A new paradigm for catchment management: detection, forecasting and management of water catchments with multiple steady states. Understanding the response and recovery of Australia's water catchments to climatic change and variability is become increasingly urgent. Our catchments are vulnerable because there is a fundamental gap in our understanding of how they recover from high or low rainfall periods. This project will: a) advance water management concepts; b) build tools to understand how and ....A new paradigm for catchment management: detection, forecasting and management of water catchments with multiple steady states. Understanding the response and recovery of Australia's water catchments to climatic change and variability is become increasingly urgent. Our catchments are vulnerable because there is a fundamental gap in our understanding of how they recover from high or low rainfall periods. This project will: a) advance water management concepts; b) build tools to understand how and when catchments might switch to new states when hit by a disturbance; and c) identify how best to build the buffering capacity to reduce the chance of a switch occurring. The project will make Australia's groundwater and streamflow resources more secure and make Australian researchers and water resource managers world leaders in the emerging science of catchment resilience.Read moreRead less
Understanding and modelling of interannual hydroclimatic variability in the context of historic streamflow. Recent persistently dry conditions in Australia have triggered water restrictions in major cities and re-emphasised the importance of water to this country. This project represents an integrated package of research that will enhance our understanding of interannual hydroclimatic variability, and its implications for land and water resources systems. The methodologies and model developed he ....Understanding and modelling of interannual hydroclimatic variability in the context of historic streamflow. Recent persistently dry conditions in Australia have triggered water restrictions in major cities and re-emphasised the importance of water to this country. This project represents an integrated package of research that will enhance our understanding of interannual hydroclimatic variability, and its implications for land and water resources systems. The methodologies and model developed here will directly lead to more informed decision making for sustainable use and management of Australia's increasingly scarce natural resources to cope with changing climate over a range of time scales. This is particularly important for Australia because of its higher interannual hydroclimate variability compared to elsewhere in the world.Read moreRead less
Narrowing the scatter and assessing the uncertainty of climate change projections of Australian river flows. Recent prolonged dry conditions in south-eastern Australia have triggered water restrictions in major cities, zero irrigation allocations in the Murray-Darling region and highlighted the importance of water to this country. This project represents an integrated package of research that will enhance our understanding of the uncertainty of future annual river flows, leading to more informed ....Narrowing the scatter and assessing the uncertainty of climate change projections of Australian river flows. Recent prolonged dry conditions in south-eastern Australia have triggered water restrictions in major cities, zero irrigation allocations in the Murray-Darling region and highlighted the importance of water to this country. This project represents an integrated package of research that will enhance our understanding of the uncertainty of future annual river flows, leading to more informed decision making for the sustainable management of Australia’s increasingly scarce water resources. The outcomes from this project are highly relevant to the national research priority “An Environmentally Sustainable Australia”, particularly priority goals “Water - a critical resource” and “Responding to climate change and variability”.Read moreRead less
Stable water isotopic simulation and analysis to improve Earth System models and deliver better predictions of Australian water resource vulnerability. As Australia's challenges in environmental sustainability rival those anywhere on Earth, we must be clever in our diagnosis of susceptibility and insightful in proposed remedies. Climate change and variability have impacts on people and society that must be managed effectively whatever their causes. Of importance to Australia is the availabilit ....Stable water isotopic simulation and analysis to improve Earth System models and deliver better predictions of Australian water resource vulnerability. As Australia's challenges in environmental sustainability rival those anywhere on Earth, we must be clever in our diagnosis of susceptibility and insightful in proposed remedies. Climate change and variability have impacts on people and society that must be managed effectively whatever their causes. Of importance to Australia is the availability of water for drinking and agriculture. The new, interdisciplinary ARC network for Earth System Science provides models for novel and synergistic research such as naturally occurring water isotopes as a tool for improving predictive skill and confidence. We exploit these and leverage international programs to improve regional hydro-climate and water resource understanding in Australia.Read moreRead less
A new flood design methodology for a variable and changing climate. The extreme temporal and spatial variability of Australia's rainfall affects the quantity and quality of water resources, the productivity of agricultural systems, and aquatic and terrestrial ecosystems. Given the impact of extreme events such as floods and the massive investment in water-related infrastructure, evaluation of these risks is an issue of national economic and environmental significance. Monte Carlo simulation tech ....A new flood design methodology for a variable and changing climate. The extreme temporal and spatial variability of Australia's rainfall affects the quantity and quality of water resources, the productivity of agricultural systems, and aquatic and terrestrial ecosystems. Given the impact of extreme events such as floods and the massive investment in water-related infrastructure, evaluation of these risks is an issue of national economic and environmental significance. Monte Carlo simulation techniques will quantify the risks associated with current and future climate change, and the combined risks that come from multiple sources, such as from coastal tides and storm runoff. This research will provide a new spatial framework for calculating risk as well as tools to evaluate flood risk.Read moreRead less
A Bayesian Hierarchical Approach for Simulating Multi-time Scale Hydrological Variability for Water Resource Planning. Assessments of future drought risks are dependent on simulations of hydrological inputs provided by stochastic models. The current models are limited to simulating variability at a single time scale using only local observed hydrological data. This data has only limited information on the long-term climate variability which is the cause of long-term severe droughts. The proposed ....A Bayesian Hierarchical Approach for Simulating Multi-time Scale Hydrological Variability for Water Resource Planning. Assessments of future drought risks are dependent on simulations of hydrological inputs provided by stochastic models. The current models are limited to simulating variability at a single time scale using only local observed hydrological data. This data has only limited information on the long-term climate variability which is the cause of long-term severe droughts. The proposed research will develop a new Bayesian framework for simulating multi-time scale variability in hydrological data. This will enable the dynamic processes which simulate long-term variability to be identified using auxiliary information in an uncertainty framework. This will provide water resource planners with more accurate assessments of long-term drought risks.
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Improving understanding of climate change and its impacts in Australia through detection and attribution of climate change. This research will quantify the contribution to Australian regional climate change due to greenhouse gases, which will assist policymakers in reaching decisions about policies on emission reductions or adaptation to greenhouse climate change. Improved estimates of uncertainties in future regional climate changes due to increasing greenhouse gases will allow better quantifi ....Improving understanding of climate change and its impacts in Australia through detection and attribution of climate change. This research will quantify the contribution to Australian regional climate change due to greenhouse gases, which will assist policymakers in reaching decisions about policies on emission reductions or adaptation to greenhouse climate change. Improved estimates of uncertainties in future regional climate changes due to increasing greenhouse gases will allow better quantification of their likely impacts, estimation of the costs or maximising any benefits from regional climate changes. Through collaboration with the Bureau of Meteorology and CSIRO, this research enhances Australia's capabilities in diagnostic analysis of climate variability and change, and aids the development and evaluation of new Australian climate models. Read moreRead less
Do terrestrial processes intensify Australian droughts ? Australia's agricultural productivity is strongly affected by climate, climate variability and climate change. Recent climate changes in Western Australia forced adaptation strategies costing $500 million while the anomalously intense 2002 Murray-Darling Basin drought significantly affected agriculture. Any further intensification of droughts would affect Australia's rural economy. This proposal will assess the role of terrestrial processe ....Do terrestrial processes intensify Australian droughts ? Australia's agricultural productivity is strongly affected by climate, climate variability and climate change. Recent climate changes in Western Australia forced adaptation strategies costing $500 million while the anomalously intense 2002 Murray-Darling Basin drought significantly affected agriculture. Any further intensification of droughts would affect Australia's rural economy. This proposal will assess the role of terrestrial processes, linked to increasing CO2, in causing the drought intensification and declines in rainfall. This will provide knowledge that will guide the development of future environmental management strategies.Read moreRead less
Understanding the effect of climate change on runoff variability and water resource systems performance. This project aims to assess the impacts of climate changes on annual runoff variability. Understanding variability of annual runoff is important in managing water resources, in catchment and stream management, and to researchers in hydrology, stream ecology and fluvial geomorphology. Expected outcomes from this research are an estimate of impact on the variability of annual runoff from futu ....Understanding the effect of climate change on runoff variability and water resource systems performance. This project aims to assess the impacts of climate changes on annual runoff variability. Understanding variability of annual runoff is important in managing water resources, in catchment and stream management, and to researchers in hydrology, stream ecology and fluvial geomorphology. Expected outcomes from this research are an estimate of impact on the variability of annual runoff from future climate change, improvement in understanding the processes that operate on the variability of annual runoff, and an assessment of the performance of water resource systems under a changing climate.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668400
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
A high-throughput stable isotope ratio mass spectrometer for water resource management and climate change studies. Cave speleothems are highly sensitive to climate and are widely used to investigate past climate variability. Many researchers in Australia are now employing speleothems to find out more about the long-term behaviour of the Australian climate system, especially regarding ENSO. However, progress is inhibited by a lack of appropriate instrumentation capable of meeting the unique deman ....A high-throughput stable isotope ratio mass spectrometer for water resource management and climate change studies. Cave speleothems are highly sensitive to climate and are widely used to investigate past climate variability. Many researchers in Australia are now employing speleothems to find out more about the long-term behaviour of the Australian climate system, especially regarding ENSO. However, progress is inhibited by a lack of appropriate instrumentation capable of meeting the unique demands of speleothem research. Our new mass spectrometer will provide precise, rapid and low-cost isotope analyses of speleothem samples, and in doing so generate exciting and important palaeoclimate data, particularly in the area of pre-instrumental rainfall histories.Read moreRead less