Multitrophic interactions drive diversity-ecosystem function relationships. Soil communities, among the most abundant and diverse in nature are responsible for many critical ecosystem functions, including nutrient cycling and climate regulation. This project will determine whether consideration and quantification of interactions between different biotic communities – specifically among plants, soil microbes and animals, within and across trophic levels - can address underlying shortcomings in pr ....Multitrophic interactions drive diversity-ecosystem function relationships. Soil communities, among the most abundant and diverse in nature are responsible for many critical ecosystem functions, including nutrient cycling and climate regulation. This project will determine whether consideration and quantification of interactions between different biotic communities – specifically among plants, soil microbes and animals, within and across trophic levels - can address underlying shortcomings in predictions from classical biodiversity-ecosystem function theory. By advancing understanding of biological complexity and its impacts on ecosystem functions, the project will provide a unifying framework for understanding variation in ecosystem functions across scales, ecosystem types and multiple environmental disturbances.Read moreRead less
Understanding snow gum dieback for effective and integrated management. The project leverages recent research and infrastructure investments and our determined and collaborative team as it aims to: 1) assess the future geography of snow gum dieback in the high country and identify priority locations for pro-active management, 2) quantify the impact of snow gums on high country water and carbon budgets and thus the socio- economic and biodiversity values, and 3) determine options for mitigation. ....Understanding snow gum dieback for effective and integrated management. The project leverages recent research and infrastructure investments and our determined and collaborative team as it aims to: 1) assess the future geography of snow gum dieback in the high country and identify priority locations for pro-active management, 2) quantify the impact of snow gums on high country water and carbon budgets and thus the socio- economic and biodiversity values, and 3) determine options for mitigation. Dieback of our iconic snow gum forests is diminishing the ecological, hydrological and cultural values of the Australian Alps and will impact state and national water-supply and power-generation systems. Our research will inform Alps-wide management efforts designed for long-term success.Read moreRead less
Rhizosphere mediation of soil greenhouse gas fluxes with climate change. Increasingly extreme heat waves, droughts and floods contribute major uncertainties in predicting natural land-based climate change mitigation. This project will quantify current and future greenhouse gas absorption in a managed grassland ecosystem, and the new knowledge will contribute to carbon emissions offsets in climate change accounting schemes. We will conduct this research using a manipulative field experiment, cont ....Rhizosphere mediation of soil greenhouse gas fluxes with climate change. Increasingly extreme heat waves, droughts and floods contribute major uncertainties in predicting natural land-based climate change mitigation. This project will quantify current and future greenhouse gas absorption in a managed grassland ecosystem, and the new knowledge will contribute to carbon emissions offsets in climate change accounting schemes. We will conduct this research using a manipulative field experiment, controlled laboratory incubations, microbial gene analysis and mechanistic modelling to provide new insights into future potential climate change mitigation by soils.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
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
Feast or famine: how Australian plants stay productive under low phosphorus. Phosphorus (P) is in low supply in soils around the nation, and limits plant production in the Australian landscape, as well as for many tropical forests worldwide. How scarce P restricts photosynthetic capacity has remained elusive. We will determine how Australian plants achieve high phosphorus-use efficiency despite low P concentrations in leaves and soils. We will synthesise knowledge of how plants maintain producti ....Feast or famine: how Australian plants stay productive under low phosphorus. Phosphorus (P) is in low supply in soils around the nation, and limits plant production in the Australian landscape, as well as for many tropical forests worldwide. How scarce P restricts photosynthetic capacity has remained elusive. We will determine how Australian plants achieve high phosphorus-use efficiency despite low P concentrations in leaves and soils. We will synthesise knowledge of how plants maintain productivity with low P availability, and inform global models how to represent P biogeochemistry and photosynthesis to improve C-cycle estimates. The understanding of plant photosynthetic and P-saving mechanisms that emerge should provide benefits through improved ecological models and enhanced management of primary production.Read moreRead less
Leaf and wood physiology and biomass allocation as drivers of plant growth. This project will build new understanding of how physiological and morphological traits of plants drive growth rates and reflect evolutionary adaptation to different environments. This is significant because growth rates are pivotal in vegetation ecology and a core element of plant ecological strategies. Expected outcomes include new cost-benefit theory for plant form and function considered at whole-canopy scale, with e ....Leaf and wood physiology and biomass allocation as drivers of plant growth. This project will build new understanding of how physiological and morphological traits of plants drive growth rates and reflect evolutionary adaptation to different environments. This is significant because growth rates are pivotal in vegetation ecology and a core element of plant ecological strategies. Expected outcomes include new cost-benefit theory for plant form and function considered at whole-canopy scale, with empirical tests from Australian and Chinese ecosystems and via global trait datasets. Benefits include new approaches for predicting plant physiological properties and growth rates, and new knowledge crucial for understanding links between species traits, plant strategies and, ultimately, ecosystem productivity.Read moreRead less
Causes and consequences of biogeochemical mismatches during drought. This project aims to provide improved understanding of biogeochemical cycling. Drought is one of the main threats to Earth’s ecosystems, but our ability to predict the consequences of drought remain limited. There is strong evidence that drought impacts critical carbon and nutrient cycles, with substantial impacts on ecosystem functioning. This project will provide insights into carbon, nitrogen and phosphorous cycles essential ....Causes and consequences of biogeochemical mismatches during drought. This project aims to provide improved understanding of biogeochemical cycling. Drought is one of the main threats to Earth’s ecosystems, but our ability to predict the consequences of drought remain limited. There is strong evidence that drought impacts critical carbon and nutrient cycles, with substantial impacts on ecosystem functioning. This project will provide insights into carbon, nitrogen and phosphorous cycles essential to generalise patterns of biogeochemical cycling under current and future conditions. The project will assist scientists, policymakers and landholders make better-informed management decisions to reduce the risks of drought impacts on ecosystem functioning.Read moreRead less
Optimising biodiversity conservation in managed forest landscapes. How to meet human needs for timber while limiting harm to biodiversity is an urgent scientific goal. The project will address this challenge by quantifying the impacts of forestry systems and wildfire on mammal species. Novel network modelling of interactions among plants, animals, and environmental variables will establish cost-effective management improvements to maximise biodiversity values. A systematic conservation planning ....Optimising biodiversity conservation in managed forest landscapes. How to meet human needs for timber while limiting harm to biodiversity is an urgent scientific goal. The project will address this challenge by quantifying the impacts of forestry systems and wildfire on mammal species. Novel network modelling of interactions among plants, animals, and environmental variables will establish cost-effective management improvements to maximise biodiversity values. A systematic conservation planning approach will deliver spatially and temporally explicit solutions to balancing trade-offs between production and conservation taking into account dynamic impacts from climate change and fire. Outcomes will provide a foundation for policy changes to put theoretical solutions into practice.Read moreRead less
Escalating the arms race: Understanding when and how trees get really tall. Australia's giant Eucalypt trees are an amazing phenomenon and resource; underpinning unique ecosystems, rich in timber, stored carbon, and animal habitat. While tree height generally arises via an evolutionary arms race for light, the race has escalated dramatically in some locations and species. Using a computational framework that simulates adaptation driven by size-structured competition, this project will quantify h ....Escalating the arms race: Understanding when and how trees get really tall. Australia's giant Eucalypt trees are an amazing phenomenon and resource; underpinning unique ecosystems, rich in timber, stored carbon, and animal habitat. While tree height generally arises via an evolutionary arms race for light, the race has escalated dramatically in some locations and species. Using a computational framework that simulates adaptation driven by size-structured competition, this project will quantify how distinct factors-including climate, recruitment, and disturbance-enhance the race for light and can thereby explain the origins of Australia's giant Eucalypt. With calibrated models of species evolution, coupled with targeted fieldwork and big data, this project clarifies key forces shaping present and future vegetation.Read moreRead less