Reading the past to predict future biodiversity: a deep-time perspective. The extent of human-moderated impact on ecosystems is rapidly increasing. To date, most current research in this field is based on short-term observations or experiments. By examining the characteristics of species and ecosystem response to climate change from a major geological Ice Age ~320-265 million years ago in eastern Australia, this study will investigate how marine species and ecological communities evolved in resp ....Reading the past to predict future biodiversity: a deep-time perspective. The extent of human-moderated impact on ecosystems is rapidly increasing. To date, most current research in this field is based on short-term observations or experiments. By examining the characteristics of species and ecosystem response to climate change from a major geological Ice Age ~320-265 million years ago in eastern Australia, this study will investigate how marine species and ecological communities evolved in response to repeated glacial/interglacial cycles and associated warming/cooling climate changes. Expected findings will help to better understand the long-term links between global warming/cooling climate regimes, sea levels, changing sea-water temperature and chemistry, and species and ecosystem responses to these drivers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100340
Funder
Australian Research Council
Funding Amount
$441,281.00
Summary
Identifying key fire drivers in Australia; biomass, climate or people. This project aims to provide a greater understanding of Australia’s bushfire risk in the face of climate change. By comparing fire occurrence in three Australian bioclimates across two millennial-scale time periods, one prior to human settlement and one during active Indigenous management, this research expects to define which factors — climate, vegetation profile, or landscape management —most impact fire frequency and sever ....Identifying key fire drivers in Australia; biomass, climate or people. This project aims to provide a greater understanding of Australia’s bushfire risk in the face of climate change. By comparing fire occurrence in three Australian bioclimates across two millennial-scale time periods, one prior to human settlement and one during active Indigenous management, this research expects to define which factors — climate, vegetation profile, or landscape management —most impact fire frequency and severity. Outcomes will likely create new knowledge on how past climates affected the Australian environment; enhance predictive ability for future fire risks under emerging climate scenarios; and provide new insights into how cultural burning can be incorporated into fire management plans to reduce catastrophic bushfires.Read moreRead less