Coastal tropicalisation – adapting to novel ecosystems and trajectories. This project aims to quantify the impacts of a changing climate on key ecosystem functions of temperate reefs. As global temperate reefs respond to ocean warming, iconic and economically important kelp forests and associated fishes and invertebrates are being lost. Novel communities and never-before seen configurations of species are emerging in these systems. This project aims to characterise the new dynamics of these nove ....Coastal tropicalisation – adapting to novel ecosystems and trajectories. This project aims to quantify the impacts of a changing climate on key ecosystem functions of temperate reefs. As global temperate reefs respond to ocean warming, iconic and economically important kelp forests and associated fishes and invertebrates are being lost. Novel communities and never-before seen configurations of species are emerging in these systems. This project aims to characterise the new dynamics of these novel systems, and provide an understanding of how to maintain key ecosystem functions - primary productivity, fish production - that underpin the benefits that humans derive from our coastlines.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100828
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Mathematical models for Antarctic animal migrations in a changing climate. This project aims to build state-of-the-art mathematical models for movement processes of high conservation-value Antarctic penguins, seals, and whales. This will generate new capacity to predict the likelihood of changes in sea ice and ocean dynamics impacting important forage migration pathways. These outcomes address knowledge gaps highlighted in climate reporting on Polar Regions and will strategically position Austra ....Mathematical models for Antarctic animal migrations in a changing climate. This project aims to build state-of-the-art mathematical models for movement processes of high conservation-value Antarctic penguins, seals, and whales. This will generate new capacity to predict the likelihood of changes in sea ice and ocean dynamics impacting important forage migration pathways. These outcomes address knowledge gaps highlighted in climate reporting on Polar Regions and will strategically position Australia to create a forward-looking context for conservation management efforts under international treaty commitments.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
Discovery Early Career Researcher Award - Grant ID: DE200100900
Funder
Australian Research Council
Funding Amount
$426,718.00
Summary
When and where are temperate reef communities vulnerable to ocean warming? This project will test in the laboratory and the field, when and where ocean warming will exceed the thermal limits of marine species and why certain species show greater sensitivity to warming temperatures than others. This project expects to generate robust estimates about how temperature sensitivity varies between populations across species’ ranges and identify the ecological implications for habitat loss in areas wher ....When and where are temperate reef communities vulnerable to ocean warming? This project will test in the laboratory and the field, when and where ocean warming will exceed the thermal limits of marine species and why certain species show greater sensitivity to warming temperatures than others. This project expects to generate robust estimates about how temperature sensitivity varies between populations across species’ ranges and identify the ecological implications for habitat loss in areas where thermal limits differ between key species. Expected outcomes include an enhanced capacity to detect when and where vulnerability hotspots will emerge that could jeopardise the immense social, ecological, and economic value of Australia’s temperate reefs, next to which 70% of Australians live, along 8,000 km of coastline.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100144
Funder
Australian Research Council
Funding Amount
$446,548.00
Summary
Linking changes in plant-pollinator networks to plant reproduction. The project aims to investigate how human actions in agricultural landscapes affect the activity of pollinating insects and the consequence for the plants that rely on them for reproduction. The project seeks to reveal how the structure of plant-pollinator networks is related to the reproductive success of plants through the novel application of networks that describe patterns in species interactions. The knowledge gained from t ....Linking changes in plant-pollinator networks to plant reproduction. The project aims to investigate how human actions in agricultural landscapes affect the activity of pollinating insects and the consequence for the plants that rely on them for reproduction. The project seeks to reveal how the structure of plant-pollinator networks is related to the reproductive success of plants through the novel application of networks that describe patterns in species interactions. The knowledge gained from this study will enhance our ability to forecast the effects of insect declines for plant seed production in Australia and the world. The intended benefit is an improved capacity to identify vulnerable plant species and maintain pollination services in managed landscape for both wild and cultivated plant populations.Read moreRead less
Marine heatwaves drive loss of genetic diversity and selection in kelps. This project aims to unravel where and when marine heatwaves drive loss of genetic diversity and rapid directional selection in kelp forests. Although the devastating ecological impacts of marine heatwaves are well studied, empirical understanding of how marine heatwaves impact underlying evolutionary processes including adaptive capacity and resilience is lacking. This research will use a powerful combination of innovative ....Marine heatwaves drive loss of genetic diversity and selection in kelps. This project aims to unravel where and when marine heatwaves drive loss of genetic diversity and rapid directional selection in kelp forests. Although the devastating ecological impacts of marine heatwaves are well studied, empirical understanding of how marine heatwaves impact underlying evolutionary processes including adaptive capacity and resilience is lacking. This research will use a powerful combination of innovative heatwave analyses, cutting-edge genomics and physiological experiments to fill these knowledge gaps and represents a step change in our understanding of how kelp respond and adapt in multi-stressor seascapes. Results will pave the way for development of novel mitigation strategies to future-proof marine management. Read moreRead less
Carbon in - carbon out: can carbon inputs keep up with losses in peatland? This project aims to quantify the current and predict the future carbon balance of a high altitude, carbon-dense ecosystem, namely sub-alpine grassy peatland, by measuring how environmental variables including experimental warming control the fluxes of carbon and water into and out of the system. In this way, this project will produce new knowledge on the susceptibility of high-altitude peaty soils to climate change. Expe ....Carbon in - carbon out: can carbon inputs keep up with losses in peatland? This project aims to quantify the current and predict the future carbon balance of a high altitude, carbon-dense ecosystem, namely sub-alpine grassy peatland, by measuring how environmental variables including experimental warming control the fluxes of carbon and water into and out of the system. In this way, this project will produce new knowledge on the susceptibility of high-altitude peaty soils to climate change. Expected outcomes include an enhanced ability to predict future carbon accumulation rates and the resilience of the vital water-storage and filtration services provided by these systems. This project will enhance outputs from new infrastructure and assist planning for future flood and drought management across SE Australia.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100036
Funder
Australian Research Council
Funding Amount
$3,011,916.00
Summary
Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of ....Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of corals, and advance the microbial symbiosis discipline globally. Expected outcomes include healthier coral reefs through the use of more climate resilient coral stock in reef conservation and restoration initiatives.Read moreRead less
Pushing the envelope: does range size limit eucalypt tolerance to warming? This project aims to characterise the biogeographic constraints on the physiological flexibility of eucalypts to accommodate climate warming. Do temperature tolerances of diverse taxa vary predictably with native geographic range sizes and climate of origin? In addressing this question, the project expects to generate new knowledge on the comparative physiological responses of diverse eucalypt taxa to warming and heat wav ....Pushing the envelope: does range size limit eucalypt tolerance to warming? This project aims to characterise the biogeographic constraints on the physiological flexibility of eucalypts to accommodate climate warming. Do temperature tolerances of diverse taxa vary predictably with native geographic range sizes and climate of origin? In addressing this question, the project expects to generate new knowledge on the comparative physiological responses of diverse eucalypt taxa to warming and heat waves using controlled-environment studies and a unique facility at Western Sydney University for heat wave studies of large trees. Expected outcomes include an enhanced capacity to predict carbon exchange and growth responses of native trees to climate warming over large geographic scales.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100003
Funder
Australian Research Council
Funding Amount
$3,108,997.00
Summary
A unified dynamic vegetation model for Australia. This project aims to synthesise current theory and data to develop a predictive, process-based model for Australian vegetation dynamics in response to environmental change. The existing theory and data are extensive, but fragmented. This project will deliver a crucial missing link in Australian ecosystem science, unifying these data in an integrative quantitative framework that can identify the critical limiting factors for different vegetation t ....A unified dynamic vegetation model for Australia. This project aims to synthesise current theory and data to develop a predictive, process-based model for Australian vegetation dynamics in response to environmental change. The existing theory and data are extensive, but fragmented. This project will deliver a crucial missing link in Australian ecosystem science, unifying these data in an integrative quantitative framework that can identify the critical limiting factors for different vegetation types, and predict their dynamics and resilience. It will transform our understanding of Australian vegetation form and function, and place it in a global context, with significant ongoing benefits for land management, fire management, agriculture and conservation.Read moreRead less