circular economy.Read moreRead less
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
Australian Laureate Fellowships - Grant ID: FL170100086
Funder
Australian Research Council
Funding Amount
$2,924,858.00
Summary
Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting an ....Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting and highly valuable area of anaerobic microbial conversion of methane, the least understood process in the global carbon cycle. This transformational research has a strong potential to create a new biotechnology sector producing high-value chemicals from methane, and will propel Australia to the forefront of sustainable resources research.Read moreRead less
A top-down approach to synthesising high-value fluorocarbons. Fluorocarbons' ability to impart high stability, solubility, and unique reactivity to host molecules renders them invaluable in agrochemicals, pharmaceuticals, polymers and surfactants. Their robustness also renders them environmentally persistent. There are no industrially utilised methods for the re-purposing or recycling of fluorocarbons. This project aims to generate new methods for the selective activation of carbon-fluorine bond ....A top-down approach to synthesising high-value fluorocarbons. Fluorocarbons' ability to impart high stability, solubility, and unique reactivity to host molecules renders them invaluable in agrochemicals, pharmaceuticals, polymers and surfactants. Their robustness also renders them environmentally persistent. There are no industrially utilised methods for the re-purposing or recycling of fluorocarbons. This project aims to generate new methods for the selective activation of carbon-fluorine bonds in polyfluorocarbons, allowing their incorporation or repurposing into high value chemicals and/or easy derivitisation to access a plethora of new fluorocarbon products. Expected outcomes will allow new processing methods to value add to fluorocarbons while preventing their environmental release. Read moreRead less