Novel strategy for optimising fertilizer input coupled with organic residue management for sustainable reconstruction of jarrah forest ecosystem. This project is aimed at judicious management of the rehabilitation process following surface mining by reducing initial fertilizer input along with using organic residue accumulated following pre-mine clearing of vegetation. This approach has the potential for 'speeding-up' the ecosystem development process by initiating early microbial development in ....Novel strategy for optimising fertilizer input coupled with organic residue management for sustainable reconstruction of jarrah forest ecosystem. This project is aimed at judicious management of the rehabilitation process following surface mining by reducing initial fertilizer input along with using organic residue accumulated following pre-mine clearing of vegetation. This approach has the potential for 'speeding-up' the ecosystem development process by initiating early microbial development in rehabilitation practice and reducing the deleterious effect of heavy fertilization. Apart from these ecological advantages, reducing fertilizer application lowers minesite rehabilitation cost incurred by mining companies. This project will be the first attempt to use organic residue and streamlining the use of mineral fertilizers in mine rehabilitation practice.Read moreRead less
How are microorganisms and nutrient cycling in saline soils affected by soil matric potential? Dryland agriculture is threatened by salinity and drought, and it is well-known that individually, both can decrease not only crop growth but also microbial activity and nutrient cycling which are critical for sustainability. As our climate becomes drier, it is necessary to understand how microbial activity and nutrient cycling in saline soils will be affected by drought and sporadic summer rainfall ev ....How are microorganisms and nutrient cycling in saline soils affected by soil matric potential? Dryland agriculture is threatened by salinity and drought, and it is well-known that individually, both can decrease not only crop growth but also microbial activity and nutrient cycling which are critical for sustainability. As our climate becomes drier, it is necessary to understand how microbial activity and nutrient cycling in saline soils will be affected by drought and sporadic summer rainfall events. As an international team of soil biologists, we will investigate the interactions between salinity and soil moisture on microbial activity and nutrient cycling. The results will provide insights into nutrient cycling in saline soils now and in the future and the benefit of amelioration strategies.Read moreRead less
Quantifying the re-establishment of soil processes and the impact of fire management on rehabilitated bauxite mines in Western Australia. A major objective in the rehabilitation of bauxite mines in the jarrah forest of Western Australia is to return a self-sustaining ecosystem. Nutrient cycling and microbial diversity are key components of the functioning of the rehabilitated system; but little is know about the resilience of these processes in jarrah forests. We aim to quantify the dynamic rela ....Quantifying the re-establishment of soil processes and the impact of fire management on rehabilitated bauxite mines in Western Australia. A major objective in the rehabilitation of bauxite mines in the jarrah forest of Western Australia is to return a self-sustaining ecosystem. Nutrient cycling and microbial diversity are key components of the functioning of the rehabilitated system; but little is know about the resilience of these processes in jarrah forests. We aim to quantify the dynamic relationships between soil organic matter cycling, microbial diversity and function in relation to seasonality, rehabilitation age and fire. This is of specific relevance to restoring biodiversity within rehabilitated Jarrah forests and establishing a time frame for their return to state government management.Read moreRead less
Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iro ....Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iron reducers will be selected and introduced to the cell (in conjunction with chemical amendments) and their colonization monitored. The new technology once developed has the potential to be used at mine sites in Australia and overseas and its employment offers a sustainable, biological "green" approach to mine waste remediation.Read moreRead less
Biogeochemistry of ferruginous duricrusts. The project is focussed on the examination and application of microbial iron cycling in the formation of geologically stable, iron duricrusts in tropical regimes. The aim of the project is to develop a site-scale bioremediation strategy for iron ore mines by re-establishing canga, which are ‘ancient’ distinct ecosystems possessing unique plant species rarely found on Earth. This university-industry collaboration aims to produce economic benefits for the ....Biogeochemistry of ferruginous duricrusts. The project is focussed on the examination and application of microbial iron cycling in the formation of geologically stable, iron duricrusts in tropical regimes. The aim of the project is to develop a site-scale bioremediation strategy for iron ore mines by re-establishing canga, which are ‘ancient’ distinct ecosystems possessing unique plant species rarely found on Earth. This university-industry collaboration aims to produce economic benefits for the world’s iron mining industry through advanced training in mining-related research, and through the completion of the mining life cycle by site remediation, enhancing Australia’s position as a global leader in providing innovative solutions to today’s mining challenges.Read moreRead less
Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated c ....Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated compounds, will inform handling of contaminated sites and lead to development of cost effective and sustainable remediation technologies. Read moreRead less
Managing acid mine drainage in northern Australia using microbial mats. One of the most difficult environmental issues for the mining industry is acid mine drainage (AMD) that can lead to significant environmental damage. This project aims to identify microbes and characterise their roles in AMD formation in north Australia. We will use our new knowledge to design and trial microbial mats for the treatment of AMD. A successful AMD microbial treatment technology will minimise the risk of acid run ....Managing acid mine drainage in northern Australia using microbial mats. One of the most difficult environmental issues for the mining industry is acid mine drainage (AMD) that can lead to significant environmental damage. This project aims to identify microbes and characterise their roles in AMD formation in north Australia. We will use our new knowledge to design and trial microbial mats for the treatment of AMD. A successful AMD microbial treatment technology will minimise the risk of acid runoff and metal seepage into rivers and through groundwater. AMD treatment technology we develop in the tropics where we experience the extremes of dry and wet seasons will require only minor modification to operate in temperate climates however the reverse is not true. Read moreRead less
Geochemical, physical and microbiological controls on zinc mobility and implications for bioremediation strategies in Western Tasmanian acid mine drainage. We propose to study heavy metal pollution (e.g., zinc, arsenic, iron, tin) and biogeochemical processes operating in acid mine drainage at the abandoned Mt Bischoff tin mine in Western Tasmania. The drainage waters at this site have pH values as low as 2, but contain an extensive and thriving natural biological community. We will evaluate w ....Geochemical, physical and microbiological controls on zinc mobility and implications for bioremediation strategies in Western Tasmanian acid mine drainage. We propose to study heavy metal pollution (e.g., zinc, arsenic, iron, tin) and biogeochemical processes operating in acid mine drainage at the abandoned Mt Bischoff tin mine in Western Tasmania. The drainage waters at this site have pH values as low as 2, but contain an extensive and thriving natural biological community. We will evaluate whether the natural biogeochemical processes operating at Mt Bischoff have the potential to remediate mine waters under the full gamut of climatic conditions, so as to evaluate whether the biota could be exported to other mine sites to help in ameliorating acid drainage problems.Read moreRead less
Saprophytic Ability and Long-term Survival of Phytophthora cinnamomi in Rehabilitated Bauxite Mines and Adjacent Eucalyptus marginata (Jarrah) Forest. The plant pathogen Phytophthora cinnamomi is listed by the Commonwealth as a ?Key threatening process? to Australia's biodiversity. This study will examine the physical, chemical and biological factors that influence long-term survival of P. cinnamomi in a range of jarrah forest and mine site soils, by examining saprophytic ability and endogenous ....Saprophytic Ability and Long-term Survival of Phytophthora cinnamomi in Rehabilitated Bauxite Mines and Adjacent Eucalyptus marginata (Jarrah) Forest. The plant pathogen Phytophthora cinnamomi is listed by the Commonwealth as a ?Key threatening process? to Australia's biodiversity. This study will examine the physical, chemical and biological factors that influence long-term survival of P. cinnamomi in a range of jarrah forest and mine site soils, by examining saprophytic ability and endogenous dormancy. Managers will be provided with better tools for determining the presence and predicting the persistence of P. cinnamomi by obtaining information on the environmental factors that influence survival time in different soils and how to manipulate these to decrease the pathogen's survival.Read moreRead less
Breaking critical barriers in soil formation of bauxite residues . Conventional methods of bauxite residue rehabilitation require expensive and unsustainable covering topsoil. Building on recent breakthroughs in eco-engineering tailings into soil, the project aims to develop a field-based technology using marine microbes and halophytic plants to accelerate in-situ soil formation from bauxite residues (incl seawater neutralised bauxite residues) under field conditions. The technology will be unde ....Breaking critical barriers in soil formation of bauxite residues . Conventional methods of bauxite residue rehabilitation require expensive and unsustainable covering topsoil. Building on recent breakthroughs in eco-engineering tailings into soil, the project aims to develop a field-based technology using marine microbes and halophytic plants to accelerate in-situ soil formation from bauxite residues (incl seawater neutralised bauxite residues) under field conditions. The technology will be underpinned by understanding the roles of marine microbe consortia and eco-engineering inputs in accelerating key mineralogical, geochemical, physical and biological changes in bauxite residues. This technology is expected to be transferable and adaptable across other alumina refineries in Australia.Read moreRead less