Discovery Early Career Researcher Award - Grant ID: DE240100533
Funder
Australian Research Council
Funding Amount
$434,727.00
Summary
Paris-compliance: assessing companies and portfolios. The aim of this research project is to turn the tide on misleading corporate climate pledges and systematise the assessment of companies' climate performance by using a science-based approach. A critical strategic priority urgently called for during recent international climate negotiations, the research conducted will be translated into a global platform where corporate Paris Compliance information will be shared openly and transparently. Th ....Paris-compliance: assessing companies and portfolios. The aim of this research project is to turn the tide on misleading corporate climate pledges and systematise the assessment of companies' climate performance by using a science-based approach. A critical strategic priority urgently called for during recent international climate negotiations, the research conducted will be translated into a global platform where corporate Paris Compliance information will be shared openly and transparently. This will bolster businesses’ climate action by outlining meaningful and effective decarbonisation pathways, allowing all stakeholders to make climate-safe decisions, and guiding policy makers to enforce the required changes for any business to become Paris-compliant. Read moreRead less
A theory for the vertical structure of tropical atmospheric circulations. The vertical structure of atmospheric circulations is a key determinant of rainfall patterns and climate, but model projections do not agree on how it will change in a warmer world. This project aims to discover the processes that control the vertical structure of tropical atmospheric circulations. It will combine theory development, analysis of observations, and targeted modelling to generate new knowledge of the mechanis ....A theory for the vertical structure of tropical atmospheric circulations. The vertical structure of atmospheric circulations is a key determinant of rainfall patterns and climate, but model projections do not agree on how it will change in a warmer world. This project aims to discover the processes that control the vertical structure of tropical atmospheric circulations. It will combine theory development, analysis of observations, and targeted modelling to generate new knowledge of the mechanisms affecting atmospheric circulations as the climate changes. This will allow for process-based identification of the most reliable climate models, facilitating increased confidence in future projections. More accurate tropical climate projections will benefit decision making for resource management in northern Australia.Read moreRead less
Novel tools for dating explosive volcanic eruptions in the critical window. This project will develop novel dating methods necessary for precise reconstruction of the eruption histories of super-volcanoes in the Asia-Pacific region over the last million years. The project outcomes will provide better models for predicting super-eruptions, thereby informing global climate change research, urban planning, and transport and telecommunications infrastructure engineering. Results will also improve ex ....Novel tools for dating explosive volcanic eruptions in the critical window. This project will develop novel dating methods necessary for precise reconstruction of the eruption histories of super-volcanoes in the Asia-Pacific region over the last million years. The project outcomes will provide better models for predicting super-eruptions, thereby informing global climate change research, urban planning, and transport and telecommunications infrastructure engineering. Results will also improve existing volcanic risk models used by insurers to quantify volcanic risks and calculate expected losses from volcanic eruptions, and greatly improve our ability to use eruption deposits as time markers for important events in human evolution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100611
Funder
Australian Research Council
Funding Amount
$393,664.00
Summary
Building community resilience to coastal climate hazards in Australia. More frequent and intense climate hazards are devastating Australian communities and are projected to worsen as climate changes. This project aims to develop and communicate urgently needed strategies to assist coastal communities to prepare for and respond to climate hazards. The relationship between local-scale connection and capacity to prepare and respond will be investigated using mixed methods research in at-risk commun ....Building community resilience to coastal climate hazards in Australia. More frequent and intense climate hazards are devastating Australian communities and are projected to worsen as climate changes. This project aims to develop and communicate urgently needed strategies to assist coastal communities to prepare for and respond to climate hazards. The relationship between local-scale connection and capacity to prepare and respond will be investigated using mixed methods research in at-risk communities. The research will deliver practical guidance to policy makers and managers that will optimise investments in building community resilience, advance the discipline of human geography, and benefit over 20 million Australians living in coastal areas by creating new knowledge on neighbourhood adaptive capacity.Read moreRead less
Understanding the impact of heat stress on cognition in a changing world. Our research will determine how anthropogenic climate change effects the ability of animals to process information in their environment. This research is significant because it directly addresses the growing issue of wildlife adaptation to climate change. If heat stress, reported widely in wildlife both in Australia and globally, impairs an animal's ability to respond to stimuli in its surrounding environment, then this ma ....Understanding the impact of heat stress on cognition in a changing world. Our research will determine how anthropogenic climate change effects the ability of animals to process information in their environment. This research is significant because it directly addresses the growing issue of wildlife adaptation to climate change. If heat stress, reported widely in wildlife both in Australia and globally, impairs an animal's ability to respond to stimuli in its surrounding environment, then this may cause lower reproductive success (eg lower predator detection rates) and population declines. We aim to identify critical temperature points beyond which the cognitive responses of animals decline rapidly - a significant finding for effective wildlife management priorities in the face of rapid climate change. Read moreRead less
Aqueous fluids in the deep earth. This project aims to improve our understanding of the role of fluids in controlling exchanges between the deep Earth, shallow rocks, and atmosphere. The project expects to investigate some of the key weaknesses in the thermodynamic models that are used to predict the behaviour of sulphur, carbon and metals in fluids at high pressure and temperature by using recent advances in computational and experimental (geo)chemistry. Integrated in large-scale geodynamic mod ....Aqueous fluids in the deep earth. This project aims to improve our understanding of the role of fluids in controlling exchanges between the deep Earth, shallow rocks, and atmosphere. The project expects to investigate some of the key weaknesses in the thermodynamic models that are used to predict the behaviour of sulphur, carbon and metals in fluids at high pressure and temperature by using recent advances in computational and experimental (geo)chemistry. Integrated in large-scale geodynamic models, the more reliable predictions will provide a more realistic assessment of the role of sulphur in controlling metal endowment and atmospheric chemistry through geological times. This should provide a useful guide for mineral exploration and planetary science.Read moreRead less
Mechanisms of proxy uptake in biominerals. This project plans to combine nano-analytical and aquaculture methods to develop new models that improve the reliability of paleoclimate reconstructions. The compositions of shells and skeletal materials of marine invertebrates are essential archives for quantifying temperatures and environmental conditions before modern climate records began. However, their reliability relies on understanding their formation. Emerging knowledge from material sciences i ....Mechanisms of proxy uptake in biominerals. This project plans to combine nano-analytical and aquaculture methods to develop new models that improve the reliability of paleoclimate reconstructions. The compositions of shells and skeletal materials of marine invertebrates are essential archives for quantifying temperatures and environmental conditions before modern climate records began. However, their reliability relies on understanding their formation. Emerging knowledge from material sciences indicates that these biocarbonates form via transient precursors rather than direct precipitation from seawater, profoundly affecting their interpretation. This project plans to transfer this new understanding to the earth sciences using nanoscale analytical methods including in vitro geochemical partitioning experiments. This would enable realistic models for geochemical proxy behaviour to be developed, significantly improving paleoclimate interpretations and assessments of ocean acidification effects on marine calcifiers.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE230100553
Funder
Australian Research Council
Funding Amount
$439,218.00
Summary
How does morality influence adaptation to climate change? This project aims to understand how morality influences adaptation to climate change in the Great Barrier Reef region. This project expects to generate new knowledge in the critical area of climate change adaptation, using an interdisciplinary approach. Expected outcomes include empirical insights into the connection between morality and adaptation, international collaborations, theory development, and refined methods to help identify lev ....How does morality influence adaptation to climate change? This project aims to understand how morality influences adaptation to climate change in the Great Barrier Reef region. This project expects to generate new knowledge in the critical area of climate change adaptation, using an interdisciplinary approach. Expected outcomes include empirical insights into the connection between morality and adaptation, international collaborations, theory development, and refined methods to help identify leverage points for incorporating morality into climate change decision-making. This should provide significant benefits, including a basis for policy-making in Australia and globally, that supports effective and just adaptation to climate change in ways that sustain livelihoods and respect local values.Read moreRead less
Millennial climate change in southern Australia during the Last Glacial. Abrupt warming and cooling events were a persistent feature of Earth's most recent climate cycle. Surprisingly, little is known of how these events affected the climate of Australia. This project will produce precisely dated reconstructions of rainfall and temperature trends in southern Australia during these events. These new terrestrial and ocean data will be compared with model simulations to determine how rapidly abrupt ....Millennial climate change in southern Australia during the Last Glacial. Abrupt warming and cooling events were a persistent feature of Earth's most recent climate cycle. Surprisingly, little is known of how these events affected the climate of Australia. This project will produce precisely dated reconstructions of rainfall and temperature trends in southern Australia during these events. These new terrestrial and ocean data will be compared with model simulations to determine how rapidly abrupt climate perturbations in the Northern Hemisphere reached our region, and the processes by which this occurred. The results will advance theory on how abrupt climate change propagates globally and provide a long-awaited climatic context for capstone events in Australia's natural history.Read moreRead less