Discovery Early Career Researcher Award - Grant ID: DE190100636
Funder
Australian Research Council
Funding Amount
$401,202.00
Summary
Integrating genomics into native fish management to promote persistence. This project aims to improve predictions of the effects of environmental change on the long-term survival of wildlife, using native fish as a case study. By integrating genomics into biodiversity models, this project expects to generate fundamental knowledge of processes underpinning long-term survival and is a big advance on traditional biodiversity models that consider only occurrence or abundance. Expected outcomes inclu ....Integrating genomics into native fish management to promote persistence. This project aims to improve predictions of the effects of environmental change on the long-term survival of wildlife, using native fish as a case study. By integrating genomics into biodiversity models, this project expects to generate fundamental knowledge of processes underpinning long-term survival and is a big advance on traditional biodiversity models that consider only occurrence or abundance. Expected outcomes include insights into fish responses to environmental conditions and new tools to predict long-term survival of wildlife. These tools will guide cost-effective delivery of environmental water in the Murray-Darling Basin, and wider uptake should promote the long-term effectiveness of conservation efforts for many species.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100752
Funder
Australian Research Council
Funding Amount
$453,582.00
Summary
Reducing greenhouse gas emissions from Australian farm dams. There is an untapped potential to reduce greenhouse gas emissions from millions of Australian farm dams. This project aims to quantify the nation-wide carbon footprint of farm dams and develop low-cost strategies for “greener” practices. Contributing to Australia’s commitment to tackle climate change, this project aspires to empower farmers to significantly reduce the carbon footprint of their farm dams. It will also inform on the econ ....Reducing greenhouse gas emissions from Australian farm dams. There is an untapped potential to reduce greenhouse gas emissions from millions of Australian farm dams. This project aims to quantify the nation-wide carbon footprint of farm dams and develop low-cost strategies for “greener” practices. Contributing to Australia’s commitment to tackle climate change, this project aspires to empower farmers to significantly reduce the carbon footprint of their farm dams. It will also inform on the economic viability of alternative management strategies for mitigating farm dam emissions and provide recommendations for financial incentives. This project should enhance the capacity of Australia to meet its carbon reduction targets and mitigate anthropogenic climate change.Read moreRead less
Natural flood management: Nature-based flood mitigation in the 21st Century. The 2021-22 floods in Eastern Australia revealed the vulnerability of rivers to climate extremes. To prepare for a future with more intense floods, we must integrate nature-based flood mitigation strategies into river management. This project aims to address the potential of using Natural Flood Management (NFM) as a 21st Century flood mitigation solution. NFM uses natural processes to slow floods, reduce erosion, and mi ....Natural flood management: Nature-based flood mitigation in the 21st Century. The 2021-22 floods in Eastern Australia revealed the vulnerability of rivers to climate extremes. To prepare for a future with more intense floods, we must integrate nature-based flood mitigation strategies into river management. This project aims to address the potential of using Natural Flood Management (NFM) as a 21st Century flood mitigation solution. NFM uses natural processes to slow floods, reduce erosion, and minimise flood risk. Collaborating with NSW government partners the project expects to deliver scientific evidence for NFM and solutions for implementation in river rehabilitation, planning and community capacity building. The results will impact society's ability to adapt, reduce economic costs, and benefit the environment.Read moreRead less
Male-male competition vs female choice: same-same or something different? This project aims to increase our understanding of the phenotypic, genetic and genomic outcomes of evolution, by both enhancing, and reversing, sexual selection in laboratory fruit flies. In doing so, this project expects to separate the entangled effects of female choice and male competition, generating new knowledge in evolutionary ecology and genetics. Expected outcomes of this project include identifying the separate m ....Male-male competition vs female choice: same-same or something different? This project aims to increase our understanding of the phenotypic, genetic and genomic outcomes of evolution, by both enhancing, and reversing, sexual selection in laboratory fruit flies. In doing so, this project expects to separate the entangled effects of female choice and male competition, generating new knowledge in evolutionary ecology and genetics. Expected outcomes of this project include identifying the separate molecular effects on the genome of selection through male competition and female choice. This should provide significant benefits in understanding the role of different forms of sexual selection in removing mutations and maintaining population fitness: vital factors in securing the long term viability of vulnerable species.Read moreRead less
Resolving the role of kelp in blue carbon cycles to enable management. We aim to uncover how kelp forests contribute to carbon storage, biodiversity enhancement and nutrient mitigation in Australia. We will combine mapping and modelling to identify local variation in kelp carbon stocks and sequestration potential and verify kelp carbon export to deep ocean sinks through genetic tracing in seawater and sediments. Co-benefits will be identified through nutrient experiments and reef surveys. We wil ....Resolving the role of kelp in blue carbon cycles to enable management. We aim to uncover how kelp forests contribute to carbon storage, biodiversity enhancement and nutrient mitigation in Australia. We will combine mapping and modelling to identify local variation in kelp carbon stocks and sequestration potential and verify kelp carbon export to deep ocean sinks through genetic tracing in seawater and sediments. Co-benefits will be identified through nutrient experiments and reef surveys. We will also assess the risk that calcification and production of halogenic gas within the kelp forest could offset its climate mitigation potential. Project outcomes will enable management to consider kelp ecosystem services broadly and optimize our capacity to meet current emission reduction and biodiversity commitments.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101029
Funder
Australian Research Council
Funding Amount
$462,763.00
Summary
A global exploration of microbial carbon breakdown in wetland ecosystems. This project aims to investigate how plant litter breakdown in wetlands controls soil carbon preservation by identifying the climatic, environmental and microbial drivers of decomposition on a global scale. This project will generate new knowledge in the area of freshwater and coastal wetland ecology using interdisciplinary approaches in biogeochemistry and microbial ecology. Outcomes of this project include novel global d ....A global exploration of microbial carbon breakdown in wetland ecosystems. This project aims to investigate how plant litter breakdown in wetlands controls soil carbon preservation by identifying the climatic, environmental and microbial drivers of decomposition on a global scale. This project will generate new knowledge in the area of freshwater and coastal wetland ecology using interdisciplinary approaches in biogeochemistry and microbial ecology. Outcomes of this project include novel global datasets that will identify why some wetlands preserve carbon better than others and what management practices can enhance sequestration capacity. This should provide significant benefits, including advancing carbon-cycling models and predictions, and improving capacity to manage and restore wetland function.Read moreRead less
Formation and stabilisation of coastal blue carbon. Blue carbon is organic carbon stored within coastal vegetated ecosystems. This project will examine the composition, formation and dynamics of blue carbon in a range of coastal ecosystems. Combining advanced analytical chemistry with environmental microbiology, we will discover how blue carbon is stabilised and destabilised, a critical factor in nature-based climate change mitigation strategies. Further, we will gain a quantitative understandin ....Formation and stabilisation of coastal blue carbon. Blue carbon is organic carbon stored within coastal vegetated ecosystems. This project will examine the composition, formation and dynamics of blue carbon in a range of coastal ecosystems. Combining advanced analytical chemistry with environmental microbiology, we will discover how blue carbon is stabilised and destabilised, a critical factor in nature-based climate change mitigation strategies. Further, we will gain a quantitative understanding of blue carbon contributions to carbon cycling, providing enhanced modeling and prediction of climate-cycle feedbacks in response to biotic and environmental change. This research will significantly benefit Australia’s effective management of coastal vegetated ecosystems for maximum carbon offsets.Read moreRead less
Blue carbon potential of the Great Southern Reef. As one of Australia’s largest vegetated coastal ecosystems, kelp forests provide substantial climate mitigation opportunities. Although kelp carbon is ubiquitous in the deep ocean, the mechanism of transport and amount of kelp carbon reaching deep sinks remains largely unknown, significantly hampering their inclusion in ocean carbon budgets and mitigation action. We will use Australia-wide field data on kelp export, cross-shelf measurements of tr ....Blue carbon potential of the Great Southern Reef. As one of Australia’s largest vegetated coastal ecosystems, kelp forests provide substantial climate mitigation opportunities. Although kelp carbon is ubiquitous in the deep ocean, the mechanism of transport and amount of kelp carbon reaching deep sinks remains largely unknown, significantly hampering their inclusion in ocean carbon budgets and mitigation action. We will use Australia-wide field data on kelp export, cross-shelf measurements of transport and decay, coastal ocean circulation and future distribution models to vastly improve estimates of kelp carbon transfer to deep ocean sinks. Our comprehensive data-driven assessment of kelp carbon sequestration aims to uncover the carbon sink capacity of seaweed forests now and in the futureRead moreRead less
Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understandin ....Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understanding of how microbes control seagrass health and an enhanced capacity to develop effective restoration strategies for Australia's valuable seagrass ecosystems. Benefits include improving the extensive environmental, economic, social/cultural services Australian communities derive from seagrass ecosystems.Read moreRead less
Anaerobic methane oxidation in the deep sub-seafloor microbial biosphere. Microbes that control the emission of the greenhouse gas methane from the seafloor to the Earth's atmosphere effectively slow global warming. This project aims to understand the microbial controls for this process to improve an understanding of this planet's natural carbon cycle, and yield valuable information for marine CO2 geosequestration strategies.