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Dynamic soil landscape carbon modelling. Soil is the largest terrestrial store of carbon. This project will enhance our understanding of the causes and controls of spatial and temporal variations of soil carbon which is crucial for managing climate change, food water and energy security and for maintenance of biodiversity.
Crops for a phosphorus-scarce future: plant adaptation to fluctuating phosphorus availability. Phosphorus is commonly used on farmland to ensure high yields. However, rock phosphate reserves are declining and leaching of phosphorus from farmlands into native vegetation and water bodies causes significant environmental degradation. As a result, more phosphorus-efficient farming systems are urgently required. Many Australian native plants have adapted to low phosphorus soils and fast fluctuations ....Crops for a phosphorus-scarce future: plant adaptation to fluctuating phosphorus availability. Phosphorus is commonly used on farmland to ensure high yields. However, rock phosphate reserves are declining and leaching of phosphorus from farmlands into native vegetation and water bodies causes significant environmental degradation. As a result, more phosphorus-efficient farming systems are urgently required. Many Australian native plants have adapted to low phosphorus soils and fast fluctuations in phosphorus availability. This project aims to investigate plant adaptations to phosphorus fluctuations and the potential for storing phosphorus when it is abundant for later use. This should aid development of crops with improved phosphorus fertiliser-use efficiency in anticipation of a phosphorus-scarce future.Read moreRead less
Unlocking Viral Contribution to Terrestrial Nitrogen Cycling. This project aims to investigate how soil viruses steer key nitrogen cycling microorganisms and processes, by utilising emerging approaches of viromes, DNA-stable-isotope probing, and Raman-spectroscopy-based single-cell-sorting technology. This project expects to generate new knowledge in harnessing the potential of soil viruses to improve fertiliser nitrogen use efficiency through manipulating the biological pathways of nitrogen los ....Unlocking Viral Contribution to Terrestrial Nitrogen Cycling. This project aims to investigate how soil viruses steer key nitrogen cycling microorganisms and processes, by utilising emerging approaches of viromes, DNA-stable-isotope probing, and Raman-spectroscopy-based single-cell-sorting technology. This project expects to generate new knowledge in harnessing the potential of soil viruses to improve fertiliser nitrogen use efficiency through manipulating the biological pathways of nitrogen losses from agricultural ecosystems. Expected outcomes of this project include novel and comprehensive evidence for the roles of soil viruses in controlling terrestrial nitrogen cycling processes. This should provide significant benefits to Australian agriculture and environmental management.Read moreRead less
Contribution of comammox bacteria to soil nitrification. This project aims to understand the diversity, activity and environmental relevance of comammox bacteria, the newly-discovered complete nitrifiers, in Australian soils, and to evaluate their relative contributions to nitrification processes compared to other canonical nitrifying prokaryotes. Nitrogen transformations are pivotal microbial processes, with nitrification largely responsible for nitrogen losses through nitrous oxide emissions a ....Contribution of comammox bacteria to soil nitrification. This project aims to understand the diversity, activity and environmental relevance of comammox bacteria, the newly-discovered complete nitrifiers, in Australian soils, and to evaluate their relative contributions to nitrification processes compared to other canonical nitrifying prokaryotes. Nitrogen transformations are pivotal microbial processes, with nitrification largely responsible for nitrogen losses through nitrous oxide emissions and nitrate leaching in the terrestrial ecosystems. The expected outcomes will develop new knowledge on the comammox bacteria and provide novel insights into refined strategies to manipulate nitrification processes for improved nitrogen use efficiency and sustainable agricultural management.Read moreRead less
The timescales of Earth-system processes. This project will advance our understanding of the timescales of Earth processes using short-lived (22 to 380,000 years) isotopes. The results will provide better constraints on the timescales of magmatic processes and frequency of large-scale eruptions for volcanic hazard mitigation and also soil production rates for landscape erosion studies.
Soil ecology in the 21st century - a crucial role in land management. Recent technological advances have helped us discover the role of soil ecology in achieving sustainability in Australia. This project will develop ways to take this complex knowledge and translate it into forms that can be used by land managers. This work will focus on soil carbon sequestration, but is relevant to many other environmental issues.
Sea-level rise as a driver for arsenic mobilisation: unravelling the fundamental hydro-geochemical controls. This project will reveal the effects of rising sea-levels on arsenic mobilisation in vulnerable coastal lowlands. By resolving coupled interactions between tides and geochemistry, this project will provide the necessary knowledge platform to underpin management responses to protect sensitive estuarine and coastal waters.
Responsive porous materials for the triggered release of stored target molecules. This project will create a new generation of ultraporous materials capable of releasing a valuable molecule, stored within their pores, when an external trigger is applied. The porous materials, including metal organic frameworks and porous aromatic frameworks, will have components incorporated within them that can respond to stimuli such as ultraviolet or visible light, microwave, ultrasound, or pH change, causing ....Responsive porous materials for the triggered release of stored target molecules. This project will create a new generation of ultraporous materials capable of releasing a valuable molecule, stored within their pores, when an external trigger is applied. The porous materials, including metal organic frameworks and porous aromatic frameworks, will have components incorporated within them that can respond to stimuli such as ultraviolet or visible light, microwave, ultrasound, or pH change, causing the stored target molecule to be released. Target molecules will include carbon dioxide, fertilisers, clean burning gaseous fuels and medicines.Read moreRead less
Drought effects on soil carbon and nitrogen cycling mediated by rhizosphere processes. There is much uncertainty about how drought caused by global warming will affect agricultural sustainability in Australia. This project will provide new knowledge about plant-soil interactions affecting carbon and nutrient cycling and will make predictions about long-term soil carbon storage and agricultural productivity in response to drought.
Advancing our understanding of plant responses to low phosphorus availability beyond the transcriptome. Phosphorus is essential for plant growth. Plants have evolved mechanisms to cope with the poor availability of phosphorus in many soils. This project will improve Australia's knowledge of how plants alter the expression of genes and proteins to activate their mechanisms for coping with poor phosphorus availability in some soils.