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
Tackling the resurgences of life, advanced dating tools of oils by sophisticated molecular and isotopic analyses from major geological events. Evidence of Earth’s biogeochemical evolution is uniquely recorded in sediments and petroleum, as are the mechanisms of life’s recovery from mass extinction caused by past catastrophes. Pioneering ageing techniques will be tested on ancient sediments, low temperature mineral fabrics and petroleum leading to the exploration of new energy sources.
Gold transport in aqueous versus organic fluids: Experimental data for describing ore-forming systems. In many hydrothermal ore-forming systems, the ore is associated with inclusions of both aqueous brine and organic liquid (petroleum). The conventional theory is that the metals are dissolved and transported to the deposit by the brine, but some researchers suggest that petroleum may fill this role. This project proposes to conduct an experimental and field-based study on the chemical behaviour ....Gold transport in aqueous versus organic fluids: Experimental data for describing ore-forming systems. In many hydrothermal ore-forming systems, the ore is associated with inclusions of both aqueous brine and organic liquid (petroleum). The conventional theory is that the metals are dissolved and transported to the deposit by the brine, but some researchers suggest that petroleum may fill this role. This project proposes to conduct an experimental and field-based study on the chemical behaviour of gold in aqueous-organic and organic fluid systems, to determine which type of liquid is more important for gold mobilisation in a competitive situation. This study will provide much-needed data for more accurate modelling of ore systems, furthering our understanding and facilitating mineral exploration. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100219
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A modern, high-tech mineral separation facility for geochemistry and isotope science. This project will support geoscience research in Western Australia that incorporates a new conservative way of fragmenting rocks to their constituent grains. The facility will provide mineral samples for discovery science and for applied research for the minerals and petroleum industries.
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
Sulfur Cycling in Toxic Oozes, Microbialites and Petroleum. This project will apply compound specific sulfur isotope analyses to sulfur-rich deposits from extreme environments including sulfidic black oozes (Peel-Harvey estuary); modern microbialites (for example, Shark Bay) and oils/source rocks (established and frontier oil fields). Sulfur isotopic data, integrated with other stable isotopic and molecular data, will greatly assist the study of sulfur biogeochemical cycles and mechanisms of org ....Sulfur Cycling in Toxic Oozes, Microbialites and Petroleum. This project will apply compound specific sulfur isotope analyses to sulfur-rich deposits from extreme environments including sulfidic black oozes (Peel-Harvey estuary); modern microbialites (for example, Shark Bay) and oils/source rocks (established and frontier oil fields). Sulfur isotopic data, integrated with other stable isotopic and molecular data, will greatly assist the study of sulfur biogeochemical cycles and mechanisms of organic sulfurisation at different diagenetic stages or geological ages. The project aims to address national concerns through measuring the respective impact of anthropogenic and natural changes on environments, helping to understand the evolution of life on Earth and contributing to efficient discovery of our natural petroleum systems.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: LE130100145
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Three-dimensional analysis of important organic components in energy, environmental and earth systems. Australia’s ecosystems and water resources are sensitive to climate change and anthropogenic activities. A third degree of separation provided by this technique will improve our abilities to monitor the role of organic matter in modern systems. The characterisation of organics of petroleum mineral systems will sustain Australia's energy demand.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100127
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
High resolution liquid chromatography mass spectrometry (Orbitrap) for analyses of polar compounds in biomass, petroleum, potable and reclaimed water. Climate change and human impact can harm sensitive ecosystems, significantly threatening Australian biodiversity and water resources. Chemical and biological characterisation of aquatic and terrestrial environments is paramount to assessing and responding to these threats, as well as assisting natural resource utilisation. The high structural pola ....High resolution liquid chromatography mass spectrometry (Orbitrap) for analyses of polar compounds in biomass, petroleum, potable and reclaimed water. Climate change and human impact can harm sensitive ecosystems, significantly threatening Australian biodiversity and water resources. Chemical and biological characterisation of aquatic and terrestrial environments is paramount to assessing and responding to these threats, as well as assisting natural resource utilisation. The high structural polarity of many environmentally occurring organics from biological, petroleum and anthropogenic sources, unamenable to gas chromatographic resolution, can now be accommodated by the advanced organic analytical technology sought in this proposal. This project will enable scholars and young professionals to be skilled in state-of-the-art technology, and prepare quality scientists, ready for employment.Read moreRead less