Geoscience Australia houses one of the world's largest collections of petroleum data. Much of this data is non-confidential and available to the petroleum industry, research organisations and the public. The collection includes well data submitted by industry under legislative requirements as well as data collected by research projects and marine surveys undertaken by Geoscience Australia or other government agencies or institutions. The collections comprise of digital data such as well completion reports, well logs, destructive analysis reports, vertical seismic profiles, core photography, special studies and also hard-copy well log data and graphs submitted during the pre-digital era. <b>Value: </b> information related to the subsurface that have the potential to support geological investigations and assessment of a variety of resources. <b>This data can be discovered through the National Offshore Petroleum Information Management System (NOPIMS) - http://www.ga.gov.au/nopims</b>

The dataset was created by Geoscience Australia using the framework described in Section 33 of the Offshore Petroleum and Greenhouse Gas Storage Act 2006 (OPGGS Act) and previous Acts. The international, scheduled areas and coastal waters used in this dataset are those found in the current Australian Maritime Boundary Dataset 2020 (AMB2020). The 2020 release has been updated to reflect the 2018 Timor Sea Treaty. Available for download in GDA94 or GDA2020. The dataset is comprised of both polygons and points created to very high precision, accurate to within millimetres. The blocks have been cut by Australia's international boundaries, the scheduled areas and the coastal waters. Each block is assigned a polygon, including partial blocks. All blocks are titled with their block ID, and a list of vertices that make up the blocks. Each vertex of the dataset is also replicated as a discrete point in the points dataset. The design of the dataset allows for the exact location of every vertex to be known to millimetre precision. The corner coordinates of blocks are now defined to a high precision, and can be found by querying the appropriate point. The blocks are attributed with fields containing information on: - Block ID - Parent 1 Million Mapsheet - Offshore Area - Epoch of the boundaries used to cut the data AMB2014 - Datum - Origin of the mapsheet in AGD66 - The position of all vertices in the block - The number of vertices in the block - The area of the block in acres - The area of the block in hectares The calculation used to find the area of the blocks is estimated to be precise to better than 1%. This is considered to be sufficient as under the permit and licensing arrangements in the OPGGS Act, the area of a block has no relevance. Therefore the area figure is provided solely for reference.

Videos of our primary professional learning sessions: Year 3-4 Stage 2 (middle primary): This session focussed on ‘Earth’s surface changes over time as a result of natural processes and human activity’. The activities emphasised practical investigations of weathering and erosion processes. 30 minutes long. Year 5-6 Stage 3 (upper primary): This session focused on teaching about ‘Sudden geological changes and extreme weather events that can affect Earth’s surface’. Geohazards were the main topic covered and suggested activities to undertake with students were demonstrated. 50 minutes long. These sessions are recordings of Zoom presentations. The accompanying PowerPoint slides are available for download, the presentations also include demonstrations of hands on activities. <p>

This report presents groundwater levels results from the Upper Burdekin Groundwater Project in North Queensland, conducted as part of Exploring for the Future (EFTF)—an eight year, $225 million Australian Government funded geoscience data and information acquisition program focused on better understanding the potential mineral, energy and groundwater resources across Australia. The Upper Burdekin Groundwater Project is a collaborative study between Geoscience Australia and the Queensland Government. It focuses on basalt groundwater resources in two geographically separate areas: the Nulla Basalt Province (NBP) in the south and the McBride Basalt Province (MBP) in the north. This report describes a data release of water levels measured in monitoring bores in both provinces by Geoscience Australia during the EFTF project. It includes: - A full description of how water levels in metres relative to Australian Height Datum (m AHD; where zero m AHD is an approximation of mean sea level) were calculated from manual dips and electronic dataloggers for this project. - A series of tables in Appendix A containing sufficient information for each bore and datalogger file to reproduce the water levels reported in Appendix B and Appendix C. - A series of hydrographs in Appendix B showing how water levels (in m AHD) interpreted from manual dips and datalogger files varied during the EFTF project. - A series of electronic files in Appendix C that include (i) Data files from dataloggers in CSV file format that can be used with the information contained in this data release to regenerate the water levels shown on hydrographs in Appendix B, and (ii) Data files in CSV file format reporting the final water levels used to generate the hydrographs in Appendix B. This data release report does not include hydrograph interpretation, which is undertaken in detail in: Cook, S. B. & Ransley, T. R., 2020. Exploring for the Future—Groundwater level interpretations for the McBride and Nulla basalt provinces: Upper Burdekin region, North Queensland. Geoscience Australia, Canberra, https://pid.geoscience.gov.au/dataset/ga/135439.

This resource includes backscatter data for Arafura Marine Park (Arafura Sea) collected by Geoscience Australia (GA) and the Australian Institute of Marine Science during the period 2 – 15 November 2020 on the RV Solander. The survey was undertaken as a collaborative project funded through the National Environmental Science Program Marine Biodiversity Hub, with co-investment by GA and AIMS. The purpose of the project was to build baseline information for benthic habitats in Arafura Marine Park that will support ongoing environmental monitoring within the North Marine Park Network as part of the 10-year management plan (2018-2028). Data acquisition for the project included multibeam bathymetry and backscatter for two areas (Money Shoal and Pillar Bank), seabed samples and underwater imagery of benthic communities and demersal fish. This backscatter dataset contains two 32-bit geotiff files of the backscatter mosaic for two survey areas produced from the processed EM2040C Dual Head system using the CMST-GA MB Process v15.04.04.0 (x64) toolbox software co-developed by the Centre for Marine Science and Technology at Curtin University and Geoscience Australia. A detailed report on the survey is provided in: Picard, K. Stowar, M., Roberts, N., Siwabessy, J., Abdul Wahab, M.A., Galaiduk, R., Miller, K., Nichol, S. 2021. Arafura Marine Park Post Survey Report. Report to the National Environmental Science Program, Marine Biodiversity Hub (https://www.nespmarine.edu.au/node/4505).

Offshore Minerals Act (OMA 1994) - Mineral Blocks. This service displays the most recent realisation of the Mineral Blocks as defined under the Offshore Minerals Act 1994 (OMA 1994) as realised in GDA94. Block data extends beyond the area of operation of the OMA and includes areas of coastal waters and land within the constitutional limits of the States and Territories.

This web service provides access to datasets generated by the North Australian Craton (NAC) Iron Oxide Copper Gold (IOCG) Mineral Potential Assessment. Two outputs were created: a comprehensive assessment, using all available spatial data, limiting data where possible to capture mineral systems older than 1500 ma, and; a coverage assessment, which is constrained to data that have no reliance on outcrop or age of mineralisation.

Australia is endowed with abundant, high quality energy resources, which provide both affordable and reliable energy for domestic use, and underpin our status as a major global energy provider. Australia continues to have the world’s largest economic uranium resources, the third largest coal resources, and substantial conventional and unconventional natural gas resources. Gas production has grown rapidly in recent years enabled by a series of new LNG projects on the North West Shelf, together with established CSG projects in Queensland. In 2019, Australia became the world’s largest LNG exporter on an annualised basis. Results from Geoscience Australia’s 2021 edition of the Australian Energy Commodity Resources assessment highlight that the nation’s energy commodity resources are widely distributed and include a significant resource potential in many onshore and offshore basins. Knowledge of the existing and untapped resource potential allows decision makers to prioritise development of energy resources that are able to support Australia’s recovery from the recent economic downturn. This aligns well with the Australian Government’s plans to support the development of natural gas resources in order to enable a rapid transition to a low carbon economy. A key component of Australia’s clean energy future and economic recovery will be the development of a hydrogen industry, with hydrogen produced either through electrolysis of water using renewable energy resources (green hydrogen), or manufactured from natural gas or through coal gasification with CCS of the co-produced CO2 (blue hydrogen). Geoscience Australia’s assessment includes a synopsis of the current status of Australia’s rapidly evolving hydrogen industry. Appeared in The APPEA Journal 61(2) 325-330, 2 July 2021

The Seas and Submerged Lands Act (SSLA) 1973 is the Australian legislation that provides the domestic legal framework for Australia to declare its international offshore maritime zones, as provided for by the United Nations Convention on the Law of the Sea (UNCLOS) to which Australia is a party. Proclamations under the SSLA establish the territorial sea baseline, the territorial sea, the contiguous zone, the exclusive economic zone and the continental shelf. This service depicts official spatial representation of these proclamations. The service includes feature layers: Normal and Straight baselines limits and locations; Contiguous Zone and limit; Territorial Sea Zone and limit; Exclusive Economic Zone (EEZ), limits and locations; Continental Shelf limit and locations.

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.