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
Toppling the Boring Billion: Biomarkers, orbital cycles and primordial life. This project aims to discover microbiological processes involved in ore formation in order to understand how zinc and lead minerals formed in the sediments of Australia’s ancient seas. The apparent ‘Boring Billion’ – the geological period 1800 to 800 million years ago – may have harboured seas of fluctuating colours. Fossil biomolecules, unearthed from 1.6 billion years old sediments, draw a picture of ancient seas osci ....Toppling the Boring Billion: Biomarkers, orbital cycles and primordial life. This project aims to discover microbiological processes involved in ore formation in order to understand how zinc and lead minerals formed in the sediments of Australia’s ancient seas. The apparent ‘Boring Billion’ – the geological period 1800 to 800 million years ago – may have harboured seas of fluctuating colours. Fossil biomolecules, unearthed from 1.6 billion years old sediments, draw a picture of ancient seas oscillating between blooms of purple and green bacteria, with waters rapidly alternating between toxic and sulphidic and rich in dissolved iron. Based on these observations, the project aims to discover the dynamic nature of primordial ecosystems, investigate how ancient seas were controlled by the Earth’s orbit around the sun, and explore how microorganisms may have formed the world’s largest zinc deposits.Read moreRead less
The rise of algae and the emergence of animals. This project aims to uncover the environmental changes that transformed the oceans 650 million years ago when complex algal cells started to replace bacteria as the dominant forms of life. Using a groundbreaking combination of molecular fossils and isotopes from ancient sedimentary rocks, the project aims to reveal how the flow of energy changed through Earth’s ecosystems. The expected outcomes include new knowledge about our own origins and the ev ....The rise of algae and the emergence of animals. This project aims to uncover the environmental changes that transformed the oceans 650 million years ago when complex algal cells started to replace bacteria as the dominant forms of life. Using a groundbreaking combination of molecular fossils and isotopes from ancient sedimentary rocks, the project aims to reveal how the flow of energy changed through Earth’s ecosystems. The expected outcomes include new knowledge about our own origins and the events that led to the emergence of the first animals. Additionally, new insights about the mechanisms that generated the oldest hydrocarbon reserves may lead to a new biomarker tool to aid discovery of major new oil or gas reserves in Australia’s Red Centre.Read moreRead less
Molecular traces of our primordial ancestors. This project aims to work with the exploration industry to develop an age-diagnostic fingerprinting tool for ancient petroleum seeps. Primordial molecules extracted from 1.6 billion years old rocks are the first and only witnesses of this extinct world. Australia’s vast red centre retains undiscovered oil reserves. This project will yield information about an oil’s provenance and help predict where reserves may be hidden, increasing the accuracy of s ....Molecular traces of our primordial ancestors. This project aims to work with the exploration industry to develop an age-diagnostic fingerprinting tool for ancient petroleum seeps. Primordial molecules extracted from 1.6 billion years old rocks are the first and only witnesses of this extinct world. Australia’s vast red centre retains undiscovered oil reserves. This project will yield information about an oil’s provenance and help predict where reserves may be hidden, increasing the accuracy of surveys and reducing costs and risks of exploration. Broader benefits from the findings may change common understanding about our very earliest ancestors and their effect on the planet’s evolution.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100160
Funder
Australian Research Council
Funding Amount
$297,463.00
Summary
Femtosecond laser micropyrolysis gas chromatograph-mass spectrometer. This project aims to build a femtosecond-laser, micropyrolysis gas-chromatographmass spectrometer. The facility will have the capability to selectively analyse very small petrographically-recognisable organic components, hence bridging the analytical gap between organic petrography and organic geochemistry. The project aims to understand the early evolution of life, the response of the biosphere to mass extinction, the migrati ....Femtosecond laser micropyrolysis gas chromatograph-mass spectrometer. This project aims to build a femtosecond-laser, micropyrolysis gas-chromatographmass spectrometer. The facility will have the capability to selectively analyse very small petrographically-recognisable organic components, hence bridging the analytical gap between organic petrography and organic geochemistry. The project aims to understand the early evolution of life, the response of the biosphere to mass extinction, the migration of fluids in petroleum reservoirs, the heterogeneity of organic matter in shale gas reservoirs, and the composition of macromolecules in biominerals and macerals. The facility will contribute to a broad range of Australia’s theoretical and applied problems in geoscience and geobiology.Read moreRead less