Zooplankton: the missing link in modelling the ocean carbon cycle. What is arguably the biggest gap in our ability to close the ocean carbon cycle, and thus improve future forecasts of carbon sequestration and fisheries? The answer is our modelling of zooplankton, the most abundant animals on Earth. This project aims to build a next-generation ecosystem model that resolves zooplankton groups, their traits and key processes, generating novel insights into carbon sequestration and fisheries. Expec ....Zooplankton: the missing link in modelling the ocean carbon cycle. What is arguably the biggest gap in our ability to close the ocean carbon cycle, and thus improve future forecasts of carbon sequestration and fisheries? The answer is our modelling of zooplankton, the most abundant animals on Earth. This project aims to build a next-generation ecosystem model that resolves zooplankton groups, their traits and key processes, generating novel insights into carbon sequestration and fisheries. Expected outcomes include new methods for zooplankton modelling, leading to a paradigm shift in how we model carbon cycling. This should provide significant benefits, including vastly improved estimates of carbon sequestration and fisheries production, vital for carbon budgets and food security in Australia and globally.Read moreRead less
Improving long term forecasts of tree growth in carbon farming projects. Australia is taking action to limit global warming, including use of "carbon farming" to capture CO2 using trees as natural carbon sinks. Limited knowledge on the growth rate of Mulga trees, a primary carbon sink, hampers our partner organisation’s ability to maximise carbon stores. The aim of this proposal is to use dendrochronology to inform novel predictive models for growth of mulga trees that will reduce uncertainty in ....Improving long term forecasts of tree growth in carbon farming projects. Australia is taking action to limit global warming, including use of "carbon farming" to capture CO2 using trees as natural carbon sinks. Limited knowledge on the growth rate of Mulga trees, a primary carbon sink, hampers our partner organisation’s ability to maximise carbon stores. The aim of this proposal is to use dendrochronology to inform novel predictive models for growth of mulga trees that will reduce uncertainty in carbon removal forecasts. The expected outcome will be significant and benefit our partner organisation and other agencies by providing improved forecasting of tree growth that will inform their decisions for investment in carbon farming and nature repair markets.Read moreRead less
Sex is important in adaptation to environmental change. Aims: This project will use novel experiments with the aim of determining the potential for plasticity to be adaptive with sexual selection and how non-genetic effects transfer across generations by establishing genomic mechanisms. Significance: Plasticity (or acclimation) is often hailed as the saviour for species in the face of rapid climate change, but it is problematic if it is not adaptive in nature. Expected outcomes: Expected outcome ....Sex is important in adaptation to environmental change. Aims: This project will use novel experiments with the aim of determining the potential for plasticity to be adaptive with sexual selection and how non-genetic effects transfer across generations by establishing genomic mechanisms. Significance: Plasticity (or acclimation) is often hailed as the saviour for species in the face of rapid climate change, but it is problematic if it is not adaptive in nature. Expected outcomes: Expected outcomes include an enhanced ability to predict adaptation of fish under environmental change. Benefits: This project will provide significant benefits to Australian and international communities that rely on fish for nutrition, economic and social values, through an improved evidence base to inform management.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100477
Funder
Australian Research Council
Funding Amount
$449,592.00
Summary
Quantifying climate change impacts for wetlands in agricultural landscapes. This project aims to quantify the impacts of changed water availability on wetland biodiversity. Research will focus on high conservation value wetlands in agricultural regions, which face significant climatic risk. Novel integration of biodiversity theory with hydroecological and spatial modelling is expected to generate new understanding of how water availability drives wetland diversity. Intended outcomes include new ....Quantifying climate change impacts for wetlands in agricultural landscapes. This project aims to quantify the impacts of changed water availability on wetland biodiversity. Research will focus on high conservation value wetlands in agricultural regions, which face significant climatic risk. Novel integration of biodiversity theory with hydroecological and spatial modelling is expected to generate new understanding of how water availability drives wetland diversity. Intended outcomes include new techniques to model wetland biodiversity, building of international collaborations and enhanced ability to support policy development to ameliorate climate-related wetland impacts. This should promote sustainable management of water and biodiversity in farmlands, benefitting productive capacity and environmental amenity.Read moreRead less
How climate-resilient are our temperate fisheries species? This project assesses the resilience of our temperate fisheries species to climate change. Using natural warming hotspots and volcanic CO2 vents we study populations of fisheries species that are already pre-adapted to future climate, and therefore could act as key populations for replenishment of future fisheries stocks. An innovative and interdisciplinary approach combines the ecology, genetics, behaviour, and physiology of fisheries s ....How climate-resilient are our temperate fisheries species? This project assesses the resilience of our temperate fisheries species to climate change. Using natural warming hotspots and volcanic CO2 vents we study populations of fisheries species that are already pre-adapted to future climate, and therefore could act as key populations for replenishment of future fisheries stocks. An innovative and interdisciplinary approach combines the ecology, genetics, behaviour, and physiology of fisheries species to evaluate their climate resilience. An advanced food web model will be developed to forecast changes to fisheries production in a future world. This provides a much-improved forecast of climate adaptation and managing future biodiversity and fisheries species through resilient genes and populations.Read moreRead less
Mapping climate change vulnerability of older Australians to extreme heat. Exposure to extreme heat is associated with negative health outcomes and has been recognized as a global health challenge in the context of climate change, especially among older people. While the direct heat-related mortality for older people reached a record high of 345,000 deaths worldwide in 2019, which was 80.6% higher than the 2000–05 average, there has been no detailed study in Australia. This project is to have a ....Mapping climate change vulnerability of older Australians to extreme heat. Exposure to extreme heat is associated with negative health outcomes and has been recognized as a global health challenge in the context of climate change, especially among older people. While the direct heat-related mortality for older people reached a record high of 345,000 deaths worldwide in 2019, which was 80.6% higher than the 2000–05 average, there has been no detailed study in Australia. This project is to have a national picture of the impact of extreme heat on the health outcomes of older people and associated healthcare costs at Statistical Area level 3 (SA3), to inform the design and implementation of tailored interventions to minimize the health risk and costs from extreme heat to protect the health of this vulnerable group. Read moreRead less
Physico-chemical effects on long-time fluid transport for CO2 geostorage. This project aims to develop an efficient multi-scale laboratory-based modelling framework for the analysis of nonequilibrium transport and reaction processes occurring in CO2 storage scenarios. In a significant technological advance two non-destructive analysis techniques, Xray computed tomography and nuclear magnetic resonance, are combined with pore-scale simulations to address uncertainties in dynamic wettability alter ....Physico-chemical effects on long-time fluid transport for CO2 geostorage. This project aims to develop an efficient multi-scale laboratory-based modelling framework for the analysis of nonequilibrium transport and reaction processes occurring in CO2 storage scenarios. In a significant technological advance two non-destructive analysis techniques, Xray computed tomography and nuclear magnetic resonance, are combined with pore-scale simulations to address uncertainties in dynamic wettability alteration occurring during gravity driven convection. Expected outcomes are the in-situ characterisation of solid-surface interactions and predictions of multi-phase fluid flow. The project benefits the Australian resources sector by improving injectivity, storage efficiency and security of supercritical CO2 storage projects.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100317
Funder
Australian Research Council
Funding Amount
$459,562.00
Summary
Single-cell metabolite imaging of the coral-microalgal symbiosis. Corals sustain some of the most diverse ecosystems on Earth but are at risk due to warming and acidifying oceans. Coral survival critically depends on the photosynthetic microalgae that live inside the coral and provide the coral with nutrients. Many aspects of this coral-algal relationship remain poorly defined. This project aims to unravel coral-algal interactions with single-cell imaging. Insights from extreme environment coral ....Single-cell metabolite imaging of the coral-microalgal symbiosis. Corals sustain some of the most diverse ecosystems on Earth but are at risk due to warming and acidifying oceans. Coral survival critically depends on the photosynthetic microalgae that live inside the coral and provide the coral with nutrients. Many aspects of this coral-algal relationship remain poorly defined. This project aims to unravel coral-algal interactions with single-cell imaging. Insights from extreme environment corals will reveal how these microalgae may facilitate coral survival under future climate change, providing vital information for reef managers and restoration practitioners. By establishing a novel method, databases and networks, this project will create a powerful forward momentum for coral-algal research.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100578
Funder
Australian Research Council
Funding Amount
$355,208.00
Summary
Next generation soil carbon satellite-based measurement for carbon markets. Soil carbon sequestration is a federal government priority to offset greenhouse gas emissions. Efforts to advance this opportunity are hindered by the high technical costs of soil carbon quantification. This project will develop an innovative and potentially commercialisable technology that integrates ground data, unmanned aerial vehicles (UAVs), satellites, Eddy covariance CO2 flux towers, soil carbon (C) models, and ar ....Next generation soil carbon satellite-based measurement for carbon markets. Soil carbon sequestration is a federal government priority to offset greenhouse gas emissions. Efforts to advance this opportunity are hindered by the high technical costs of soil carbon quantification. This project will develop an innovative and potentially commercialisable technology that integrates ground data, unmanned aerial vehicles (UAVs), satellites, Eddy covariance CO2 flux towers, soil carbon (C) models, and artificial intelligence (AI) to improve the accuracy of satellite-based soil C modelling. The project will provide an accurate and cost-effective solution to quantification of soil C changes to unlock a large potential of carbon offsets in rangelands in Australia and worldwide.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100831
Funder
Australian Research Council
Funding Amount
$835,302.00
Summary
Protecting aquifers in the race to net-zero carbon emissions. This project aims to address the key risk factor of gas leakage from carbon dioxide geological sequestration and hydrogen or compressed air renewable-energy storage. This project expects to develop innovative methods for monitoring gas leakage contamination into overlying Australian aquifer water resources. Expected outcomes of this project include a multidisciplinary method to detect leakages of CO2 and future stored-energy gases t ....Protecting aquifers in the race to net-zero carbon emissions. This project aims to address the key risk factor of gas leakage from carbon dioxide geological sequestration and hydrogen or compressed air renewable-energy storage. This project expects to develop innovative methods for monitoring gas leakage contamination into overlying Australian aquifer water resources. Expected outcomes of this project include a multidisciplinary method to detect leakages of CO2 and future stored-energy gases that can contaminate aquifers. This should provide significant benefits including enabling greenhouse gas emissions reduction while protecting Australian water resources. This is critically important for Great Artesian Basin aquifers that support over 180,000 Australians and overlie many planned storage sites.Read moreRead less