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Origins and distributions of intraplate earthquakes. This project aims to investigate the behaviour and origin of intraplate earthquakes in Australia by developing a multi-million-year record of earthquakes using geological, geochronological, geospatial, seismological, statistical and numerical modelling data. It will use maximum credible magnitudes, maximum shaking intensities of intraplate earthquakes and spatiotemporal relationships between large prehistoric and contemporary earthquakes to im ....Origins and distributions of intraplate earthquakes. This project aims to investigate the behaviour and origin of intraplate earthquakes in Australia by developing a multi-million-year record of earthquakes using geological, geochronological, geospatial, seismological, statistical and numerical modelling data. It will use maximum credible magnitudes, maximum shaking intensities of intraplate earthquakes and spatiotemporal relationships between large prehistoric and contemporary earthquakes to improve models of future seismic hazard in Australia and globally. This will lead to improved predictions of future earthquake impacts in urban and natural environments and development of new paleoseismic techniques.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
Why do Australians still die during natural disasters? This project will test the idea that Australians do not adequately perceive the risks associated with natural disasters that threaten them. The outcomes of this project will include an Australian-specific risk perception model, more disaster resilient communities through improved social science understanding and improved disaster management policy.
Developing and testing a new dating tool for Quaternary science. This project plans to use cutting-edge instrumentation to develop a novel method for dating geological materials formed in a critical time window for which no dating technique currently exists. The last million years of Earth’s history has seen dramatic changes in global climate and environment, with catastrophic volcanic eruptions and numerous other natural processes shaping landforms and ecosystems. A major challenge for studying ....Developing and testing a new dating tool for Quaternary science. This project plans to use cutting-edge instrumentation to develop a novel method for dating geological materials formed in a critical time window for which no dating technique currently exists. The last million years of Earth’s history has seen dramatic changes in global climate and environment, with catastrophic volcanic eruptions and numerous other natural processes shaping landforms and ecosystems. A major challenge for studying these phenomena and their impacts is the dating of geological archives in the time window between 50 000 and 1 000 000 years. This project aims to develop a method for dating young volcanic rocks that can close this critical gap. The result would be a new dating tool with broad implications for the Quaternary sciences globally, including paleoclimate and paleoenvironmental reconstructions, natural hazards assessment, hominin evolution and archaeology.Read moreRead less
Using past climate extremes to guide infrastructure planning for the future. This project aims to analyse a 2000-year palaeoclimate record of single event and complex climate extremes to provide a long-term context for observed changes in climate extremes over recent decades. This project expects to generate new knowledge about long-term variability in the frequency and magnitude of climate extremes that occur on seasonal - decades time-scales. It also expects to provide information about com ....Using past climate extremes to guide infrastructure planning for the future. This project aims to analyse a 2000-year palaeoclimate record of single event and complex climate extremes to provide a long-term context for observed changes in climate extremes over recent decades. This project expects to generate new knowledge about long-term variability in the frequency and magnitude of climate extremes that occur on seasonal - decades time-scales. It also expects to provide information about complex extremes that involve multiple types of impacts (e.g. drought followed by flood, simultaneous drought and fire). Expected benefits of the project include improved understanding of climate extremes and improved risk estimates for the impacts of climate extremes on Australian government and industry infrastructure.Read moreRead less
Transforming decision making for rockfall hazard assessment. The aim is to transform conventional approaches to rockfall hazard prediction and mitigation. The management of risks posed by rockfall in Australia currently comes at significant cost and is suboptimal; predicted environmental changes are likely to worsen these hazards. Rockfall mechanics, remote sensing, and data-driven modelling will be combined with advanced visual technologies to deliver a novel, rapid, and reliable augmented real ....Transforming decision making for rockfall hazard assessment. The aim is to transform conventional approaches to rockfall hazard prediction and mitigation. The management of risks posed by rockfall in Australia currently comes at significant cost and is suboptimal; predicted environmental changes are likely to worsen these hazards. Rockfall mechanics, remote sensing, and data-driven modelling will be combined with advanced visual technologies to deliver a novel, rapid, and reliable augmented reality based rockfall hazard assessment tool. The outcomes are expected to streamline prediction, assessment, and mitigation – supporting practitioners and governments to proactively assess triggering conditions, evaluate risk, and apply robust solutions to improve safety, with substantial economic savings.Read moreRead less
New observational constraints on 2004-2007 rupture of the Sumatra megathrust. This project will develop innovative methods and generate new data for studying the rupture of giant subduction zone earthquakes and the generation of destructive tsunamis. This will lead to a better understanding of these phenomena that will enhance our ability to forecast, warn and map the hazards associated with them.
Earthquake hazard in Indonesia. This project will deliver breakthrough science that will strengthen Indonesia's ability to reduce its vulnerability to earthquake disasters. This will be achieved through a collaboration of Australian and Indonesian scientists who will fundamentally improve understanding of the destructive potential of Indonesian earthquakes.
Early Career Industry Fellowships - Grant ID: IE230100498
Funder
Australian Research Council
Funding Amount
$470,550.00
Summary
Optimising bioengineered structures for resilient shorelines and habitats. Nature-based solutions for shoreline protection through ecosystem restoration are increasingly being considered by foreshore managers. However, habitat restoration efforts are greatly hampered by the time it takes to fully revegetate an area. This project aims to develop a comprehensive understanding of wave interaction with bioengineered structures that provide shelter from wave impacts and promote revegetation and contr ....Optimising bioengineered structures for resilient shorelines and habitats. Nature-based solutions for shoreline protection through ecosystem restoration are increasingly being considered by foreshore managers. However, habitat restoration efforts are greatly hampered by the time it takes to fully revegetate an area. This project aims to develop a comprehensive understanding of wave interaction with bioengineered structures that provide shelter from wave impacts and promote revegetation and contribute to shoreline flood and erosion mitigation. Expected outcomes of this project include quantitative design guidelines and predictive tools that will help foreshore managers to develop more robust and cost-effective nature-based shoreline protection strategies. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100062
Funder
Australian Research Council
Funding Amount
$404,000.00
Summary
What's shaking down under? This project aims to determine the underlying cause of recent earthquake activity in central Australia. Of all the stable continents, Australia is surprisingly seismically active, with intra-plate earthquakes occurring relatively frequently. However, these are unpredictable, placing lives and infrastructure at risk. This project offers the opportunity to use a new seismic experiment to improve detection of small events that may warn of a more dangerous earthquake to co ....What's shaking down under? This project aims to determine the underlying cause of recent earthquake activity in central Australia. Of all the stable continents, Australia is surprisingly seismically active, with intra-plate earthquakes occurring relatively frequently. However, these are unpredictable, placing lives and infrastructure at risk. This project offers the opportunity to use a new seismic experiment to improve detection of small events that may warn of a more dangerous earthquake to come, and provide sub-surface imaging of the hidden crustal boundaries and faults that are ultimately responsible. Benefits will include improved hazard assessment, and a new predictive model for exploration that relates regional seismicity, crustal faults, and mineral systems.Read moreRead less