Diagnosing river health using invertebrate traits and DNA barcodes. Diagnosing river health using invertebrate traits and DNA barcodes. This project aims to develop indices that link change in invertebrate communities to specific environmental stressors, and combine these indices with innovative, low cost molecular approaches to species identification to rapidly identify the causes of decline. River health assessment methods, usually based on aquatic invertebrates, identify if rivers are impaire ....Diagnosing river health using invertebrate traits and DNA barcodes. Diagnosing river health using invertebrate traits and DNA barcodes. This project aims to develop indices that link change in invertebrate communities to specific environmental stressors, and combine these indices with innovative, low cost molecular approaches to species identification to rapidly identify the causes of decline. River health assessment methods, usually based on aquatic invertebrates, identify if rivers are impaired but must be developed to identify the causes of decline. The intended outcomes are improved sustainable water resource management within and among states, and improved natural resource policy development.Read moreRead less
Improved biomonitoring of urban freshwater ecosystems using DNA barcodes. This project aims to provide rapid diagnostic detection of environmental change in aquatic ecosystems at reduced cost. Next-generation sequencing (NGS) can transform monitoring of aquatic ecosystems by identifying many species in multiple biological samples. This project aims to use NGS technology to identify macroinvertebrate species as biological indicators in urban freshwater ecosystems to provide more rapid, sensitive ....Improved biomonitoring of urban freshwater ecosystems using DNA barcodes. This project aims to provide rapid diagnostic detection of environmental change in aquatic ecosystems at reduced cost. Next-generation sequencing (NGS) can transform monitoring of aquatic ecosystems by identifying many species in multiple biological samples. This project aims to use NGS technology to identify macroinvertebrate species as biological indicators in urban freshwater ecosystems to provide more rapid, sensitive and cost-effective monitoring compared to traditional methods. The project uses DNA barcodes that identify species to detect species in samples processed with NGS. The project also plans to use previously collected samples to explore species diversity and detect indicator species.Read moreRead less
Revolutionising biodiversity monitoring in freshwater ecosystems using environmental DNA. Australian biodiversity is declining at an unprecedented rate and freshwater species are particularly at risk. Effective conservation of freshwater biodiversity depends on reliable, accurate and cost-efficient monitoring techniques for assessing species communities and key environmental assets and threats. However, current techniques are inefficient, expensive and highly invasive. This project aims to utili ....Revolutionising biodiversity monitoring in freshwater ecosystems using environmental DNA. Australian biodiversity is declining at an unprecedented rate and freshwater species are particularly at risk. Effective conservation of freshwater biodiversity depends on reliable, accurate and cost-efficient monitoring techniques for assessing species communities and key environmental assets and threats. However, current techniques are inefficient, expensive and highly invasive. This project aims to utilise a novel methodology known as environmental DNA to revolutionise biodiversity surveys in freshwater environments, and aims to lead to a substantial increase in positive conservation outcomes through cost-efficient and accurate assessments of the distributions and abundances of both native and introduced species.Read moreRead less
From hazard identification to risk management. From hazard identification to risk management. This project aims to explore health risks from water- and sediment-borne bacteria to recreational users of urban rivers, using a suite of novel molecular microbiological and in-vitro assays and microbial risk assessment modelling. This project also aims to develop source tracking methods to mitigate and manage these risks. The number of bacterial-related water-borne outbreaks associated with recreationa ....From hazard identification to risk management. From hazard identification to risk management. This project aims to explore health risks from water- and sediment-borne bacteria to recreational users of urban rivers, using a suite of novel molecular microbiological and in-vitro assays and microbial risk assessment modelling. This project also aims to develop source tracking methods to mitigate and manage these risks. The number of bacterial-related water-borne outbreaks associated with recreational activities is rising, but waterway managers are under pressure to re-open these rivers for recreation. The project is expected to benefit urban communities by ensuring waterway managers make informed decisions about river recreation.Read moreRead less
A new-generation flood forecasting system using observations from space. Floods are dangerous and expensive, costing Australia more than any other cause of natural disaster. This project will use satellite measurements of soil moisture and rainfall along with computer models to improve the Bureau of Meteorology’s predictions of floods in rivers. Better flood forecasts will reduce costs and save lives.
Taking eDNA underground: transforming assessment of subterranean ecosystems. This project aims to improve Environmental Impact Assessment and monitoring of subterranean ecosystems by developing a rigorous, credible and practicable environmental DNA assessment framework. Resource companies in Western Australia are mandated to assess groundwater biodiversity under Environmental Protection legislation. Current surveys are time-consuming (expensive) and biased toward common taxa. For regulators, sta ....Taking eDNA underground: transforming assessment of subterranean ecosystems. This project aims to improve Environmental Impact Assessment and monitoring of subterranean ecosystems by developing a rigorous, credible and practicable environmental DNA assessment framework. Resource companies in Western Australia are mandated to assess groundwater biodiversity under Environmental Protection legislation. Current surveys are time-consuming (expensive) and biased toward common taxa. For regulators, stakeholders and industry involved in this project we will provide real-world information and cost savings through innovation in understanding patterns in species boundaries and detection of subterranean fauna. The outcomes will be directly applicable to monitoring subterranean ecosystems across Australia and internationally.Read moreRead less
Revolutionising water-quality monitoring in the information age. In today’s information age, automated low-cost sensors distributed in the environment have the potential to revolutionise the way we monitor and manage air, water and soil. This project aims to develop novel statistical methods to detect anomalies in the data generated from these in-situ sensors with computationally efficient modelling on river networks through space and time, with the applied goals of automating anomaly detection ....Revolutionising water-quality monitoring in the information age. In today’s information age, automated low-cost sensors distributed in the environment have the potential to revolutionise the way we monitor and manage air, water and soil. This project aims to develop novel statistical methods to detect anomalies in the data generated from these in-situ sensors with computationally efficient modelling on river networks through space and time, with the applied goals of automating anomaly detection in water-quality data and generating predictions of sediment and nutrient concentrations throughout river networks in near-real time. This will represent a fundamental increase in scientific knowledge, which will be immediately useful in the domains of aquatic science, environmental monitoring, and statistics.Read moreRead less
From environmental monitoring to management: extracting knowledge about environmental events from sensor data. New, high-detail sources of environmental sensor data are useless without new methods for identifying patterns and extracting knowledge from that data. This project will develop improved techniques for interacting with environmental sensor data to assist environmental scientists and manager in understand the important events that are occurring.
Predicting water quality at the catchment scale: learning from two decades of monitoring. Poor water quality affects many rivers and receiving waters such as the Great Barrier Reef and Gippsland Lakes. This project aims to use Bayesian hierarchical models of statewide water quality data to quantify the effects of a range of factors on stream water quality including climate, land use, river flow, vegetation cover, etcetera. The analysis intends to extract information from the entire data set rath ....Predicting water quality at the catchment scale: learning from two decades of monitoring. Poor water quality affects many rivers and receiving waters such as the Great Barrier Reef and Gippsland Lakes. This project aims to use Bayesian hierarchical models of statewide water quality data to quantify the effects of a range of factors on stream water quality including climate, land use, river flow, vegetation cover, etcetera. The analysis intends to extract information from the entire data set rather than concentrating on individual sites. It intends to underpin a new predictive capacity including response to land use and management changes and climatic variations based on long-term data sets, as well as a water quality prediction capability. It is intended that the models developed will jointly model a range of inter-related water quality parameters.Read moreRead less
Monitoring organic matter in drinking water systems using fluorescence spectroscopy: improved early warning, process optimisation and water quality. Climate change is contributing to elevated organic matter (OM) concentrations in drinking water supplies. If insufficiently treated, OM can lead to unacceptable concentrations of disinfection by-products, considered to be potential carcinogens, as well as taste and odour problems and bacterial re-growth in the distribution system. Currently availabl ....Monitoring organic matter in drinking water systems using fluorescence spectroscopy: improved early warning, process optimisation and water quality. Climate change is contributing to elevated organic matter (OM) concentrations in drinking water supplies. If insufficiently treated, OM can lead to unacceptable concentrations of disinfection by-products, considered to be potential carcinogens, as well as taste and odour problems and bacterial re-growth in the distribution system. Currently available on-line monitoring techniques give limited information regarding the nature of OM; however, fluorescence spectroscopy has shown promise in this regard. Hence, this project aims to provide an on-line monitoring protocol utilising fluorescence to aid utilities in their provision of safe drinking water, thus addressing the National Research Priority goal water – a critical resource.Read moreRead less