Discovery Early Career Researcher Award - Grant ID: DE210101654
Funder
Australian Research Council
Funding Amount
$335,528.00
Summary
Assessing Eucalyptus forest responses to rising CO2 and climate change. Rising atmospheric CO2 and the associated changes in rainfall regimes are rapidly reshaping how Australia’s forest ecosystems function and underpin our daily life. Whether Australia’s native Eucalyptus trees can withstand the impacts of climate extremes such as drought and heat under rising CO2 is a crucial question that this project aims to resolve. Using an innovative framework that integrates novel knowledge, data assimil ....Assessing Eucalyptus forest responses to rising CO2 and climate change. Rising atmospheric CO2 and the associated changes in rainfall regimes are rapidly reshaping how Australia’s forest ecosystems function and underpin our daily life. Whether Australia’s native Eucalyptus trees can withstand the impacts of climate extremes such as drought and heat under rising CO2 is a crucial question that this project aims to resolve. Using an innovative framework that integrates novel knowledge, data assimilation and ecosystem modelling, this project will provide critically needed evidence to disentangle the multifaceted impacts of climate change to Eucalyptus trees. This will help reduce the predictive uncertainty in assessing the vulnerability and resilience of Eucalyptus forests in the changing Australian landscape. 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
How has bushfire activity varied around the Southern Hemisphere over the last 10,000 years? We will determine the relative contribution of climate and human ignitions in driving bushfire activity around the Southern Hemisphere over the last 10,000 years. Such knowledge is crucial for ecologically sustainable fire management, resolving debates about past Aboriginal environmental impacts and understanding the risk posed by climate change.
Hydroregulation – a missing piece of the climate change puzzle. There is a great need for process-explicit approaches to the puzzle of how organisms will respond to changes in temperature and rainfall. To achieve this for animals, behavioural buffering of both body temperature and water balance must be accounted for. Much is known about thermoregulation, but 'hydroregulation' stands out as a major missing piece of the climate change forecasting puzzle. This project will integrate new modelling m ....Hydroregulation – a missing piece of the climate change puzzle. There is a great need for process-explicit approaches to the puzzle of how organisms will respond to changes in temperature and rainfall. To achieve this for animals, behavioural buffering of both body temperature and water balance must be accounted for. Much is known about thermoregulation, but 'hydroregulation' stands out as a major missing piece of the climate change forecasting puzzle. This project will integrate new modelling methods and empirical approaches to understand the connections between thermoregulation, hydroregulation, activity and, ultimately, distribution and abundance. It will test the predictions against long-term activity observations of reptiles and invertebrates from the Australian arid zone.Read moreRead less
When fire and water mix: do carbon dioxide-related water savings drive woody plant thickening and fire dynamics in a grassy woodland? Australia's woodland landscapes have experienced widespread shrub expansion in the last century due to changes in fire, grazing and atmospheric carbon dioxide. This project will endevour to fill critical gaps in the nexus between carbon dioxide-induced effects on vegetation and fire disturbance to help explain this phenomenon and help manage Australian woodlands i ....When fire and water mix: do carbon dioxide-related water savings drive woody plant thickening and fire dynamics in a grassy woodland? Australia's woodland landscapes have experienced widespread shrub expansion in the last century due to changes in fire, grazing and atmospheric carbon dioxide. This project will endevour to fill critical gaps in the nexus between carbon dioxide-induced effects on vegetation and fire disturbance to help explain this phenomenon and help manage Australian woodlands into the future.Read moreRead less
Climate change: bridging the gap between environmental induced phenotypic change, population dynamics, and long-term evolution. It is becoming impossible to ignore the impact of global climate change on organisms around the world from changes in migration, distribution to extinction events - yet there is much to understand. This project examines the role of a changing environment during developmental and its effects on ecological and evolutionary outcomes.
Extreme Heat: A new driver of desert mammal assemblages . Heat waves cause more deaths than any other severe weather event and are becoming longer, more frequent and more intense. Consequently, extreme heat may soon rival predation and rainfall as a major driver of desert mammal assemblages. This project will investigate how heat wave attributes (duration, intensity, frequency), species attributes (physiology, behaviour, plasticity) and landscape features (refuges, fire, grazing) interact and co ....Extreme Heat: A new driver of desert mammal assemblages . Heat waves cause more deaths than any other severe weather event and are becoming longer, more frequent and more intense. Consequently, extreme heat may soon rival predation and rainfall as a major driver of desert mammal assemblages. This project will investigate how heat wave attributes (duration, intensity, frequency), species attributes (physiology, behaviour, plasticity) and landscape features (refuges, fire, grazing) interact and contribute to lethal and sublethal effects of extreme heat on desert mammals. Modelling will predict changes in desert mammal assemblages under different climatic and land management scenarios. Results will inform fire and grazing management, threatened species recovery programs and arid zone restoration. Read moreRead less
The role of common species in biodiversity turnover and function . This project aims to understand how common species change across regions and how this affects the functions that biodiversity provides across natural and built landscapes. Using a novel, information-rich approach and metric, the project aims to combine simulation experiments, and empirical data using organisms with low (plants) and high mobility (birds). Expected outcomes include new theory and improved biodiversity models, polic ....The role of common species in biodiversity turnover and function . This project aims to understand how common species change across regions and how this affects the functions that biodiversity provides across natural and built landscapes. Using a novel, information-rich approach and metric, the project aims to combine simulation experiments, and empirical data using organisms with low (plants) and high mobility (birds). Expected outcomes include new theory and improved biodiversity models, policy and management-relevant insights, new institutional collaborations, and student training. The research aims to provide significant benefits for understanding and monitoring the dynamics of common species, including problem species and common native species in rapid decline.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101611
Funder
Australian Research Council
Funding Amount
$379,040.00
Summary
Snow, shrub and climate feedbacks: impacts of shrub expansion in the Australian alpine zone. This project aims to understand the mechanisms promoting shrub expansion in alpine areas and the consequences of a shrub-dominated landscape in terms of shrubs as hydrological mediators and as biodiversity and ecosystem modifiers. Some shrub species trap wind-blown snow, thereby facilitating seedling survival through soil insulation and increases to meltwater. However, if adaptive and plastic responses t ....Snow, shrub and climate feedbacks: impacts of shrub expansion in the Australian alpine zone. This project aims to understand the mechanisms promoting shrub expansion in alpine areas and the consequences of a shrub-dominated landscape in terms of shrubs as hydrological mediators and as biodiversity and ecosystem modifiers. Some shrub species trap wind-blown snow, thereby facilitating seedling survival through soil insulation and increases to meltwater. However, if adaptive and plastic responses to climate change allows, shrub expansion will have significant negative impacts on alpine biodiversity and ecosystem function. This project will tease apart the interacting effects of snow, recruitment and adaptation to provide models of shrub increase and determine how shrubs modify alpine ecosystem processes and upper catchment hydrology.Read moreRead less
What fungal features are key to developing environmental resilience? The aim of this project is to identify key mechanisms contributing to environmental resilience within the east Antarctic soil mycobiome. We will use cutting-edge approaches to perform comparative phenotypic and genomic analyses on cold-adapted fungi against temperate species counterparts. Intended outcomes include an enhanced capacity to contribute substantially to the fungal tree of life while gaining new knowledge on fungal a ....What fungal features are key to developing environmental resilience? The aim of this project is to identify key mechanisms contributing to environmental resilience within the east Antarctic soil mycobiome. We will use cutting-edge approaches to perform comparative phenotypic and genomic analyses on cold-adapted fungi against temperate species counterparts. Intended outcomes include an enhanced capacity to contribute substantially to the fungal tree of life while gaining new knowledge on fungal adaptations in a model ecosystem at the limits of life. Significant benefits to the Royal Botanical Gardens and Domain Trust is delivery on their mission to quantify and qualify fungal biodiversity, and building of a restore and renew program that will inform future management and restoration of Australian ecosystems.Read moreRead less