Defend or retreat? Adapting to the impacts of sea level rise as a result of rapid climate change.
. Rapid sea level rise has been identified as a major threat to coastal Australia, where most of the Australian population lives. Our understanding and ability to respond to this threat is extremely limited at this point. This project will directly benefit Australian communities and businesses, specifically those in southeast Queensland by bringing together a team of distinguished, multidiscipli ....Defend or retreat? Adapting to the impacts of sea level rise as a result of rapid climate change.
. Rapid sea level rise has been identified as a major threat to coastal Australia, where most of the Australian population lives. Our understanding and ability to respond to this threat is extremely limited at this point. This project will directly benefit Australian communities and businesses, specifically those in southeast Queensland by bringing together a team of distinguished, multidisciplinary researchers and Super Science Fellows to explore the threats and challenges posed by rapidly rising sea levels. By building capacity and answering many urgent and difficult questions related to the legal, environmental and planning ramifications of sea level rise, this project will prepare communities and policymakers for the difficult times ahead.Read moreRead less
Reconciling competing objectives for the design of marine reserve networks: biodiversity, food security, and local equity in benefits. This project uses a decision-theoretic framework to balance the often conflicting marine conservation objectives of preserving biodiversity and building food security for local communities in the socially and ecologically complex region of the Coral Triangle. A new reserve design will boost biodiversity conservation and better support livelihoods.
Maximising carbon sequestration in freshwater wetlands. Maximising carbon sequestration in freshwater wetlands. This project aims to determine how manipulation of wetland hydrology can alter sulphur and iron cycling to inhibit methane emission and improve wetland net-carbon sequestration. Wetlands are among earth's most efficient ecosystems for carbon sequestration, but methane emission can offset this capacity. Redox cycling of sulphur and iron in wetlands can inhibit methane emission, but the ....Maximising carbon sequestration in freshwater wetlands. Maximising carbon sequestration in freshwater wetlands. This project aims to determine how manipulation of wetland hydrology can alter sulphur and iron cycling to inhibit methane emission and improve wetland net-carbon sequestration. Wetlands are among earth's most efficient ecosystems for carbon sequestration, but methane emission can offset this capacity. Redox cycling of sulphur and iron in wetlands can inhibit methane emission, but the precise biogeochemical processes and their efficiency are very poorly constrained due to a lack of studies—especially in Australian freshwater wetlands. This project is expected to inhibit methane emission in freshwater wetlands and maximise their net carbon sequestration efficiency.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
Conflicting temporalities of climate governance: a comparative sociology of policy design and operationalization in Australia and the United Kingdom. This project will investigate the ways in which climate policy in Australia and the United Kingdom deals with uncertainty in the timing of climate change and climate change impacts. It will evaluate the utility of various approaches to climate policy and the potential contradictions that arise between climate dynamics and the policy design.
Discovery Early Career Researcher Award - Grant ID: DE240100305
Funder
Australian Research Council
Funding Amount
$434,042.00
Summary
Unravelling the pathways of methane production and oxidation in mangroves. This project addresses a long-standing conundrum of why high methane emissions are sustained in saline coastal wetlands by identifying and quantifying methane production and oxidation processes in mangrove ecosystems. Using a novel combination of cutting-edge instrumentation for greenhouse gases, radiocarbon/stable isotope analysis, this project will generate a first complete picture of the mangrove methane cycle, to accu ....Unravelling the pathways of methane production and oxidation in mangroves. This project addresses a long-standing conundrum of why high methane emissions are sustained in saline coastal wetlands by identifying and quantifying methane production and oxidation processes in mangrove ecosystems. Using a novel combination of cutting-edge instrumentation for greenhouse gases, radiocarbon/stable isotope analysis, this project will generate a first complete picture of the mangrove methane cycle, to accurately quantify, for the first time, Australia’s contribution to global coastal mangrove emissions. The outcomes will establish currently lacking fundamental understanding of wetland methane cycling, advance global biogeochemical models, and improve strategies for natural climate solutions of coastal wetlands in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100854
Funder
Australian Research Council
Funding Amount
$356,761.00
Summary
An evidence-based approach to integrate evolutionary theory in conservation. This project aims to integrate evolutionary theory into conservation science to ensure management promotes the long-term resilience of biodiversity. The management of evolutionary risks and benefits is routinely left out of decision tools that identify optimal management strategies. By developing tools that integrate evolutionary theory into key conservation problems, this project is expected to significantly advance co ....An evidence-based approach to integrate evolutionary theory in conservation. This project aims to integrate evolutionary theory into conservation science to ensure management promotes the long-term resilience of biodiversity. The management of evolutionary risks and benefits is routinely left out of decision tools that identify optimal management strategies. By developing tools that integrate evolutionary theory into key conservation problems, this project is expected to significantly advance conservation science. It should provide managers with essential tools to support the persistence of biodiversity and thus long-term success of biodiversity conservation.Read moreRead less
Adaptation to carbon-tax-induced changes in energy demand in rural and regional Australia. The Clean Energy Bills will create a more sustainable environment but have a large impact on energy sectors. This project models the impact of the carbon tax and the responses of energy sectors.
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