Identifying regions of high drought mortality risk for tree species in NSW. Trees define our landscapes and are crucial for ecosystem services including biodiversity, carbon sequestration and prevention of soil erosion. Drought is a major threat to tree survival across Australia and is being exacerbated by rising temperatures and changing rainfall patterns due to climate change. This project aims to calculate the risk of drought mortality for key tree species across New South Wales in current an ....Identifying regions of high drought mortality risk for tree species in NSW. Trees define our landscapes and are crucial for ecosystem services including biodiversity, carbon sequestration and prevention of soil erosion. Drought is a major threat to tree survival across Australia and is being exacerbated by rising temperatures and changing rainfall patterns due to climate change. This project aims to calculate the risk of drought mortality for key tree species across New South Wales in current and future climates. It aims to integrate four independent, complementary research streams to develop robust probabilistic risk profiles that account for variation in drought intensity and species resilience over landscapes. These risk profiles will be fundamental to conservation planning and land management across New South Wales.Read moreRead less
Forecasting live fuel moisture content, the on/off switch for forest fire. Dry forest fuels are a precursor of large bushfires. This research aims to develop, for the first time, a model to reliably forecast the moisture content of live fuels (e.g. the foliage and fine branches of shrubs and trees). This will be achieved by combining (i) satellite-derived estimates of live fuel moisture content, (ii) forecasts of soil moisture, and (iii) plant physiological responses to soil dryness. Forecasts o ....Forecasting live fuel moisture content, the on/off switch for forest fire. Dry forest fuels are a precursor of large bushfires. This research aims to develop, for the first time, a model to reliably forecast the moisture content of live fuels (e.g. the foliage and fine branches of shrubs and trees). This will be achieved by combining (i) satellite-derived estimates of live fuel moisture content, (ii) forecasts of soil moisture, and (iii) plant physiological responses to soil dryness. Forecasts of live fuel moisture content will deliver an early warning system of the risk of bushfires. These forecasts will also facilitate improved planning of prescribed burns: if fuels are too dry there is a risk of burns escaping, conversely, if fuels are too wet there is a risk that burns will fail to meet objectives.Read moreRead less
Has Twentieth Century warming changed southeastern Australia's fire regimes? This project will reconstruct extreme fire seasons and fire events for the past 500 years in three temperate regions of southeastern Australia. This baseline information will extend our historic records of fire, quantify the controls on fire in our landscapes and place recent catastrophic fire events in historical context.
Mechanistic responses of phosphorus-limited forests to CO2 enrichment. Carbon dioxide continues to accumulate in the atmosphere, driven by human emissions. The future fate of the global forest carbon sink, which significantly slows CO2 increase in the atmosphere, helping to dampen climate change, remains poorly constrained, hindering mitigation and adaptation planning. A key gap concerns the role of phosphorus, crucial in limiting the productivity of Australian woodlands and tropical forests. Mo ....Mechanistic responses of phosphorus-limited forests to CO2 enrichment. Carbon dioxide continues to accumulate in the atmosphere, driven by human emissions. The future fate of the global forest carbon sink, which significantly slows CO2 increase in the atmosphere, helping to dampen climate change, remains poorly constrained, hindering mitigation and adaptation planning. A key gap concerns the role of phosphorus, crucial in limiting the productivity of Australian woodlands and tropical forests. Model-data fusion based on the results of a crossed CO2 x P experiment in Eucalyptus forest - EucFACE - will help close this vital knowledge gap, and leverage new mechanistic knowledge in a leading global model used for climate and emissions assessment.Read moreRead less
Understanding population growth time lags in invasive species. This project will use data collected from wild animals, landholder surveys, and computer simulation models to understand why invasive chital deer (Axis axis) are suddenly increasing in number after many years of slow population growth. By combining multiple empirical datasets and developing new modelling techniques, we will generate a new method for understanding population trends in introduced species. The results of this study will ....Understanding population growth time lags in invasive species. This project will use data collected from wild animals, landholder surveys, and computer simulation models to understand why invasive chital deer (Axis axis) are suddenly increasing in number after many years of slow population growth. By combining multiple empirical datasets and developing new modelling techniques, we will generate a new method for understanding population trends in introduced species. The results of this study will allow Queensland Department of Agriculture and Fisheries and others to better predict invasive species growth rates, which will allow for better, and more cost effective control methods. Read moreRead less
Integrating climate adaptation into rainforest restoration plantings. This project aims to investigate the impact of within species adaptation to climate on restoratoin success in the Australian Wet Tropics. For a suite of six species of tropical tree frequently employed in rainforest restoration plantings in northeast Queensland, this project aims to test the hypothesis that collecting seed from populations in similar ecoclimatic settings to the planting site will result in superior seedling gr ....Integrating climate adaptation into rainforest restoration plantings. This project aims to investigate the impact of within species adaptation to climate on restoratoin success in the Australian Wet Tropics. For a suite of six species of tropical tree frequently employed in rainforest restoration plantings in northeast Queensland, this project aims to test the hypothesis that collecting seed from populations in similar ecoclimatic settings to the planting site will result in superior seedling growth and survival. The expected outcome is to provide practical advice to restoration practitioners about the importance of matching the provenance of seed source to planting sites, and opportunities for selecting provenances pre-adapted to predicted future climatic conditions at planting sites.Read moreRead less
Conserving and recovering the koala populations on NSW Far North Coast. Conserving and recovering the koala populations on NSW Far North Coast. This project aims to develop a novel, integrated socio-ecological approach for connecting landscapes and communities for the recovery of threatened koala populations on the New South Wales far north coast. This should increase understanding of how local landholders and land managers respond to koala recovery programs and why they respond positively and b ....Conserving and recovering the koala populations on NSW Far North Coast. Conserving and recovering the koala populations on NSW Far North Coast. This project aims to develop a novel, integrated socio-ecological approach for connecting landscapes and communities for the recovery of threatened koala populations on the New South Wales far north coast. This should increase understanding of how local landholders and land managers respond to koala recovery programs and why they respond positively and become engaged for the long-term. The intended outcome is a spatial prioritisation framework for species recovery that integrates social and ecological values, and increased global knowledge of how to recover declining wildlife populations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101484
Funder
Australian Research Council
Funding Amount
$379,500.00
Summary
How will Australian rainforest species cope with climate warming? This project plans to investigate how, and how much, rainforest tree species will adjust to warmer temperatures. Understanding the temperature dependence of physiological processes of Australian rainforest trees and how they are related to climate variation is critical. This should enable prediction of how species will adjust to warmer temperatures, what their thermal tolerances are and how future species distribution ranges may c ....How will Australian rainforest species cope with climate warming? This project plans to investigate how, and how much, rainforest tree species will adjust to warmer temperatures. Understanding the temperature dependence of physiological processes of Australian rainforest trees and how they are related to climate variation is critical. This should enable prediction of how species will adjust to warmer temperatures, what their thermal tolerances are and how future species distribution ranges may change.Read moreRead less
Using assisted evolution to win the war against invasive species. Invasive species disrupt ecosystem functioning, causing severe economic costs. This project investigates the use of native insects, alongside assisted evolution, as a novel approach to control invasive plants. Combining experimental and observational data we aim to accelerate adaptation already underway and entrained by selection from interactions between invasive plants and Australian insects. These data will not only address unr ....Using assisted evolution to win the war against invasive species. Invasive species disrupt ecosystem functioning, causing severe economic costs. This project investigates the use of native insects, alongside assisted evolution, as a novel approach to control invasive plants. Combining experimental and observational data we aim to accelerate adaptation already underway and entrained by selection from interactions between invasive plants and Australian insects. These data will not only address unresolved questions in evolutionary biology but will also provide knowledge on the role native insects can play in the biocontrol of invasive weeds. This will be crucial for conservation managers and agricultural practitioners dealing with plant movement and/or crop development under ongoing environmental change.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120103022
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Generalising a root-water uptake mechanism for successful land surface modelling. Understanding root functioning in Australian savanna ecosystems is critically important for successful resource management but such understanding is not represented in land surface models (LSMs). This project will incorporate root functioning into LSMs and improve our ability to manage water and carbon natural resources in a changing climate.