This dataset features Australian hydrogen projects and research centres that are active in the development, construction, or operating phase, and meet renewable hydrogen or carbon capture and storage (CCS) hydrogen production methods outlined in Australia's National Hydrogen Strategy. This dataset aims is to provide a detailed snapshot of hydrogen activity across Australia. It includes location data, proponent details, and descriptions for all hydrogen projects and research centres listed. Additional data is included for hydrogen projects, such as the energy source for hydrogen production, the method of hydrogen production, and the amount of hydrogen to be produced per year. This dataset is the basis of the point-location map of active Australian hydrogen projects and research centres featured on the Australia Hydrogen Opportunities Tool (AusH2.ga.gov.au). AusH2 aims to attract investment in Australia’s hydrogen industry, providing high quality, free, online geospatial analysis tools and data for mapping and understanding Australia’s hydrogen potential. It hosts key national-scale datasets, such as locations of wind and solar resources and distribution of infrastructure, as well as the Hydrogen Economic Fairways Tool (HEFT) that maps the economic viability of hydrogen production in Australia. The user can examine both hydrogen production by electrolysis using renewable energy sources and fossil fuel produced hydrogen coupled with CCS. AusH2 was produced by Geoscience Australia for the Council of Australian Governments (COAG) Energy Council’s Hydrogen Working Group in 2019. Updates to this dataset since September 2020 are coordinated with research.csiro.au/HyResource

Underground halite, or salt, deposits can potentially be used for large scale storage of hydrogen. This dataset maps the spatial distribution of known, thick underground halite deposits across Australia. Halite sequences included in this map are at least 100 metres thick (to ensure sufficient storage capacity) and are located onshore. Known, thick halite deposits are located in the Carnarvon, Amadeus and Adavale basins. Underground halite deposits have not been extensively explored for across Australia and additional halite deposits suitable for large scale hydrogen storage may exist. Geoscience Australia, through the Exploring for the Future (EFTF) program, is therefore exploring for underground halite deposits to further our understanding of sub-surface halite distribution for potential hydrogen storage. This map may be updated periodically to reflect new halite discoveries found during the EFTF program. This dataset is published with the permission of the CEO, Geoscience Australia.

Depleted gas fields can potentially be used for large scale storage of gases such as carbon dioxide, natural gas and hydrogen. Onshore Depleted Gas Fields This dataset maps the spatial distribution of depleted gas fields across onshore Australia. Underground Gas Storage Facilities This dataset maps the spatial distribution of underground gas storage facilities across Australia. Underground gas storage facilities utilise depleted gas fields for the seasonal storage of natural gas in Australia. The injection, withdrawal and storage capacities of each underground gas storage facility is included within this dataset. This dataset is published with the permission of the CEO, Geoscience Australia.

This web map service provides visualisations of the outputs from the five scenarios assessed in the analysis of prospective hydrogen production regions of Australia. Datasets used as inputs into the hydrogen production prospectivity analysis have been sourced from the Department of Environment and Energy, PSMA Australia, Garrad Hassan Pacific Pty. Ltd., Australian Bureau of Meteorology, Department of Resources Energy and Tourism, Queensland Department of Employment, Economic Development and Innovation, NSW Department of Planning, Industry and Environment, and Geoscience Australia.

There is significant interest in Australia, both federally and at the state level, to develop a hydrogen production industry. Australia’s Chief Scientist, Alan Finkel, recently prepared a briefing paper for the COAG Energy Council outlining a road map for hydrogen. It identifies hydrogen has the potential to be a significant source of export revenue for Australia in future years, assist with decarbonising Australia’s economy and could establish Australia as a leader in low emission fuel production. As part of the ongoing investigations into the hydrogen production potential of Australia, Geoscience Australia has been commissioned by the Department of Industry, Innovation and Science to develop heat maps that show areas with high potential for future hydrogen production. The study is technology agnostic, in that it considers hydrogen production via electrolysis using renewable energy sources and also fossil fuel hydrogen coupled with carbon capture and storage (CCS). The heat maps presented in this work are synthesized from the key individual national-scale datasets that are relevant for hydrogen production. In the case of hydrogen from electrolysis, renewable energy potential and the availability of water are the most important factors, with various infrastructural considerations playing a secondary role. In the case of fossil fuel hydrogen, proximity to gas and coal resources, water and availability of carbon storage sites are the important parameters that control the heat maps. In this report we present 5 different heat map scenarios, reflecting different assumptions in the geospatial analysis and also reflecting to some degree the different projected timeframes for hydrogen production. The first three scenarios pertain to renewable energy and hydrogen produced by electrolysis. Differences between the three scenarios depend on whether hydrogen is produced near the coastal areas, where infrastructure and water are not issues or whether hydrogen can be produced in inland areas provided water does become a constraining factor. Assumptions regarding the proximity of a currently connected electrical grid to transport renewable energy also play a large role in the different scenarios. The final two scenarios focus on the potential for fossil fuel hydrogen, coupled with CCS, with the difference between the two scenarios being related to the timeframes for readiness for both fossil fuel production and availability of CO2 storage resources. This dataset includes the five scenario raster outputs as produced as part of the Prospective hydrogen production regions of Australia report.

This web map service provides visualisations of datasets used as inputs into the analysis of prospective hydrogen production regions of Australia. The service has been developed using datasets sourced from the Department of Environment and Energy, PSMA Australia, Garrad Hassan Pacific Pty. Ltd., Australian Bureau of Meteorology, Department of Resources Energy and Tourism, Queensland Department of Employment, Economic Development and Innovation, NSW Department of Planning, Industry and Environment, and Geoscience Australia

Hydrogen can be used for a variety of domestic and industrial purposes such as heating and cooking (as a replacement for natural gas), transportation (replacing petrol and diesel), and energy storage (by converting intermittent renewable energy into hydrogen). The key benefit of using hydrogen is that it is a clean fuel that emits only water vapour and heat when combusted. To support implementation of the National Hydrogen Strategy, Geoscience Australia in collaboration with Monash University are releasing the Hydrogen Economic Fairways Tool (HEFT). HEFT is a free online tool designed to support decision making by policymakers and investors on the location of new infrastructure and development of hydrogen hubs in Australia. It considers both hydrogen produced from renewable energy and from fossil fuels with carbon capture and storage. Tune in to this seminar to discover HEFT’s capabilities, its potential to attract worldwide investment into Australia’s hydrogen industry, and what’s up next for hydrogen at Geoscience Australia.

From the beginning of petroleum exploration in the Perth Basin, the importance of the Early Triassic marine Kockatea Shale was recognised as the principal source for liquid petroleum in the onshore northern Perth Basin (Powell and McKirdy, 1976). Thomas and Barber (2004) constrained the effective source rock to a Early Triassic, middle Sapropelic Interval in the Hovea Member of the lower Kockatea Shale. In addition, Jurassic and Permian sourced-oils (Summons et al., 1995) demonstrate local effective non-Kockatea source rocks. However, evidence for multiple effective gas source rocks is limited. This study utilizes the molecular composition and carbon and hydrogen isotopic compositions of 34 natural gases from the Perth Basin, extending the previous study (Boreham et al., 2001) to the offshore and includes hydrogen isotopes and gases. It shows the existence of Jurassic to Permain gas systems in the Perth Basin.

<div>The bulk source rock database table contains publicly available results from Geoscience Australia's organic geochemistry (ORGCHEM) schema and supporting oracle databases for the bulk properties of sedimentary rocks that contain organic matter and fluid inclusions taken from boreholes and field sites. The analyses are performed by various laboratories in service and exploration companies, Australian government institutions, and universities, using a range of instruments. Sedimentary rocks that contain organic matter are typically referred to as source rocks (e.g., organic-rich shale, oil shale and coal) and the organic matter within the rock matrix that is insoluble in organic solvents is named kerogen. Data includes the borehole or field site location, sample depth, stratigraphy, analytical methods, other relevant metadata, and various data types including; elemental composition, and the stable isotopes of carbon, hydrogen, nitrogen, and sulfur. Results are also included from methods that separate the extractable organic matter (EOM) from rocks into bulk components, such as the quantification of saturated hydrocarbon, aromatic hydrocarbon, resin and asphaltene (SARA) fractions according to their polarity. The stable carbon (¹³C/¹²C) and hydrogen (²H/¹H) isotopic ratios of the EOM and derivative hydrocarbon fractions, as well as fluid inclusion oils, are presented in delta notation (i.e., &delta;¹³C and &delta;²H) in parts per mil (‰) relative to the Vienna Peedee Belemnite (VPDB) standard.</div><div><br></div><div>These data are used to determine the molecular and isotopic compositions of organic matter within rocks and associated fluid inclusions and evaluate the potential for hydrocarbon generation in a basin. Some data are generated in Geoscience Australia’s laboratory and released in Geoscience Australia records. Data are also collated from destructive analysis reports (DARs), well completion reports (WCRs), and literature. The bulk data for sedimentary rocks are delivered in the Source Rock Bulk Properties and Stable Isotopes web services on the Geoscience Australia Data Discovery Portal at https://portal.ga.gov.au which will be periodically updated.</div>

<div>GeoInsight was an 18-month pilot project developed in the latter part of Geoscience Australia’s Exploring for the Future Program (2016–2024). The aim of this pilot was to develop a new approach to communicating geological information to non-technical audiences, that is, non-geoscience professionals. The pilot was developed using a human-centred design approach in which user needs were forefront considerations. Interviews and testing found that users wanted a simple and fast, plain-language experience which provided basic information and provided pathways for further research. GeoInsight’s vision is to be an accessible experience that curates information and data from across Geoscience Australia, helping users make decisions and refine their research approach, quickly and confidently.</div><div><br></div><div>In the first iteration of GeoInsight, selected products for energy, minerals, water, and complementary information from Geoscience Australia’s Data Discovery Portal and Data and Publications Catalogue were examined to (1) gauge the relevance of the information they contain for non-geoscientists and, (2) determine how best to deliver this information for effective use by non-technical audiences.</div><div><br></div><div>This Record documents the technical details of the methods used for summarising energy commodities for GeoInsight. These methods were devised to convey current production and future production/extraction potential quickly and efficiently for regions across the Australian continent. Evaluated energy commodities include oil and gas, hydrogen and geological hydrogen storage, uranium and thorium, coal (black and brown), geothermal energy, and renewable energy. Carbon storage, a decarbonisation enabler, was also addressed under the energy theme.</div><div><br></div><div>This document contains two sections:</div><div><strong>Production Summary:</strong> To showcase where energy resources are being produced in different regions of Australia. The source datasets provide a snapshot of energy production activities at the time of publication. </div><div><strong>Potential Summary:</strong> To highlight, at first glance, the likelihood that future energy production and decarbonisation initiatives may occur in different regions of Australia. The source datasets provide a snapshot of future energy potential at the time of publication.</div><div><br></div><div>Any updates to the methodology used in GeoInsight will be accompanied by updates to this document, including a change log.</div><div>Geoscience Australia’s Exploring for the Future program provides precompetitive information to inform decision-making by government, community and industry on the sustainable development of Australia's mineral, energy and groundwater resources. By gathering, analysing and interpreting new and existing precompetitive geoscience data and knowledge, we are building a national picture of Australia’s geology and resource potential. This leads to a strong economy, resilient society and sustainable environment for the benefit of all Australians. This includes supporting Australia’s transition to net zero emissions, strong, sustainable resources and agriculture sectors, and economic opportunities and social benefits for Australia’s regional and remote communities. The Exploring for the Future program, which commenced in 2016, is an eight year, $225m investment by the Australian Government.</div><div><br></div>