Aggregate structure of humic organic matter. Soil aquatic organic matter is important in plant growth, nutrient supply and water quality and in affecting pollutants and metal ions in the environment. Indeed the survival of life on the planet depends on the way geo-organic matter functions. We have recently developed a new host guest theory on the way this material binds important substances such as metal ions and pollutants. This project aims to use this theory to investigate the structure of th ....Aggregate structure of humic organic matter. Soil aquatic organic matter is important in plant growth, nutrient supply and water quality and in affecting pollutants and metal ions in the environment. Indeed the survival of life on the planet depends on the way geo-organic matter functions. We have recently developed a new host guest theory on the way this material binds important substances such as metal ions and pollutants. This project aims to use this theory to investigate the structure of these materials and how they work in Nature by understanding molecular composition at a level hitherto thought impossible.Read moreRead less
Host-guest structure of humic organic matter - the key to understanding soil organic properties. Soil and aquatic organic matter is important in plant growth, nutrient supply and water quality and in affecting pollutants and metal ions in the environment. Indeed, the survival of life on the planet depends on the way geo-organic matter functions. We have recently developed a new host?guest theory on the way this material binds important substances such as metal ions and pollutants. This proje ....Host-guest structure of humic organic matter - the key to understanding soil organic properties. Soil and aquatic organic matter is important in plant growth, nutrient supply and water quality and in affecting pollutants and metal ions in the environment. Indeed, the survival of life on the planet depends on the way geo-organic matter functions. We have recently developed a new host?guest theory on the way this material binds important substances such as metal ions and pollutants. This project aims to use this theory to investigate the structure of these materials and how they work in Nature by understanding molecular composition at a level hitherto thought impossible.Read moreRead less
Chronostratigraphic, molecular and isotopic approaches to age petroleum. The project aims to reduce the costs of drilling in deep-water offshore by better identifying potential drilling sites. The North-West shelf offshore Australia is the main supplier of liquefied natural gas. However, there is uncertainty about the age of petroleum (oil and gas) discovered in the region. It is not currently possible to constrain an age of fluids to a number of source rocks. The aims are to develop a high-leve ....Chronostratigraphic, molecular and isotopic approaches to age petroleum. The project aims to reduce the costs of drilling in deep-water offshore by better identifying potential drilling sites. The North-West shelf offshore Australia is the main supplier of liquefied natural gas. However, there is uncertainty about the age of petroleum (oil and gas) discovered in the region. It is not currently possible to constrain an age of fluids to a number of source rocks. The aims are to develop a high-level age discriminative tool for fluids. An interdisciplinary approach will be applied using state-of-the-art techniques including comprehensive two dimensional gas chromatography time-of-flight mass spectrometry, compound specific isotope analysis of hydrocarbons, clumped isotopes of methane and metagenomics.Read moreRead less
Molecular fossils, mass extinctions and the rise of complex algae. This project aims to illuminate the fate and role of phytoplankton during the Permo-Triassic crisis, the most severe mass extinction event in Earth's history. Despite being the vital driving force of the carbon cycle, these microscopic yet essential organisms have largely evaded fossilization and their precise history remains unknown. Leveraging innovative molecular fossil technology, this project seeks to unlock this critical in ....Molecular fossils, mass extinctions and the rise of complex algae. This project aims to illuminate the fate and role of phytoplankton during the Permo-Triassic crisis, the most severe mass extinction event in Earth's history. Despite being the vital driving force of the carbon cycle, these microscopic yet essential organisms have largely evaded fossilization and their precise history remains unknown. Leveraging innovative molecular fossil technology, this project seeks to unlock this critical information, generating insights into the mechanisms behind climate-driven mass extinctions and the subsequent recovery of marine life. By doing so, this study aims to reveal how current disruptions to the base of the food chain may escalate through all levels of marine ecosystems, causing extinction.Read moreRead less
Tracing life's beginnings: molecular fossils from single oil inclusions. Biomarkers (chemical fossils) from traces of oil trapped in 2 to 3.5 billion year-old rocks from Australia, Canada and Africa will be analysed by both well established and novel techniques. The biomarkers will be used to assess which key groups of species were present when, and thus constrain the timing of evolution of Earth's early biosphere.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100229
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Time-of-flight mass spectrometer for analysis of complex mixtures in oils, ancient rocks, recent sediments, natural products and atmospheric aerosols. Research benefits will be:1. More effective remediation of petroleum spills through better understanding of degradation pathways, and ecotoxicological impact of spills.
2. Better understanding of the role of urban aerosols in human health impacts and climate change.
3. More effective development of finite petroleum resources by better understand ....Time-of-flight mass spectrometer for analysis of complex mixtures in oils, ancient rocks, recent sediments, natural products and atmospheric aerosols. Research benefits will be:1. More effective remediation of petroleum spills through better understanding of degradation pathways, and ecotoxicological impact of spills.
2. Better understanding of the role of urban aerosols in human health impacts and climate change.
3. More effective development of finite petroleum resources by better understanding of processes altering crude oil in the sub-surface.
4. Identification of natural products from algae, cyanobacteria, plants and mushrooms as new sources of pharmaceutical agents. 5. Improved knowledge of early evolution of life on Earth, helping maintain Australian scientists as world leaders in this field. 6. Greater understanding of the source and migration of petroleum in frontier areas.Read moreRead less
New molecular and isotopic biomarker approaches to establishing source, palaeoclimate, facies and thermal history of sedimentary organic matter. The ability to identify crude oil sources is a key issue in petroleum exploration, especially in Australia where vast gas deposits occur but very limited reserves of liquid hydrocarbons have been discovered. Discoveries of new petroleum reservoirs/provinces will benefit all Australians. Technological developments made will be extended to other Australia ....New molecular and isotopic biomarker approaches to establishing source, palaeoclimate, facies and thermal history of sedimentary organic matter. The ability to identify crude oil sources is a key issue in petroleum exploration, especially in Australia where vast gas deposits occur but very limited reserves of liquid hydrocarbons have been discovered. Discoveries of new petroleum reservoirs/provinces will benefit all Australians. Technological developments made will be extended to other Australian basins leading to more effective petroleum and mineral exploration strategies. The project described will also help our understanding of climate variability of past episodes and help predict what might happen in the future. The PhD scholars will foster high-calibre postgraduate research students suitable for employment in research or in industry.Read moreRead less
Molecular fossils, the evolution of Earth's early oceans and the origin of the oldest oil. Australia retains undiscovered oil reserves. We believe that a change in primitive marine life forms may have fundamentally changed the chemistry of the Earth's oceans and is responsible for the world's oldest oil reserves. While these reserves have been found, and successfully commercialised, overseas, similar reservoirs in Australia remain elusive. The project will develop and apply technologies based on ....Molecular fossils, the evolution of Earth's early oceans and the origin of the oldest oil. Australia retains undiscovered oil reserves. We believe that a change in primitive marine life forms may have fundamentally changed the chemistry of the Earth's oceans and is responsible for the world's oldest oil reserves. While these reserves have been found, and successfully commercialised, overseas, similar reservoirs in Australia remain elusive. The project will develop and apply technologies based on hydrocarbon biomarkers to help determine the oil-producing rock types of Precambrian sedimentary rocks. This allows us to estimate the oil's age and predict where petroleum reservoirs may be hidden. PhD students involved in the project will gain valuable knowledge about the link between changes in ecology and the carbon cycle.Read moreRead less
Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how ....Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how microbial ecosystems adapt to increasing salinization, and how they reacted to climate fluctuations in the past. Students will gain multidisciplinary skills in environmental genomics, proteomics and geochemistry, a unique combination that will become decisive for understanding and preserving ecosystems on our continent.Read moreRead less