The role of behavioural interactions in shaping invasion dynamics: A global synthesis using the common myna as a model system. Invasive species have detrimental effects on human health, the economy and native biodiversity. This study will address a major gap in our scientific understanding of invasions by undertaking the first large-scale examination of the role of interactions between species in determining the dynamics and outcomes of biological invasions. The project will integrate data, acro ....The role of behavioural interactions in shaping invasion dynamics: A global synthesis using the common myna as a model system. Invasive species have detrimental effects on human health, the economy and native biodiversity. This study will address a major gap in our scientific understanding of invasions by undertaking the first large-scale examination of the role of interactions between species in determining the dynamics and outcomes of biological invasions. The project will integrate data, across four continents, on dispersal, demography, breeding and behavioural interactions into one framework to create a cutting-edge model of invasion dynamics, using the highly invasive common myna as a model system. This novel approach will significantly advance theoretical developments in invasion biology and will inform pest management and threat mitigation efforts globally.Read moreRead less
Systematic prioritisation of action for confronting invasive vertebrates in Australia. This project will use novel scientific approaches to effectively prioritise action for mitigating the threats invasive vertebrate pests pose to humans and to biodiversity in Australia. Results will inform policy and management, substantially advancing our understanding of the key factors shaping spatial invasion sources, hotspots, drivers and impact.
Understanding the tipping point between epidemic and endemic disease: amphibian chytridiomycosis as a model system. The amphibian disease chytridiomycosis has caused declines and extinctions in Australian frogs; it is very sensitive to environmental conditions, and changes in climate or weather could cause outbreaks that would eliminate many more species. This project will build greater understanding as to how and when that could occur and prevent it from happening.
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
Understanding and predicting invasion in the sea: a mechanistic approach. Marine invasive species cost millions of dollars each year. This project aims to determine how and why invasive species outcompete native species around much of the coast of Australia. Identifying the conditions that help invasive species outcompete native species will help managers reduce the spread and impact of marine invasive species.
Some like it hot: invasive species, hybridisation, and a warming world. Temperatures are rising and invasive species are becoming more prevalent. This project aims to understand how climate change and hybridisation between exotic and native marine species leads to rapid adaptation. Using integrative approaches from genomics and physiology and focusing on Australian blue mussels, this proposal will test leading hypotheses about how climate change and hybridisation can enable rapid adaptation and ....Some like it hot: invasive species, hybridisation, and a warming world. Temperatures are rising and invasive species are becoming more prevalent. This project aims to understand how climate change and hybridisation between exotic and native marine species leads to rapid adaptation. Using integrative approaches from genomics and physiology and focusing on Australian blue mussels, this proposal will test leading hypotheses about how climate change and hybridisation can enable rapid adaptation and the spread of exotic species. Outcomes will include strategies for minimising impacts of invasive mussels and boosting warm-temperature adaptation in aquaculture mussels and restored shellfish reefs. This project will yield fundamental insights into how marine species can quickly adapt to warming seas.Read moreRead less
Population fluctuations: models, mechanisms and management. Changes in plant populations lead to extinctions and invasions in Australia and globally. The project will determine the drivers of plant population change and provide new tools to enable better population management.
Tackling pests using game theory to support cooperative management. This project aims to improve management of invasive species by assisting pest mitigation agencies to work together. This is expected to result in more efficient and effective strategies, with the potential to dramatically improve local and global agricultural and environmental outcomes. An interdisciplinary approach using game theory, spatial modelling, and ecology is expected to create a novel framework to identify how and when ....Tackling pests using game theory to support cooperative management. This project aims to improve management of invasive species by assisting pest mitigation agencies to work together. This is expected to result in more efficient and effective strategies, with the potential to dramatically improve local and global agricultural and environmental outcomes. An interdisciplinary approach using game theory, spatial modelling, and ecology is expected to create a novel framework to identify how and when agencies might collaborate, and how collaboration might impact on costs and benefits of pest control strategies. The project will provide significant benefits by improving management of invasive species across Queensland, one of Australia's largest agricultural producing states and home to a vast number of Australia's threatened species. Read moreRead less
Who's calling? Understanding and exploiting signalling system ecology to improve success in trapping cane toads. This project has five major national and community benefits for Australia. It will: 1. provide a much-needed control option for a major pest, 2. actually remove many toads during the course of the study, through trapping at various locations around Australia, 3. support an Australian small business by providing research outcomes that will enable it to develop and market a highly desi ....Who's calling? Understanding and exploiting signalling system ecology to improve success in trapping cane toads. This project has five major national and community benefits for Australia. It will: 1. provide a much-needed control option for a major pest, 2. actually remove many toads during the course of the study, through trapping at various locations around Australia, 3. support an Australian small business by providing research outcomes that will enable it to develop and market a highly desired product, and 4. provide high level, postgraduate training in science. This project directly addresses the National Research Priority goal safeguarding Australia, protecting Australia from invasive … pests, because it will generate new technologies useful for controlling an invasive species.Read moreRead less
Determining how plant populations will respond to climate change. It is widely predicted that global climate change will result in extinctions, invasions and disruption of the ecosystem services plants provide. In order to manage or adapt to these consequences of changing climate we need accurate forecasts of where suitable conditions for sustainable plant populations will occur. This project will enable better forecasts of where and how fast plant populations will expand or contract in response ....Determining how plant populations will respond to climate change. It is widely predicted that global climate change will result in extinctions, invasions and disruption of the ecosystem services plants provide. In order to manage or adapt to these consequences of changing climate we need accurate forecasts of where suitable conditions for sustainable plant populations will occur. This project will enable better forecasts of where and how fast plant populations will expand or contract in response to climate change. New population modelling methods which integrate plant survival, growth and reproduction along environmental gradients, together with field studies at unprecedented national and international scales, will enable better forecasts of future locations for plant dependent industries and environmental services.Read moreRead less