Drivers and consequences of novel marine ecological communities. Marine ecological communities are exhibiting rapid change in response to human actions. This project aims to apply a newly developed statistical framework, and expects to uncover historical patterns in the emergence and persistence of new community states of two sets of marine taxa: reef-building coral, and marine plankton. Understanding how often marine communities shifted into these novel states in the absence of human activities ....Drivers and consequences of novel marine ecological communities. Marine ecological communities are exhibiting rapid change in response to human actions. This project aims to apply a newly developed statistical framework, and expects to uncover historical patterns in the emergence and persistence of new community states of two sets of marine taxa: reef-building coral, and marine plankton. Understanding how often marine communities shifted into these novel states in the absence of human activities, as well as the relative contribution of environmental and biological factors, will provide significant foundational knowledge. In addition, this project aims to provide flow-on benefits to environmental management to ensure ecosystems continue to provide beneficial services, which include fisheries and tourism.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100398
Funder
Australian Research Council
Funding Amount
$349,886.00
Summary
Advancing detection and understanding of anomalous ecological change. Human impacts are driving ecosystems into new, anomalous states. Reliably detecting these ecological anomalies is essential to better understand how ecosystems change over time, and effectively manage natural resources. This project aims to advance ecological anomaly detection using techniques from complex fields such as banking fraud, cybersecurity and video surveillance. Expected project outcomes will improve understanding o ....Advancing detection and understanding of anomalous ecological change. Human impacts are driving ecosystems into new, anomalous states. Reliably detecting these ecological anomalies is essential to better understand how ecosystems change over time, and effectively manage natural resources. This project aims to advance ecological anomaly detection using techniques from complex fields such as banking fraud, cybersecurity and video surveillance. Expected project outcomes will improve understanding of patterns and drivers of both biodiversity and ecosystem change. Tools to reliably detect anomalous changes in complex ecological systems will provide significant benefits to ecosystem management, conservation decision-making and environmental remediation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100692
Funder
Australian Research Council
Funding Amount
$414,814.00
Summary
Regime shifts from kelp forests to turfs: drivers, resilience and future. This project aims to apply a comparative experimental and analytical approach to quantify linkages among multiple stressors driving kelp forest loss and expansion of turfs across three continents. Transformations of kelp forests to turf reefs are associated with a profound loss of ecological productivity and function, with significant impacts for societies reliant on the biodiversity and functioning of kelp ecosystems. Fie ....Regime shifts from kelp forests to turfs: drivers, resilience and future. This project aims to apply a comparative experimental and analytical approach to quantify linkages among multiple stressors driving kelp forest loss and expansion of turfs across three continents. Transformations of kelp forests to turf reefs are associated with a profound loss of ecological productivity and function, with significant impacts for societies reliant on the biodiversity and functioning of kelp ecosystems. Field and laboratory experiments will be used to develop and test ‘green gravel’, a novel restoration tool that aims to overcome reinforcing feedbacks (lack spores and hard substrate) preventing recovery of kelp forests. This will provide significant benefits by identifying solutions to address loss of kelp forests in Australia and globally.Read moreRead less
Dispersal and recruitment of species across landscapes: a new synthesis. This project aims to ask: does failure to disperse successfully across landscapes limit the abundances and diversity of species in habitat patches? This is a central question in ecology. The project expects to generate new knowledge about the links between dispersal success and population numbers by using recent advances in river ecology that have overcome logistical barriers to hypothesis tests. Expected outcomes include n ....Dispersal and recruitment of species across landscapes: a new synthesis. This project aims to ask: does failure to disperse successfully across landscapes limit the abundances and diversity of species in habitat patches? This is a central question in ecology. The project expects to generate new knowledge about the links between dispersal success and population numbers by using recent advances in river ecology that have overcome logistical barriers to hypothesis tests. Expected outcomes include new insights into why dispersal failures occur and how they are associated with low population numbers. Benefits should include improved advice to conservation managers about extinction risks, and unique, tangible outcomes for fundamental ecological research in Australia that will spring from international collaboration.Read moreRead less
Diversity maintenance in patchy environments. This project aims to advance understanding of species coexistence and diversity maintenance in complex natural environments. Though diversity varies across patchy natural and human-created environments, the mechanistic drivers of these patterns remain poorly understood. This knowledge gap limits our ability to predict and manage responses of natural communities to environmental changes. Using data from threatened Western Australian wildflower communi ....Diversity maintenance in patchy environments. This project aims to advance understanding of species coexistence and diversity maintenance in complex natural environments. Though diversity varies across patchy natural and human-created environments, the mechanistic drivers of these patterns remain poorly understood. This knowledge gap limits our ability to predict and manage responses of natural communities to environmental changes. Using data from threatened Western Australian wildflower communities and novel ecological models of species coexistence, the project aims to deliver a mechanistic understanding of biological diversity, and provide fundamental knowledge needed to improve ecosystem management and restoration outcomes across Australia and globally.Read moreRead less
The costs and consequences of resistance to stress in microbial systems. The coexistence of antibiotic resistant and sensitive bacteria in microbial communities represents a paradox. Combining novel ecological models and competition experiments, this project aims to investigate how the pulsing of antibiotics and resources affects the coexistence of resistant and sensitive bacteria. This project expects to generate new knowledge into how the complex non-equilibrium dynamics of natural systems fee ....The costs and consequences of resistance to stress in microbial systems. The coexistence of antibiotic resistant and sensitive bacteria in microbial communities represents a paradox. Combining novel ecological models and competition experiments, this project aims to investigate how the pulsing of antibiotics and resources affects the coexistence of resistant and sensitive bacteria. This project expects to generate new knowledge into how the complex non-equilibrium dynamics of natural systems feeds back to regulate the spread of antibiotic resistance in microbial communities. This should advance our fundamental understanding of microbial competition, and provide a foundation for the development of new ecologically-aware strategies for managing resistance.Read moreRead less
Safeguarding coral reef fisheries for future food security. This Fellowship aims to address the vulnerability of coral reef fisheries in Australia and the Indo-Pacific by identifying fishery targets that benefit human nutrition and will persist despite declining coral habitats and rising water temperature. This project will advance knowledge on coral and fish responses to increasingly frequent marine heatwaves, using novel methodologies rooted in ecological modelling, experimental marine biology ....Safeguarding coral reef fisheries for future food security. This Fellowship aims to address the vulnerability of coral reef fisheries in Australia and the Indo-Pacific by identifying fishery targets that benefit human nutrition and will persist despite declining coral habitats and rising water temperature. This project will advance knowledge on coral and fish responses to increasingly frequent marine heatwaves, using novel methodologies rooted in ecological modelling, experimental marine biology and climate forecasting. Expected outcomes include (i) a comprehensive toolbox for improved management of coral reefs and associated fisheries in Australia and beyond, and (ii) an integrated socio-ecological model for predicting coral reef fishery responses under environmental change.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100373
Funder
Australian Research Council
Funding Amount
$447,320.00
Summary
The role of resource fluctuations in structuring microbial communities. The flow of nutrients through ecological systems fluctuates through time and yet the impact this variability has on the maintenance of biodiversity is poorly understood. Drawing on emerging theory and a tight integration of modelling and experiments in a model microbial system, this project aims to investigate the impact of modified nutrient regimes on the structure and stability of ecological communities. This project expec ....The role of resource fluctuations in structuring microbial communities. The flow of nutrients through ecological systems fluctuates through time and yet the impact this variability has on the maintenance of biodiversity is poorly understood. Drawing on emerging theory and a tight integration of modelling and experiments in a model microbial system, this project aims to investigate the impact of modified nutrient regimes on the structure and stability of ecological communities. This project expects to generate new knowledge at the forefront of research into diversity maintenance, ecosystem functioning and higher-order interactions. The outcomes should provide a deep mechanistic understanding of microbial community dynamics, with applications from animal health to environmental flows and insect pest management.Read moreRead less
How positive interactions improve predictions of plant community diversity. Though common in nature, the importance of plant-plant facilitation to coexistence and the maintenance of plant diversity at community scales is poorly understood. This project aims to advance understanding of how positive interactions (facilitation) impact on coexistence among plant species as well as local patterns of diversity. To achieve these aims the project will use a combination of field experiments and a compara ....How positive interactions improve predictions of plant community diversity. Though common in nature, the importance of plant-plant facilitation to coexistence and the maintenance of plant diversity at community scales is poorly understood. This project aims to advance understanding of how positive interactions (facilitation) impact on coexistence among plant species as well as local patterns of diversity. To achieve these aims the project will use a combination of field experiments and a comparative analysis of competition and facilitation in Australian, Californian and Spanish annual plant communities with a novel modelling approach for predicting coexistence across variable environments. Outcomes are expected to include an innovative predictive framework of use for plant conservation in Australia and beyond.Read moreRead less
Rapid evolution, and the dynamics and stability of ecological communities. Population sizes of species go up and down and often we do not know why. This is a problem because changes in population size underpin more complex ecological change, and understanding why population sizes change affects our ability to manage environmental impacts, and threatened, harvested and pest species. The aim of this project is to discover how rapid evolution – evolution occurring over just a few generations – driv ....Rapid evolution, and the dynamics and stability of ecological communities. Population sizes of species go up and down and often we do not know why. This is a problem because changes in population size underpin more complex ecological change, and understanding why population sizes change affects our ability to manage environmental impacts, and threatened, harvested and pest species. The aim of this project is to discover how rapid evolution – evolution occurring over just a few generations – drives changes in population sizes of plants in Australian freshwater ecosystems. By focusing on this fundamental yet poorly understood process, our results promise to rewrite our understanding of the causes of change in ecological communities, while highlighting a unique and little studied component of Australia’s biota.Read moreRead less