The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
Using molecular tools to understand and control the transmission of Cryptosporidium. Cryptosporidium is the major public health concern of water utilities as the parasite has a global impact on the health and survival of millions of people and animals worldwide. It is resistant to chlorine and there are no effective drugs against it. Control strategies therefore rely on understanding how it is transmitted. This project will conduct a comprehensive study utilising molecular tools to determine if ....Using molecular tools to understand and control the transmission of Cryptosporidium. Cryptosporidium is the major public health concern of water utilities as the parasite has a global impact on the health and survival of millions of people and animals worldwide. It is resistant to chlorine and there are no effective drugs against it. Control strategies therefore rely on understanding how it is transmitted. This project will conduct a comprehensive study utilising molecular tools to determine if the Cryptosporidium in humans is the same as that derived from water contamination sources (animals, sewage etc). The outcomes of this project will result in the development of more targeted, cost-effective preventive measures to minimize exposures to infections, accurate risk assessment, and scientific management of the watershed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100149
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Spectroscopic imaging for materials, minerals and life sciences. The spectroscopic imaging equipment highlighted in this proposal will produce a number of outcomes of national benefit. First, it will elevate the impact of research in materials, minerals, and life sciences in Australia, all of which are key areas for the national economy and community. Second, the equipment will be integral to the teaching and research nexus and experiential learning facility for a new wave of materials science ....Spectroscopic imaging for materials, minerals and life sciences. The spectroscopic imaging equipment highlighted in this proposal will produce a number of outcomes of national benefit. First, it will elevate the impact of research in materials, minerals, and life sciences in Australia, all of which are key areas for the national economy and community. Second, the equipment will be integral to the teaching and research nexus and experiential learning facility for a new wave of materials science and engineering students to be educated at UniSA in the EIF-funded M2 building at Mawson Lakes. Finally, the anticipated outcomes of the research to be supported are significant and relate clearly to a number of National Research Priorities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560920
Funder
Australian Research Council
Funding Amount
$129,800.00
Summary
Field spectroradiometer and associated equipment for quantitative measurement and characterization of biophysical features and calibration of remotely sensed imagery. This set of equipment will improve and extend existing research capabilities in the field of in-situ remote sensing research and applications, for both aquatic and terrestrial environments. It will contribute to knowledge regarding terrestrial, coastal and estuarine vegetation and linkages to environmental change and will assist in ....Field spectroradiometer and associated equipment for quantitative measurement and characterization of biophysical features and calibration of remotely sensed imagery. This set of equipment will improve and extend existing research capabilities in the field of in-situ remote sensing research and applications, for both aquatic and terrestrial environments. It will contribute to knowledge regarding terrestrial, coastal and estuarine vegetation and linkages to environmental change and will assist in the development of new algorithms, indices and techniques of vegetation discrimination from remotely sensed imagery. It will help in the understanding of reflectance in plants under stress or pest damage. The spectroradiometer will enable the group to expand applications in the field of urban fire hazard mapping, precision agriculture, crop physiology, species mapping, viticulture and canopy modelling.Read moreRead less
Integrating the rice industry with biodiversity conservation: the spatial ecology of waterfowl in agricultural and natural landscapes. Waterfowl damage to rice crops is a significant problem for the rice industry worldwide. The management and conservation of waterfowl requires an explicit understanding of the effect of rice bays on habitat structure for waterfowl and how these interact with population processes operating at broad scales. This project will analyse the spatial ecology of waterfowl ....Integrating the rice industry with biodiversity conservation: the spatial ecology of waterfowl in agricultural and natural landscapes. Waterfowl damage to rice crops is a significant problem for the rice industry worldwide. The management and conservation of waterfowl requires an explicit understanding of the effect of rice bays on habitat structure for waterfowl and how these interact with population processes operating at broad scales. This project will analyse the spatial ecology of waterfowl in agricultural and natural landscapes in the Murray-Darling Basin. Specifically we will (1) track waterfowl, (2) analyse wetland distribution at fine and broad scales, (3) develop spatial models to describe the relationships between waterfowl movements and wetland distribution, including rice bays, and (4) develop models of agronomic risk based on landscape structure and the known responses of waterfowl.Read moreRead less
Novel technologies to resolve interactions between arbuscular mycorrhizal (AM) fungi, phosphate fertilisers and root disease in wheat production. Soils in Australia are often phosphate (P) deficient. Fertiliser P costs ~$1.5 billion pa, yet much is wasted because of fixation in soils. This waste must be stopped and soil reserves unlocked, because supplies of rock phosphate for fertiliser manufacture will run out in the next ~70 years. We will investigate the potential of combining two approaches ....Novel technologies to resolve interactions between arbuscular mycorrhizal (AM) fungi, phosphate fertilisers and root disease in wheat production. Soils in Australia are often phosphate (P) deficient. Fertiliser P costs ~$1.5 billion pa, yet much is wasted because of fixation in soils. This waste must be stopped and soil reserves unlocked, because supplies of rock phosphate for fertiliser manufacture will run out in the next ~70 years. We will investigate the potential of combining two approaches to maximise P fertiliser use by wheat - application of new, fluid fertiliser formulations and soil management to increase populations of beneficial arbuscular mycorrhizal (AM) fungi that have large effects on the way plants absorb P from soil. A new DNA-based method to monitor AM fungal communities will be applicable both in agricultural management and studies of AM fungal biodiversity.Read moreRead less
Dynamic signaling pathways of dispersal in bacterial biofilms. This Breakthrough Science project will result in an increased understanding of the molecular processes that govern biofilm development and dispersal. While the outcomes will be directly applicable where P. aeruginosa infections continue to cause health-threatening conditions, such as in Cystic Fibrosis chronic infections, it will also be instrumental for the rational design of novel products and strategies to control biofilms of othe ....Dynamic signaling pathways of dispersal in bacterial biofilms. This Breakthrough Science project will result in an increased understanding of the molecular processes that govern biofilm development and dispersal. While the outcomes will be directly applicable where P. aeruginosa infections continue to cause health-threatening conditions, such as in Cystic Fibrosis chronic infections, it will also be instrumental for the rational design of novel products and strategies to control biofilms of other single species or of mixed species populations in many other settings. Countless environmental, industrial and clinical applications will benefit from improved antimicrobial strategies and reduced usage of antibiotics.Read moreRead less
How do soils grow? Modelling soil development in the landscape. This project addresses the fundamental environmental issue of land degradation in Australia. The environment is both sensitive and diverse with uses from intensive agriculture, grazing, to large scale industrial. This project will build a model that will enable us to understand how soil forms and landscape evolves with time, to reconstruct the history of soil. The model will allow us to make the Australian populous aware of the frag ....How do soils grow? Modelling soil development in the landscape. This project addresses the fundamental environmental issue of land degradation in Australia. The environment is both sensitive and diverse with uses from intensive agriculture, grazing, to large scale industrial. This project will build a model that will enable us to understand how soil forms and landscape evolves with time, to reconstruct the history of soil. The model will allow us to make the Australian populous aware of the fragility of soil formation. This will lead to greater social awareness of our precarious position on the Australian landscape.Read moreRead less
Mechanisms of heavy metals sequestration and immobilization by goethite in multi-element environments. The research project will achieve critical goals of protecting river and ground water, and soil environments from toxic waste emissions from abandoned mine sites and acid sulphate soils. It will help in fomulating strategies to overcome the problems of environmentally significant heavy metals in contaminated soil environments.
Maintenance of Australia's soil resource - water, microbial diversity and function. Water availability is the major limitation to biological activity in semi-arid regions of Australia. We aim to quantify the dynamic relationships between organic matter cycling, microbial diversity and function in relation to seasonality, drought and land management. This will lead to a comprehensive understanding of how water mediates the diversity of soil organisms and their associated functions. This is of sp ....Maintenance of Australia's soil resource - water, microbial diversity and function. Water availability is the major limitation to biological activity in semi-arid regions of Australia. We aim to quantify the dynamic relationships between organic matter cycling, microbial diversity and function in relation to seasonality, drought and land management. This will lead to a comprehensive understanding of how water mediates the diversity of soil organisms and their associated functions. This is of specific relevance to maintaining biodiversity within the unique soil ecosystems that have developed under Australian climatic conditions.Read moreRead less
The molecular biology and biochemistry of bacterial manganese oxidation. This project will further the understanding of bacterial manganese (Mn2+) oxidation. A multi-disciplinary approach will be used to further investigate the genetics and biochemistry of the Mn2+-oxidising systems of Pseudomonas putida, Leptothrix sp. and Pedomicrobium sp. This work will focus in particular on comparing the Mn2+-oxidising systems from unrelated bacteria. A combination of molecular biology, protein biochemis ....The molecular biology and biochemistry of bacterial manganese oxidation. This project will further the understanding of bacterial manganese (Mn2+) oxidation. A multi-disciplinary approach will be used to further investigate the genetics and biochemistry of the Mn2+-oxidising systems of Pseudomonas putida, Leptothrix sp. and Pedomicrobium sp. This work will focus in particular on comparing the Mn2+-oxidising systems from unrelated bacteria. A combination of molecular biology, protein biochemistry and spectroscopy will be used. This will be the first time that the enzymes of bacterial Mn2+-oxidation will have been characterised in such detail and will lead to a greater understanding of the process of bacterial manganese oxidation.Read moreRead less