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
Discovery Early Career Researcher Award - Grant ID: DE230100141
Funder
Australian Research Council
Funding Amount
$444,300.00
Summary
Anticipating ecological shifts in subtropical marine ecosystems. This project aims to unravel the causes of abrupt ecological change in the subtropics and predict their future in warming seas. Uniting large-scale field observation and modelling in a novel multi-species framework, this project seeks to quantify how warming and species interactions combine to escalate change on subtropical reefs at different stages of tropicalisation. Expected outcomes include new insights into the factors that pr ....Anticipating ecological shifts in subtropical marine ecosystems. This project aims to unravel the causes of abrupt ecological change in the subtropics and predict their future in warming seas. Uniting large-scale field observation and modelling in a novel multi-species framework, this project seeks to quantify how warming and species interactions combine to escalate change on subtropical reefs at different stages of tropicalisation. Expected outcomes include new insights into the factors that promote stability or change along subtropical coasts in Australia and Japan, where the influx of tropical species already has dramatic consequences. By comparing dynamics in Australia with tropicalisation hotspots in Japan, this project expects to anticipate future ecological shifts and benefit strategic management.Read moreRead less
Reef Breath Testing (RBT): exhaled volatile-gas biomarkers of coral health. This Project aims to uncover volatile gas "fingerprints" of coral reef taxa and how they are diagnostic of healthy reef functioning over space and time. All organisms emit distinct volatile gases via physiological fine-tuning and signalling as their environments change. Whilst coral reef taxa and coral reefs are hotspots for volatile gas emissions, which gases are produced, when and why, is entirely unexplored. This proj ....Reef Breath Testing (RBT): exhaled volatile-gas biomarkers of coral health. This Project aims to uncover volatile gas "fingerprints" of coral reef taxa and how they are diagnostic of healthy reef functioning over space and time. All organisms emit distinct volatile gases via physiological fine-tuning and signalling as their environments change. Whilst coral reef taxa and coral reefs are hotspots for volatile gas emissions, which gases are produced, when and why, is entirely unexplored. This project unites a multidisciplinary team of experts to, for the first time, couple volatile gas assessment, metabolic physiology and functional genomics techniques to transform understanding of how key volatile gases underpin coral resilience to stress and disease, which is essential to improve coral reef ecosystem management.Read moreRead less
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
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