In situ remediation in mine site rehabilitation. In situ remediation in mine site rehabilitation. By enhancing and guiding abiotic and biotic processes of soil development, this project aims to accelerate the in situ remediation of bauxite residue (alumina refining tailings). Over 7 gigatonnes of tailings are produced globally every year, comprising complex mineral assemblages at extremes of pH and salinity with minimal biological activity. This project will build detailed knowledge on the chemi ....In situ remediation in mine site rehabilitation. In situ remediation in mine site rehabilitation. By enhancing and guiding abiotic and biotic processes of soil development, this project aims to accelerate the in situ remediation of bauxite residue (alumina refining tailings). Over 7 gigatonnes of tailings are produced globally every year, comprising complex mineral assemblages at extremes of pH and salinity with minimal biological activity. This project will build detailed knowledge on the chemical, physical, and biological properties of bauxite residue and apply this to develop field-scale in situ remediation strategies. This research will also advance understanding of soil development and primary succession of microbial communities in extreme, anthropogenic environments such as those presented by tailings.Read moreRead less
Development of novel and effective strategies for soil microbial- and rhizo-remediation of onshore petrogenic hydrocarbon spills. The extensive use of petroleum products represents a constant threat of oil spills to onshore and offshore environments. Petroleum spillage seriously impacts environment and human health. This project is aimed at providing a suite of techniques for dealing with onshore oil spills and thereby building Australia’s environmental response capability.
Development of an anaerobic bioprocess for hexachlorobenzene destruction. This project will develop a biological process for destruction of a 10,000 tonne hexachlorobenzene stockpile in Sydney Australia. Development of a low energy bioprocess based on recently isolated bacteria will put an end to this ongoing health, environmental and industrial legacy issue and build expertise in bioprocessing for future applications.
In situ bioremediation solutions for Australia's organochlorine contaminated aquifers. This project will develop biological technologies to accelerate chlorinated solvent degradation in contaminated groundwater. Bacterial cultures developed in Australia will be injected into groundwater to enhance solvent degradation resulting in environmentally friendly and cost effective environmental restoration.
Improving thiocyanate bioremediation with meta-genomics/transcriptomics. Improving thiocyanate bioremediation with meta-genomics/transcriptomics. This project aims to elucidate the roles of thiocyanate-degrading microbial consortium members involved in sulphur and nitrogen oxidation, using metagenomics and metatranscriptomics. The gold mining industry generates environmentally toxic thiocyanate as a waste by-product, for which the most cost-effective remediation strategy is degradation by natura ....Improving thiocyanate bioremediation with meta-genomics/transcriptomics. Improving thiocyanate bioremediation with meta-genomics/transcriptomics. This project aims to elucidate the roles of thiocyanate-degrading microbial consortium members involved in sulphur and nitrogen oxidation, using metagenomics and metatranscriptomics. The gold mining industry generates environmentally toxic thiocyanate as a waste by-product, for which the most cost-effective remediation strategy is degradation by natural microbes. Efforts to bioremediate, however, suffer from a lack of understanding of the full metabolic potential of the microbes involved. The intended outcome of this project is the improved design and operation of thiocyanate bioremediation reactor systems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102673
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
F420-Reductases from mycobacteria: new opportunities for health care and environmental protection. A new class of enzymes, derived from the bacteria responsible for drug resistant forms of tuberculosis and leprosy, will be studied at a molecular level. New antibiotics will be designed, based on the molecular structures of these proteins. The proteins themselves will be engineered to break down harmful environmental toxins.
Discovery Early Career Researcher Award - Grant ID: DE150100500
Funder
Australian Research Council
Funding Amount
$321,000.00
Summary
Electron transfer at the microbe-mineral interface via cytochromes/exudates. This project aims to develop the kinetic (both in vivo and in vitro) and thermodynamic models of the extracellular electron transfer processes at the microbe-mineral interface via outer membrane cytochromes and exudates of dissimilatory iron-reducing bacteria, and elucidating the potential electron transfer process from iron-reducing bacteria to semiconducting iron minerals. The observed models will provide a more compr ....Electron transfer at the microbe-mineral interface via cytochromes/exudates. This project aims to develop the kinetic (both in vivo and in vitro) and thermodynamic models of the extracellular electron transfer processes at the microbe-mineral interface via outer membrane cytochromes and exudates of dissimilatory iron-reducing bacteria, and elucidating the potential electron transfer process from iron-reducing bacteria to semiconducting iron minerals. The observed models will provide a more comprehensive understanding of electron transfer reactions at the microbe-mineral interface, which will be helpful in the prediction of natural redox processes of iron transformation and in the development of bioremediation strategies for contaminated sites.Read moreRead less
Harnessing microbial respiration for pollutant degradation and natural gas production. This project seeks to exploit compounds produced naturally by microorganisms to develop a marketable green technology for environmental restoration and clean energy generation in Australia and abroad. Metropolitan and regional communities will benefit from improved environmental and human health and the economy will benefit from global application.
The pollution potential of mercury in legacy biosolids and possibilities for its minimisation by phytoremediation and phytostabilisation approaches. This project will develop: (1) new chemical analysis techniques to study the mercury fate in legacy biosolids which will lead to better understanding of their potential environmental impact; (2) environmentally-benign phytoremediation approaches using native plants to reduce mercury release so the biosolids can be safely used for land applications.