Your search keyword '"Published_External"' showing total 140 results

1. Glass Google Arts and Culture Exhibit and Crossword

Author

T., Sullivan

Subjects

CHEMICAL SCIENCES, EARTH SCIENCES, Educational Product, EDUCATION, Glass, Published_External

Abstract

Google Arts and Culture exhibit explaining how man-made and natural glass is formed and the key characteristics of glass. The exhibit features high quality images of fulgurites (glass created by lightning), obsidian (glass from volcanoes) and Australites (glass created by meteorite impacts). The accompanying crossword draws upon content within the exhibit.

Published

2023

2. Australia's Identified Mineral Resources 2022

Author

A., Hughes, A., Britt, J., Pheeney, D., Summerfield, A., Senior, A., Hitchman, A., Cross, M., Sexton, H., Colclough, and J., Hill

Subjects

Mineral Resources, Minerals Inventory, GEOLOGY, Published_External, Mineral Commodity

Abstract

Australia's Identified Mineral Resources is an annual national assessment that takes a long-term view of Australian mineral resources likely to be available for mining. The assessment also includes evaluations of long-term trends in mineral resources, world rankings, summaries of significant exploration results and brief reviews of mining industry developments.

Published

2023

3. AusArray TROMINO® active seismic data acquisition, processing and MASW modelling

Author

J., Holzschuh

Subjects

EARTH SCIENCES, Active seismic, EFTF - Exploring For The Future, Published_External, AusArray

Abstract

Geoscience Australia’s Exploring for the Future program (EFTF) provides precompetitive information to inform decision-making by government, community and industry on the sustainable development of Australia's mineral, energy and groundwater resources. The Australian Passive Seismic Array Project (AusArray) program developed from a long history of passive seismic imaging in Australia involving many contributors. Building on this history, the Australian Government (EFTF), academia and state governments have united around AusArray. The objective is a standardised and quality controlled national passive seismic data coverage and an updatable national seismic velocity model framework that can be used as a background for higher-resolution studies. The AusArray passive seismic data are supplemented with active seismic data that can provide P-wave and S-wave velocity information for the near surface down to about 50 m depth. This near-surface velocity data will provide constraints for some AusArray passive seismic data modelling to obtain more reliable depth models. This document details the active seismic data acquisition using TROMINO® three-axis broadband seismometers using a wireless trigger and hammer source. Equipment packing, field operations, data extraction and preparation, and Multichannel Analysis of Surface Waves (MASW) modelling are described.

Published

2023

4. Exploring for the Future – Baseline whole rock geochemistry for South Australia Data release — geochemistry of drill core samples from the Stuart Shelf region, South Australia

Author

D., Huston, D.C., Champion, D.L., Huston, E., Bastrakov, P., Main, S., Gilmore, J., Byass, and S., Webber

Subjects

EFTF - Exploring for the Future, EARTH SCIENCES, Quality Assurance, Chemometrics, Traceability and Metrological Chemistry, Published_External, STATISTICS, Inorganic Geochemistry

Abstract

The Exploring for the Future (EFTF) program is an Australian government initiative to boost investment in resource exploration and development in Australia, and is committed to supporting a strong economy, resilient society and sustainable environment for the benefit of Australians. There are a number of interrelated projects within the EFTF, including the Australia’s Resources Framework (ARF) project. The latter is a continental-scale project aimed at laying the foundations for a national view of Australia’s surface and subsurface geology, to underpin our understanding of the continent’s mineral, energy and groundwater potential. The ARF project involves new, large-scale data acquisition, advances in big data analytics and tailored resource assessments, to support the resource sector, agriculture, remote communities and the environment, and contribute to community safety. As part of ARF, Geoscience Australia has been undertaking studies of Australian basins that are prospective for, or have potential for, basin-hosted base metal mineral systems (Pb-Zn, Co-Cu), as part of the basins module. The first component of this module (2016-2020) investigated the Paleoproterozoic to Mesoproterozoic greater McArthur Basin system, Northern Territory and western Queensland (Champion et al., 2020 a, b, c; Huston et al. 2020). The 2020-2024 module is focusing on the Neoproterozoic part of the Stuart Shelf region of the Adelaide Superbasin, South Australia. The Paleo- to Mesoproterozoic sedimentary and volcanic sequences of the Mount Isa–McArthur Basin region of Northern Territory and Queensland are host to a range of world class mineral deposits (Hutton et al., 2012) and include the basin-hosted base metal deposits of the North Australian Zinc Belt, the world’s richest belt of zinc deposits (Huston et al., 2006; Large et al., 2005). These syngenetic (and epigenetic) basin-hosted mineral deposits include McArthur River (formerly HYC) and Century lead-zinc (Pb-Zn) deposits, the Walford Creek Zn-Pb-Cu-Ag deposit (Rohrlach et al., 1998; Large et al., 2005; Hutton et al. 2012) and the Redbank Cu deposit (Knutson et al. 1979). The Neoproterozoic sedimentary sequences of the Stuart Shelf, and their continuation into the Torrens Hinge Zone and Adelaide Rift Complex (Adelaide Superbasin), South Australia, are host to, or form an integral part of, a number of, often historically important, deposits, including the first copper mining region in Australia. These include, amongst others, the Kapunda, Mt Gunson, Cattle Grid, MG14, Windabout, Myall Creek, and Emmie Bluff copper deposits (Lambert et al. 1980, 1984, 1985 1987; Knutson et al. 1983; Coda Minerals 2020, 2021). These deposits are hosted within the Neoproterozoic sediments or along the basal unconformity with older Mesoproterozoic clastic sedimentary rocks (Lambert et al. 1987). This report contains reanalysed geochemical data, and associated sample metadata, for legacy samples collected by the Baas Becking laboratories in the 1970’s from deposits and surrounds in the MacArthur Basin and Stuart Shelf region. This includes samples (mafic igneous rocks, mineralised samples and sedimentary rocks) from the Redbank Cu deposit and surrounds in the McArthur Basin, partly documented in Knutson et al. (1979); samples (sediments, mafic igneous rocks including basement volcanic units (Gawler Range Volcanics), and mineralised samples) from the Mt Gunson deposit and surrounds (Mt Gunson-Lake Dutton area) documented in Knutson et al. (1983, 1992); and a small subset of five samples (sediments, variably mineralised) from the Myall Creek prospect, documented in Lambert et al. (1984). The great majority of these samples are from drill core, with the full list of samples analyses and metadata listed in Appendix A and summarised in Table 1. This data release also includes 52 samples from the Killi Killi Hills regions and surrounds, Tanami, Northern Territory (jobno 9004424), collected by the NTGS and GA, and originally analysed, in the early 1990’s and early 2000’s. These samples included a subset of P2O5-Sr-HREE-enriched Gardiner Sandstone samples from the Killi Killi Hills prospect. These samples are not directly related to the basins project but have been included as they were analysed at the same time as the Stuart Shelf and Redbank samples, and they increase the number of samples and the range of rock types analysed, and so help with statistics for QA/QC purposes. All geochemical data are provided in the appendices, listed by batch. The data can be downloaded via the Geoscience Australia EFTF portal (https://portal.ga.gov.au/persona/eftf).

Published

2023

5. Exploring for the Future Overview Video

Author

T., Steeper and M., ORourke

Subjects

geoscience, geology, Minerals, precompetitive geoscience, FOS: Earth and related environmental sciences, precompetitive, Published_External, critical minerals, Exploring for the Future (EFTF), groundwater cultural values and knowledge, energy

Abstract

This video gives an overview of the $225 million Exploring for the Future program (2016-2024), the Australian Government’s flagship precompetitive geoscience initiative. It uses cutting-edge technologies and approaches to deliver world-leading information about the geological structure, systems and evolution of the Australian continent.

Published

2023

6. Exploring for the Future - Fluid Inclusion Petrology and Microthermometry on selected samples from NDI Carrara 1

Author

C., Carson, S., Cowan, D., Hall, W., Phiukhao, J., Chao, and C., Boreham

Subjects

EFTF - Exploring for the Future, fluid inclusions, South Nicholson, EARTH SCIENCES, microthermometry, NDI Carrara 1, GEOLOGY, Published_External, Barkly-Isa-Georgetown, Barkly Tablelands, calcite veins

Abstract

Geoscience Australia’s Exploring for the Future (EFTF) 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 a low emissions economy, strong 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. The deep stratigraphic drill hole, NDI Carrara 1 (~1751 m), was completed in December 2020 as part of the MinEx CRC National Drilling Initiative (NDI) in collaboration with Geoscience Australia and the Northern Territory Geological Survey. It is the first test of the Carrara Sub-basin, a depocentre newly discovered in the South Nicholson region based on interpretation from seismic surveys (L210 in 2017 and L212 in 2019) recently acquired as part of the Exploring for the Future program. The drill hole intersected approximately 1100 m of Proterozoic sedimentary rocks uncomformably overlain by 630 m of Cambrian Georgina Basin carbonates. This contractor report (FIT - Schlumberger) presents hydrocarbon and aqueous fluid inclusion petrology and data (micro-thermometry, salinities etc.) on four hydrocarbon-bearing calcite veins sampled from NDI Carrara 1 between 762.56-763.60 m depth, (under contract to, and fully funded by, Geoscience Australia as part of the Exploring for the Future program).

Published

2023

7. Australia's Energy Commodity Resources (AECR), 2023 Edition

Author

S., Wall and B., Bradshaw

Subjects

coal, Australia’s Future Energy Resources, uranium thorium, Australia’s Energy Commodity Resources, gas, Earth Sciences, Published_External, oil

Abstract

Australia’s Energy Commodity Resources (AECR) provides estimates of Australia’s energy commodity reserves, resources, and production as at the end of 2021. The 2023 edition of AECR also includes previously unpublished energy commodity resource estimates data compiled by Geoscience Australia for the 2021 reporting period. The AECR energy commodity resource estimates are based primarily on published open file data and aggregated (de identified) confidential data. The assessment provides a baseline for the production and remaining recoverable resources of gas, oil, coal, uranium and thorium in Australia, and the global significance of our nation’s energy commodity resources.

Published

2023

8. Basin Inventory Adavale Basin

Author

T., Palu and R., Korsch

Subjects

EFTF - Exploring for the Future, Petroleum and Reservoir Engineering, Adavale Basin, EARTH SCIENCES, GEOLOGY, Basin Analysis, Published_External

Abstract

A large proportion of Australia’s onshore sedimentary basins remain exploration frontiers. Industry interest in these basins has recently increased due to the global and domestic energy demand, and the growth in unconventional hydrocarbon exploration. In 2016 and 2018, Geoscience Australia released an assessment of several central Australian basins that summarised the current status of geoscientific knowledge and petroleum exploration, and the key questions, for each basin. This publication provides a comprehensive assessment of the geology, petroleum systems, exploration status and data coverage for the Adavale Basin.

Published

2023

9. Summary of results. Joint GSQ-GA geochronology project. Mount Isa region, 2017-2018

Author

N., Kositcin, C., Lewis, I.W., Withnall, A.P., Slade, S., Sargent, and L.J., Hutton

Subjects

U-Pb geochronology, National Collaborative Framework, Geochronology, monazite, Queensland, GEOLOGY, zircon, Published_External, SHRIMP

Abstract

This Queensland Geological Record presents ten new Sensitive High Resolution Ion MicroProbe (SHRIMP) U–Pb zircon and monazite results obtained under the auspices of the Geological Survey of Queensland–Geoscience Australia (GSQ–GA) National Collaborative Framework (NCF) geochronology project between July 2017 and June 2018. These data were collected in support of ongoing regional mapping and geoscientific programs led by the GSQ in the Mount Isa region. Bibliographic reference:Kositcin, N., Lewis, C. J. Withnall, I. W., Slade, A. P., Sargent, S. and Hutton, L. J. 2023. Summary of results. Joint GSQ–GA Geochronology Project: Mount Isa region, 2017–2018. GSQ Record 2023/03. Geoscience Australia, Canberra. Record 2023/32, Geological Survey of Queensland. http://dx.doi.org/10.26186/147793

Published

2023

10. A Stratigraphic Reconstruction of Bulk Volatile Chemistry from Fluid Inclusions in: Birksgate 1

Author

S., Cowan, C., Boreham, D., Hall, J., Chao, W., Phiukhao, R., Lishansky, R., Moore, D., Groves, and D., Edwards

Subjects

thin section, fluid inclusion, EARTH SCIENCES, Officer-Musgrave, Onshore Energy Project, microthemometry, EFTF - Exploring For The Future, Published_External

Abstract

Exploring for the Future (EFTF) is an Australian Government program led by Geoscience Australia (GA), in partnership with state and Northern Territory governments. The EFTF program (2016-2024) aims to drive industry investment in resource exploration in frontier regions of onshore Australia by providing new precompetitive data and information about their energy, mineral and groundwater resource potential. Under the EFTF program, the Onshore Energy Project undertook a study of petroleum prospectivity of the onshore Officer Basin in South Australia and Western Australia. Birksgate 1 well in South Australia was selected based on the occurrence of gas and oil shows reported in the well completion report. Sampling of cuttings and cores was done at Geoscience Australia's Petroleum Data Repository in Canberra. Geoscience Australia commissioned a fluid inclusion stratigraphy (FIS) study on the downhole samples. Here, volatile components ostensibly trapped with fluid inclusions are released and analysed revealing the level of exposure of the well section to migrating fluids. Integration of thin section (TS) preparations reveal to extent of gas and fluid trapping within fluid inclusions while microthemometry (MT) gives an estimation of fluid inclusion trapping temperature. For Birksgate 1, FIS analysis was performed on 414 cuttings and 33 cores between 150 feet and 6161 feet base depth, together with 14 samples prepared for TS and 3 samples for MT. To support this study, lithostratigraphic tops were compiled by Geoscience Australia. The results of the study are found in the accompanying documents.

Published

2023

11. Review of the Permian-Triassic boundary palynology in selected southern Bonaparte Basin wells

Author

R., Owens, D., Mantle, and C., Hannaford

Subjects

Petrel Sub-basin, Palaeontology (incl. palynology), biostratigraphy, Permian, Published_External, palynology, Bonaparte Basin

Abstract

This report presents the results from detailed palynological analyses of both newly processed samples and re-analysis of existing slides across the upper Permian to Lower Triassic section from the following wells across the southern Bonaparte Basin: Tern 3, Tern 5, Ascalon 1A, Blacktip P1, Blacktip 2, Petrel 1A, Petrel 4, Petrel 5, Prometheus 1, Rubicon 1, Torrens 1. This palynological zonal work is supplemented with palynofacies analyses in a subset of wells. In addition to these new analyses, a review of the existing palynological data from open file palynological reports (in company well completion reports) was undertaken for both the immediately under- and overlying late Permian and earliest Triassic intervals in the newly sampled wells and offset wells of the Tern and Petrel gas fields, including the following wells: Petrel 2, Petrel 3, Petrel 6, Tern 1, Tern 2, Tern 4.

Published

2023

12. Australian Critical Minerals Map 2022

Author

A.F., Britt, H., Colclough, and J., Pheeney

Subjects

Operating Mines, Infrastructure, Geoscience, Developing Mines, Critical Mineral Deposits, EARTH SCIENCES, Thematic Map, Critical Minerals, Published_External, Care and Maintenance, Mining

Abstract

This map shows the locations and status, as at 31 December 2022, of Australian operating mines, mines under development, mines on care and maintenance and resource deposits associated with critical minerals. Developing mines are deposits where the project has a positive feasibility study, development has commenced or all approvals have been received. Mines under care and maintenance and resource deposits are based on known resource estimations and may produce critical minerals in the future. The critical mineral deposits on this map may not be comprehensive for all commodities. For the purposes of this map, critical minerals are defined as minerals and elements (solid and gaseous) that are vital for modern technology and whose supply may be at risk of disruption. The Australian critical minerals list comprises aluminium (high-purity alumina), antimony, beryllium, bismuth, chromium, cobalt, gallium, germanium, graphite, hafnium, helium, indium, lithium, magnesium, niobium, platinum group elements, rare earth elements, rhenium, scandium, silicon (high-purity silica), tantalum, titanium, tungsten, vanadium and zirconium. These commodities are coloured by mineral groupings on the map.

Published

2023

13. Legacy stream sediment sample reanalysis - Red River, Hann River, Ebagoola, Coen, Georgetown, Kakadu, Araluen, Brindabella, Hedleys Creek, and Mammoth Mines Surveys

Author

P., Main, D., Champion, J., Byass, and S., Gilmore

Subjects

Geochemistry, Legacy, Stream Sediments, ARF – Australia’s Resources Framework, EFTF – Exploring for the Future, FOS: Earth and related environmental sciences, Published_External, Inorganic Geochemistry

Abstract

Geoscience Australia has a large holding of surface sediment samples, such as stream and overbank sediments, from geochemical surveys conducted over more than 50 years across the Australian continent. Geochemical data from these surface materials are of national importance as they can contribute significantly to establishing geochemical environmental baselines and their use in land management, as well as aiding in the discovery of new mineral deposits. Samples from these legacy surveys provide valuable insights into areas of Australia that are remote, difficult to access, or have since been developed. The age of a large number of these surveys, however, means that the original results included data for a smaller range of chemical elements, typically with poorer analytical precision and accuracy than those of modern surveys. This small range of chemical elements also typically doesn’t include important elements for modern use, such as critical minerals (i.e. Co, Bi, REEs), which are increasing in their importance. As part of Geoscience Australia’s Exploring for the Future program, a collection of over 9000 samples from these surveys was reanalysed using modern analytical techniques for a suite of 60 chemical elements. These samples cover several regions within Australia, including Kakadu, Cape York, the Mount Isa region, and near the Canberra region. The new analytical data maximise the value of the historical geochemical surveys and will provide new insights into the mineral potential of these regions and improve the quality of geochemical environmental baselines. This data release includes: 1) information on the surveys and their samples; 2) quality assurance results; 3) a discussion of sample preparation and analytical methods used; 4) results for total content geochemistry (XRF and LA-ICP-MS); and 5) individual element maps for each of the regions for preliminary interpretation of the data.Acquisition and release of this dataset forms part of a larger program aimed at creating a levelled geochemical baseline for the whole Australia (Main and Champion, 2020).

Published

2023

14. Seamounts, Canyons and Reefs of the Coral Sea Marine Park

Author

A., Carroll, M., Mcneil, A., Post, Z., Huang, J., Cropper, and S., Nichol

Subjects

mesophotic, EARTH SCIENCES, Geomorphology and Regolith and Landscape Evolution, bathymetry, marine, biota, Coral Sea, Published_External

Abstract

This flythrough video highlights deep and mesophotic seabed environments within the Coral Sea Marine Park, offshore northeastern Australia. The mesophotic zone, commonly referred to as the ‘twilight zone’ represents the depth range below the brightly lit shallow waters down to the maximum depth that sunlight can penetrate for photosynthesis to occur (~ 30 to 150 meters beneath the sea surface). The featured Malay and North Flinders Reefs represent mid-ocean platform reefs and Cairns Seamount hosts a thriving coral reef community atop what is likely an extinct volcanic cone. These locations represent a range of benthic communities, which vary with depth and substrate type. Soft-sediments (sands, muds and oozes) dominate the deep seafloor, with evidence of water currents that produce bedforms showing active sediment transport at these depths. The walls and flanks of the platform reefs are very steep, with evidence of slope failure where rocky head walls have collapsed and deposited large blocks and boulders on the seafloor, which provide important habitat for sessile and mobile invertebrates including soft corals and sponges as well as cryptic octopus. Typical mesophotic habitats included vast Halimeda algal meadows and rhodolith beds interspersed with soft corals and sponges on soft-sediment. Hard substrates were typically colonised by plate and encrusting hard Scleractinian corals (e.g. Leptoseris and Montipora species), sponges and ascidians. Many large black corals (Antipatharia) and gorgonians (Octocorallia) also featured, with several black coral and carnivorous sponge observations representing new species. The reef community atop Cairns Seamount was highly diverse and included many demersal and pelagic fish species. A high abundance and diversity of gelatinous zooplankton were observed in the deep waters between reefs in the Coral Sea, with several new range extensions recorded. Bathymetry data and seafloor imagery for this flythrough were collected on RV Falkor, owned and operated by the Schmidt Ocean Institute (SOI), during surveys FK200830 and FK200902 in August and October 2020. These surveys were led by Geoscience Australia and James Cook University. Collaborative research partners included the Japan Agency for Marine-Earth Science and Technology, The University of Tokyo, Queensland University of Technology, Queensland Museum, The University of Sydney, University of Tasmania and the University of Wollongong.

Published

2023

15. Wireline log data analysis in NDI Carrara 1, Northern Territory

Author

L., Wang, A., Bailey, E., Grosjean, C., Carson, L., Carr, G., Butcher, C., Boreham, and P., Henson

Subjects

Exploring for the Future, EARTH SCIENCES, Barkly-Isa-Georgetown project, Carrara Sub-basin, Reservoir characterisation, wireline log, Petrophysics, Total organic carbon content, NDI Carrara 1, MinEx Cooperative Research Centre (CRC), Gas content, South Nicholson Region, Published_External, Chemostratigraphy, Porosity

Abstract

As part of Geoscience Australia’s Exploring for the Future program, this study aims to analyse the hydrocarbon prospectivity in the Carrra Sub-basin through wireline log interpretation and shale gas reservoir characterisation. NDI Carrara 1 is the first stratigraphic test of the Carrara Sub-basin, a recently uncovered depocentre located within the South Nicholson region of the eastern Northern Territory and northwestern Queensland. Four chemostratigraphic packages were defined according to the informal sub-division of stratigraphy and inorganic geochemical properties. Wireline log interpretation has been conducted to derive the clay mineral compositions, porosity, gas saturation and gas contents for the unconventional shale gas reservoirs in the Proterozoic succession in NDI Carrara 1. The predominant clay minerals include illite/muscovite, mixed-layer clay, smectite, kaolinite, and minor contents of glauconite and chlorite. The average geothermal gradient is estimated to be 35.04 °C/km with a surface temperature of 29.4 °C. The average formation pressure gradient is calculated to be < 10.7 MPa/km from mud weight records. Artificial neural network technology is used to interpret the TOC content from wireline logs for unconventional shale gas reservoirs. TOC content is positively correlated with methane and ethane concentrations in mudlog gas profiles, shale porosity, formation resistivity and gas content for NDI Carrara 1. The organic-rich shales in P2 have favourable adsorbed, free and total gas contents. The organic-rich micrites within P3 have the potential in adsorbed gas, but with very low average gas saturation (< 0.01 m3/m3). Our interpretation has identified potential shale gas reservoirs, as well as tight non-organic-rich shales and siltstones with potential as gas reservoirs. These occur throughout several of the identified chemostratigraphic packages within the Proterozoic section of NDI Carrara 1.

Published

2023

16. A Stratigraphic Reconstruction of Bulk Volatile Chemistry from Fluid Inclusions in: NDI Carrara 1

Author

C., Carson, S., Cowan, C., Boreham, D., Hall, J., Chao, W., Phiukhao, R., Lishansky, R., Moore, and D., Groves

Subjects

thin section, fluid inclusion, EARTH SCIENCES, Onshore Energy Project, microthemometry, Published_External, EFTF

Abstract

Exploring for the Future (EFTF) is an Australian Government program led by Geoscience Australia, in partnership with state and Northern Territory governments. The first phase of the EFTF program (2016-2020) aimed to drive industry investment in resource exploration in frontier regions of northern Australia by providing new precompetitive data and information about their energy, mineral and groundwater resource potential. One key discovery was the identification of a large sedimentary depocentre concealed beneath the Cambrian Georgina Basin. This depocentre, up to 8 km deep, was termed the ‘Carrara Sub-basin’ by Geoscience Australia. It is interpreted to contain thick sequences of Proterozoic rocks, broadly equivalent to rocks of the greater McArthur Basin (Northern Territory) and northern Lawn Hill Platform and Mount Isa Province (Queensland), known to be highly prospective for sediment-hosted base metals and unconventional hydrocarbons. In order to test geological interpretations in the Carrara Sub-basin, the South Nicholson National Drilling Initiative (NDI) Carrara 1 stratigraphic drill hole was completed in late 2020, as a collaboration between Geoscience Australia, the Northern Territory Geological Survey (NTGS) and the MinEx CRC managing of the drilling operation. NDI Carrara 1 is the first drill hole to intersect Proterozoic rocks of the Carrara Sub-basin. It reached a total depth of 1751 m, intersecting ca. 630 m of Cambrian Georgina Basin overlying ca. 1100 m of Proterozoic carbonates, black shales and minor siliciclastics. Geoscience Australia has undertaken a range of investigations on the lithology, stratigraphy and geotechnical properties of NDI Carrara 1. These analyses include geochronology, isotopic studies, mineralogy, inorganic and organic geochemistry, petrophysics, geomechanics, thermal maturity, and petroleum systems investigations. To increase the understanding of the petroleum potential, molecular hydrogen and helium potential of sedimentary and basement rocks, Geoscience Australia commissioned a fluid inclusion stratigraphy (FIS) study on the downhole samples. Here, volatile components ostensibly trapped with fluid inclusions are released and analysed revealing the level of exposure of the well section to migrating fluids. Integration of thin section (TS) preparations reveal to extent of oil trapping within fluid inclusions while microthemometry (MT) gives an estimation of fluid inclusion trapping temperature. For NDI Carrara 1, FIS analysis was performed on 86 cuttings between 18 m and 282 m base depth and 342 cores between 283.9 m and 1750.45 m base depth, together with 27 samples prepared for TS and 4 samples for MT. To support this study, lithostratigraphic tops were interpreted and compiled by Geoscience Australia. The results of the study are found in the accompanying documents.

Published

2023

17. National mineral potential for sediment-hosted zinc-lead mineral systems in Australia Version 1.0

Author

A., Ford, J., Cloutier, D., Huston, M., Doublier, A., Schofield, K., Waltenberg, P., de Caritat, G., Fraser, E., Beyer, E., Bastrakov, and K., Czarnota

Subjects

sediment-hosted base metals, Mineral potential, Data mining and knowledge discovery, Earth Sciences, EFTF – Exploring for the Future, Australia’s Resources Framework, Published_External, mineral systems

Abstract

Australian sediment-hosted mineral systems are important sources of base metals and critical minerals that are vital to delivering Australia’s low-carbon economy. In Australia, sediment-hosted resources account for ~82% and ~86% of the total zinc (Zn) and lead (Pb) resources respectively. Given their significance to the Australian economy, four national-scale mineral potential models for sediment-hosted Zn-Pb mineral systems have been developed: clastic-dominated siliciclastic carbonate, clastic-dominated siliciclastic mafic, Mississippi Valley-type and Irish-type. In addition to the potential for Zn-Pb mineralisation, the uncertainty related to data availability has been examined. The mineral potential models were created using a mineral systems-based approach where mappable criteria have been used to assess the prospectivity of each system. Each model has been derived from a large volume of precompetitive geoscience data. The clastic-dominated siliciclastic carbonate mineral potential model predicts 92% of known deposits and occurrences within 15.5% of the area, the clastic-dominated siliciclastic mafic mineral potential model predicts 85% of deposits and occurrences within 27% of the area, and the Mississippi Valley-type mineral potential model predicts 66% of known deposits and occurrences within 31% of the area. Each model successfully predict the location of major sediment-hosted Zn-Pb deposits while highlighting new areas of elevated prospectivity in under-explored regions of Australia, reducing the exploration search space by up to 85% for sediment-hosted Zn-Pb mineral systems.

Published

2023

18. Airborne Magnetic and Radiometric Technical Standards - Data Acquisition, Processing and Supply

Author

J., Goodwin

Subjects

Gradiometry, Technical Standards, Magnetometer, Radiometrics, Magnetics, Data Formats, Total Magnetic Intensity (TMI), Calibration, Horizontal Magnetic Gradient, Geophysical Acquisition and Processing Section, Published_External, Quality Tolerances, Gamma-ray Spectrometer, Airborne Geophysics, Applied geophysics, Reduction

Abstract

This document defines the technical standards set by Geoscience Australia for the acquisition, processing and supply of airborne magnetic, horizontal magnetic gradient and radiometric (gamma-ray spectrometric) data. The technical standards cover the requirements for equipment, calibrations, quality control checks, reporting and data formats for airborne surveys.Table of ContentsAttachment 1A – Data Acquisition and Processing1 Aircraft2 Flight and Tie Lines3 Global Navigation Satellite System (GNSS)4 Parallax Correction5 Altimeter6 Barometer7 Digital Elevation Model8 Magnetic System Equipment9 Magnetic Gradient System Equipment10 Magnetic / Gradient Calibration and Quality Tolerances11 Magnetic Base Station (Diurnal Monitoring)12 Magnetic Data Reduction13 Magnetic Gradient Data Reduction14 Radiometric System Equipment15 Radiometric Calibration and Quality Tolerances16 Radiometric Data ReductionAttachment 1B – Reporting and Data Supply1 General2 Calibration Report3 Daily Acquisition Report4 Weekly Acquisition Report5 Operations and Processing Summary Report6 Supply ScheduleAttachment 1C – Data Formats1 General2 Point-Located Data Files3 Definition Files4 Description Files5 Raw-Edited Magnetic Data File6 Reduced Magnetic Data File7 Diurnal Magnetic Data File8 Raw-Edited Magnetic Gradient Data File9 Reduced Magnetic Gradiometry Data File10 Raw-Edited Radiometric Data File11 Reduced Radiometric Data File12 Gridded Data Files13 Image Enhanced GeoTIFF Files

Published

2023

19. How do rocks store groundwater. Porosity and permeability experiments

Author

T., Sullivan and L., Soroka

Subjects

Groundwater hydrology, Earth sciences, porosity, groundwater, permeability, Published_External, Educational product, Education

Abstract

This document describes a series of experiments that grow student understanding of the concepts on porosity and permeability as it relates to groundwater. Sediments are used to substitute for sedimentary rocks and water movement through different types of sediment is evaluated. The document is split into two sections, background information for teachers and a 3 part experiment with activity sheet for students. The activities are suitable for use with secondary to senior secondary science and geography students.

Published

2023

20. York Earthquake Building Mitigation Implementation Project: Final Report

Author

M., Edwards, M., Wehner, J., Vaculik, M., Griffith, C., Littlefair, J., Whitney, P., Baxendale, and C., Arthur

Subjects

Earthquake, Mitigation, EARTH SCIENCES, Unreinforced masonry, Published_External, Retrofit

Abstract

Older unreinforced masonry (URM) buildings have been found to perform poorly in historical Australian earthquakes. Where these building are present in pedestrian precincts, they represent a significant risk to people and communities. Some towns and cities have a significant proportion of this type of building within business districts and Perth CBD is an example having 48% by number of URM construction ranging from pre-Federation to early-to-mid twentieth century in age. Further, these buildings are often of significant heritage value providing a sense of place to residents and contribute to visitor related business revenue. These factors all come to play in the town of York which is also in an area of elevated earthquake hazard. There is a need for information inform strategies and decision making around reducing the risk they represent. This project has had a focus on York and was designed as a three-year collaboration between researchers, industry and local stakeholders to improve the understanding of the vulnerability of older unreinforced masonry (URM) buildings. The building types considered are of the types found in York and other larger communities and the project has included methods of retrofit that can enhance the resilience of these buildings to earthquake hazard. It has further included the promotion of expertise with building design professionals and in the construction industry to undertake this work through a demonstration projects. Specifically, the project has been a collaboration between the Shire of York, the Department of Fire and Emergency Services, the University of Adelaide and Geoscience Australia. While not a direct project partner, the Department of Planning Lands and Heritage (DPLH) has also been a key stakeholder that has sought to facilitate the application for grant funding for the mitigation activity to be studied as part of this project.

Published

2023

21. Giving legacy data a new life - palaeovalleys from preliminary integrated interpretation

Author

M., Smith, N., Symington, and L., Halas

Subjects

Palaeovalleys, Groundwater hydrology, Officer-Musgrave, groundwater, EFTF – Exploring for the Future, Published_External, West Musgrave

Abstract

Previous work by the SA government and CSIRO[i] highlighted the value of integrating AEM data with other geological and hydrogeological data to model palaeovalley groundwater systems and develop regional hydrogeological conceptualisations. This allows better-informed water supply decisions and management for communities in remote parts of Australia where these systems provide the only available and long-term water resource. The Exploring for the Future Musgrave Palaeovalley module seeks to apply similar work flows across the western Musgrave Province and adjacent Officer and Canning basins.Open file mineral exploration AEM data from 11 surveys in WA and SA flown between 2009 and 2012 were re-processed and inverted to produce conductivity models and a suite of derived datasets. Geoscience Australia’s Layered-Earth-Inversion was used as a single standard processing and inversion method to improve continuity and data quality.These legacy AEM data, originally for mineral exploration, have been incorporated with DEM-derived landscape attributes, previous palaeovalley mapping and available bore lithologies to model palaeovalley base surfaces. This presentation will provide an example from four blocks of AEM data to show how repurposing data from mineral exploration, public bore data and landscape analysis can be used to identify palaeovalley systems which provide critical water supplies for remote and regional communities and industry[ii].This approach can be used to model palaeovalley systems from a range of geoscientific and other datasets. The Exploring for the Future Musgrave Palaeovalley module has acquired ~23,000 line km of AEM across parts of WA and the NT at line spacings of 1 and 5 km. This new precompetitive data will be used to model palaeovalley system geometry and integrate with new and existing AEM, drilling, landscape, groundwater chemistry and surface geophysics data to test hydrogeological conceptualisations of these groundwater systems. [i] Costar, A., Love, A., Krapf, C., Keppel, M., Munday, T., Inverarity, K., Wallis, I. & Sørensen, C. (2019). Hidden water in remote areas – using innovative exploration to uncover the past in the Anangu Pitjantjatjara Yankunytjatjara Lands. MESA Journal 90(2), 23 - 35 pp.Krapf, C., Costar, A., Stoian, L., Keppel, M., Gordon, G., Inverarity, K., Love, A. & Munday, T. (2019). A sniff of the ocean in the Miocene at the foothills of the Musgrave Ranges - unravelling the evolution of the Lindsay East Palaeovalley. MESA Journal 90(2), 4 - 22 pp.Krapf, C. B. E., Costar, A., Munday, T., Irvine, J. A. & Ibrahimi, T., 2020. Palaeovalley map of the Anangu Pitjantjatjara Yankunytjatjara Lands (1st edition), 1:500 000 scale. Goyder Institute for Water Research, Geological Survey of South Australia, CSIRO.https://sarigbasis.pir.sa.gov.au/WebtopEw/ws/samref/sarig1/wci/Record?r=0&m=1&w=catno=2042122. Munday, T., Taylor, A., Raiber, M., Sørensen, C., Peeters, L. J. M., Krapf, C., Cui, T., Cahill, K., Flinchum, B., Smolanko, N., Martinez, J., Ibrahimi, T. & Gilfedder, M., 2020a. Integrated regional hydrogeophysical conceptualisation of the Musgrave Province, South Australia, Goyder Institute for Water Research Technical Report Series 20/04, Goyder Institute for Water Research, Adelaide.Munday, T., Gilfedder, M., Costar, A., Blaikie, T., Cahill, K., Cui, T., Davis, A., Deng, Z., Flinchum, B., Gao, L., Gogoll, M., Gordon, G., Ibrahimi, T., Inverarity, K., Irvine, J., Janardhanan, Sreekanth, Jiang, Z., Keppel, M., Krapf, C., Lane, T., Love, A., Macnae, J., Mariethoz, G., Martinez, J., Pagendam, D., Peeters, L., Pickett, T., Robinson, N., Siade, A., Smolanko, N., Sorensen, C., Stoian, L., Taylor, A., Visser, G., Wallis, I. & Xie, Y., 2020b. Facilitating Long-term Outback Water Solutions (G-Flows Stage 3): Final Summary Report. Goyder Institute for Water Research, Adelaide, http://hdl.handle.net/102.100.100/376125?index=1. [ii] Symington, N. J., Ley-Cooper, Y. A. & Smith, M. L., 2022. West Musgrave AEM conductivity models and data release. Geoscience Australia, Canberra, http://pid.geoscience.gov.au/dataset/ga/146278. This Abstract was submitted/presented to the 2022 Sub 22 Conference 28-30 November (http://sub22.w.tas.currinda.com/)

Published

2023

22. Oil and Gas Titles Australia

Author

S., Wall and C., Evenden

Subjects

Gas, Energy Advice and Promotion, EARTH SCIENCES, Map, Titles, Published_External, Oil

Abstract

A downloadable map showing Australia's Oil and Gas Titles as at 22 December 2022

Published

2023

23. Cenozoic alkaline and related igneous rocks of Australia

Author

E., Beyer, M., Buddee, D., Champion, and L., Highet

Subjects

EARTH SCIENCES, Alkaline rocks, Igneous rocks, Australia, EFTF – Exploring for the Future, Australia’s Resources Framework, Published_External

Abstract

Alkaline and related rocks are a relatively rare class of igneous rocks worldwide. Alkaline rocks encompass a wide range of rock types and are mineralogically and geochemically diverse. They are typically thought to have been derived by generally small to very small degrees of partial melting of a wide range of mantle compositions. As such these rocks have the potential to convey considerable information on the evolution of the Earths mantle (asthenosphere and lithosphere), particularly the role of metasomatism which may have been important in their generation or to which such rocks may themselves have contributed. Such rocks, by their unique compositions and/ or enriched source protoliths, also have considerable metallogenic potential, e.g., diamonds, Th, U, Zr, Hf, Nb, Ta, REEs. It is evident that the geographic occurrences of many of these rock types are also important, and may relate to presence of old cratons, craton margins or major lithospheric breaks. Finally, many alkaline rocks also carry with them mantle xenoliths providing a snapshot of the lithospheric mantle composition at the time of their emplacement. Accordingly, although alkaline and related rocks comprise only a volumetrically minor component of the geology of Australia, they are of considerable importance to studies of lithospheric composition, evolution and architecture and to helping constrain the temporal evolution of the lithosphere. They are also directly related to metallogenesis and mineralisation, particularly for a number of the critical minerals, e.g., rare earth elements, niobium. In light of this, Geoscience Australia is undertaking a compilation of the distribution and geology of Australian alkaline and related rocks, of all ages, and producing a GIS and associated database of such rocks, to both document such rocks and for use in metallogenic and mineral potential studies.This contribution presents data on the distribution and geology of Australian alkaline and related rocks of Cenozoic age. The report and accompanying GIS document the distribution, age, lithology, mineralogy and other characteristics of these rocks (e.g. extrusive/intrusive, presence of mantle xenoliths, presence of diamonds), as well as references for data sources and descriptions. The report also reviews the nomenclature of alkaline rocks and classification procedures. GIS metadata are documented in the appendices.Cenozoic alkaline and related rocks occur primarily within a belt running from Northeastern Queensland, through eastern New South Wales into Victoria and through to South Australia and Tasmania with a single occurrence in Western Australia. Compositions range from peralkaline trachytic and rhyolitic rocks to lamprophyric rocks to alkali basalts and more undersaturated feldspathoid-bearing lithologies. Ages span the entire Cenozoic but locally and regionally are more restrictive. Bodies are generally of small volume (extrusive rocks) or of small size (intrusive rocks). On the basis of location (and lithology, age and/or alkaline classification), 332 individual geologic units have been grouped into 59 informal alkaline provinces. The latter provides a simplified broad-scale overview of the distribution of the Cenozoic alkaline and related rocks of Australia but also allows for better search capabilities at broad scales in the GIS environment (overcoming the small size of many alkaline bodies).

Published

2023

24. Australian Operating Mines Map 2022

Author

H., Colclough and J., Pheeney

Subjects

Geoscience, Thematic Map, Geology, FOS: Earth and related environmental sciences, Published_External, Mining

Abstract

This map shows the location and status, as at 31 December 2022, of Australian operating mines, mines under development and mines under care and maintenance. Developing mines are deposits where the project has a positive feasibility study, development has commenced or all approvals have been received. Mines under care and maintenance have known resource estimations and may be mined or developed in the future.

Published

2023

25. Petrography of the Birrindudu Basin

Author

C., Carson, R.H.C., Madden, L., Carr, and J., Anderson

Subjects

Thin Sections, X-ray Diffraction, Earth Sciences, EFTF – Exploring for the Future, Mineralogy and crystallography, Proterozoic, Sedimentology, Published_External, Mineralogy, Birrindudu Basin, Officer-Musgrave-Birrindudu, Petrology

Abstract

This report presents the results of petrographic and X-ray Diffraction analysis undertaken by Microanalysis Australia under contract to Geoscience Australia, on rock samples collected from selected drill holes across the Proterozoic Birrindudu Basin and underlying metamorphic basement.

Published

2023

26. Considerations for a water balance of the Great Artesian Basin

Author

P., Kilgour and B.M., Radke

Subjects

Groundwater hydrology, Great Artesian Basin, water balance, groundwater, GAB, Published_External

Abstract

This report summarises information regarding groundwater processes considered to have direct influence on the water balance for the Great Artesian Basin (GAB). These processes are recharge, discharge, and connectivity within the GAB sequence, as well as connectivity with underlying basins and overlying cover. The substantial body of literature available on the GAB gives the impression that there is a considerable degree of understanding of the GAB groundwater system. This is, however, misleading. The reality is that many reports and reviews have been cited or reworked from pre-existing studies without carrying over the original uncertainties. Over time, the scale of knowledge gaps has been reduced only incrementally, while there has been a growing appreciation of the complexities in the system. With so much conceptual and quantitative uncertainty, much additional investigation is still required.

Published

2023

27. Australian Geomagnetism Report 2017 2021

Author

H., Glanville, A., Lewis, M., Gard, W., Jones, G., Paskos, and L, Wang

Subjects

Magnetics, geomagnetic, Magnetism and Palaeomagnetism, magnetometer, Published_External

Abstract

This report contains information about the operation of Geoscience Australia’s ten permanent geomagnetic observatories, repeat stations and other relevant information covering the period from 2017 to 2021.Information regarding the activities and services of Geoscience Australia’s Geomagnetism program, distribution of geomagnetic data, geomagnetic instrumentation and data processing procedures is also provided.

Published

2023

28. XRD Report - Mineralogy of NDI Carrara 1 Samples

Author

J., Anderson, N., Owen, R., Fan, and C., Delle Piane

Subjects

South Nicholson region, NDI Carrara 1, EFTF – Exploring for the Future, Mineralogy and crystallography, MinEx CRC – Mineral Exploration Cooperative Research Centre, Sedimentology, Published_External, X-ray diffraction

Abstract

The South Nicholson National Drilling Initiative (NDI) Carrara 1 stratigraphic drill hole was completed in late 2020, as a collaboration between Geoscience Australia, the Northern Territory Geological Survey (NTGS), and the MinEx CRC. The drilling aimed to gather new subsurface data on the potential mineral and energy resources in the newly identified Carrara Sub-basin. NDI Carrara 1 is located in the eastern Northern Territory, on the western flanks of the Carrara Sub-basin on the South Nicholson Seismic line, reaching a total depth of 1751 m, intersecting ca. 630 m of Cambrian Georgina Basin overlying ca. 1100 m of Proterozoic carbonates, black shales and minor siliciclastics (https://portal.ga.gov.au/bhcr/minerals/648482). Following a public data release of the borehole completion report, CSIRO was contracted by Geoscience Australia (GA) under the Exploring for the Future program to analyse samples from NDI Carrara 1 for quantitative bulk and clay fraction analysis. This report presents results for quantitative bulk and clay (

Published

2023

29. Palynological data review of selected boreholes in the Great Artesian, Lake Eyre basins and Upper Darling Floodplain (part 2) ‒ Infilling data and knowledge gaps

Author

N., Rollet and C., Hannaford

Subjects

Great Artesian Basin, EARTH SCIENCES, Stratigraphy, Exploring For The Future (EFTF), Jurassic, Published_External, Palynology, Cretaceous

Abstract

This report presents palynological data compiled and analysed as part of the National Groundwater Systems (NGS) Project. NGS is 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. This study builds on previous work (Hannaford et al., 2022) undertaken as part of the ‘Assessing the Status of Groundwater in the Great Artesian Basin’ project, commissioned by the Australian Government through the National Water Infrastructure Fund – Expansion. The study undertaken by MGPalaeo, in collaboration with Geoscience Australia, examined an additional 688 boreholes across the GAB and compiled 149 new palynological summary sheets having Jurassic‒Cretaceous succession, with reviewed palynology data (down to total depth). The combined borehole palynological data examined from this study and the previous GAB work (Hannaford et al., 2022) is compiled in Appendix B4. The combined dataset totals 1,394 boreholes examined and 652 with palynology in the stratigraphic interval of interest, 102 of these boreholes contained Cenozoic palynology relevant to the Lake Eyre Basin. This information has been used to revise stratigraphic correlations across the GAB (Norton & Rollet, 2022 and 2023). Initial review of the stratigraphy in the Lake Eyre Basin (LEB) compiled existing palynology from outcrop, mineral and petroleum boreholes. An additional 28 boreholes in the Upper Darling Floodplain region were examined, 16 of which contained relevant palynology. The main palynological data infill in the GAB and LEB region during this follow-up study focused on: 1. Collecting, processing and analysing new biostratigraphic data on 149 key boreholes particularly across the Eromanga and Surat basins boundary. The study focussed on integrating data in New South Wales from the southern Surat Basin and central Eromanga Basin. 2. Further palynological data infill and palynological analysis on 15 samples from 7 boreholes in the western Eromanga Basin to assess difficulties in correlating the stratigraphy across the Algebuckina Sandstone. 3. Compiling existing analyses and update any historical palynological data in the Lake Eyre Basin to reflect the latest zonation scheme developed in this study. The new palynological data combined with new zircon data from other studies in the Carpentaria and Surat basins (Foley et al., 2020, 2021, 2022; La Croix et al., 2022, respectively) provides information on the tie to the geological timescale and help refine the chronostratigraphic chart that summarises stratigraphic correlations across the Carpentaria, Surat and Eromanga basins of Hannaford et al. (2022). All boreholes were examined outside of the Cooper and Bowen basins boundaries with selected boreholes around transects defined for stratigraphic correlation review through the Cooper and Bowen basin outlines (Norton & Rollet, 2022 and 2023). As a result, most of the remaining unreviewed palynological data lies within the Cooper and Bowen basins. The results of the palynology data infill in the western Eromanga Basin, in South Australia and Northern Territory, show that the Algebuckina Sandstone section is dominated by clean sandstone and so the cuttings samples were also dominated by sand. Although attempts were made to concentrate the shale from the cuttings in the thicker shale mid formation, this did not yield results, due to the amount of caved Cretaceous material. An initial assessment of the Lake Eyre Basin palynological data and zonation scheme was undertaken using information derived from water, mineral and petroleum boreholes. This provides an initial state of knowledge for the Lake Eyre Basin that can be built on in the future. Recommendations are provided for further studies to build a better understanding of the stratigraphy in the Great Artesian and Lake Eyre basins.

Published

2023

30. Trusted Environmental and Geological Information (TEGI) program flyer

Author

S., McAlpine

Subjects

environmental assessments, EARTH SCIENCES, geological basins, Published_External, ENVIRONMENTAL SCIENCES, resource assessments

Abstract

The Trusted Environmental and Geological Information (TEGI) program will provide high-quality data to help governments, industry and communities make informed decisions about prospective basins, leading to improved outcomes for the Australian environment.

Published

2023

31. Australian Mineral Exploration Review 2022

Author

J., Pheeney, H., Colclough, and A., Britt

Subjects

Maiden Resources, Drill Results, Geology, FOS: Earth and related environmental sciences, Exploration, Critical Minerals, Published_External, GA Publication, Mining

Abstract

A review of mineral exploration trends, activities and discoveries in Australia in 2022.

Published

2023

32. Isotopic Atlas of Australia, Lu Hf and O isotope data structure and delivery. Version 1.1

Author

K., Waltenberg, C., Curtis, A., Lem, and S., Bodorkos

Subjects

Lu-Hf isotopes, oxygen isotopes, Isotope Geochemistry, dataset, EFTF – Exploring for the Future, Australia’s Resources Framework, web service, Published_External, database

Abstract

A minor update to Version 1.0: Lu Hf and O isotope data structure and delivery.Isotopic data from rocks and minerals have the potential to yield unique insights into the composition and evolution of the Earth's crust and mantle. Time-integrated records of crust and mantle differentiation (as preserved by the U-Pb, Sm-Nd and Lu-Hf isotopic systems, for example) are important in a wide range of geological applications, especially when successfully integrated with other geological, geophysical, and geochemical datasets. However, such integration requires (i) compilation of comprehensive isotopic data coverages, (ii) unification of datasets in a consistent structure to facilitate inter-comparison, and (iii) easy public accessibility of the compiled and unified datasets in spatial and tabular formats useful and useable by a broad range of industry, government and academic users. This constitutes a considerable challenge, because although a wealth of isotopic information has been collected from the Australian continent over the last 40 years, the published record is fragmentary, and derived from numerous and disparate sources. Unlocking and harnessing the collective value of isotopic datasets will enable more comprehensive and powerful interpretations, and significantly broaden their applicability to Earth evolution studies and mineral exploration.As part of the Exploring for the Future (EFTF) program (https://www.ga.gov.au/eftf), we have designed a new database structure and web service system to store and deliver full Lu-Hf isotope and associated O-isotope datasets, spanning new data collected during research programs conducted by Geoscience Australia (GA), as well as compiled literature data. Our approach emphasises the links between isotopic measurements and their spatial, geological, and data provenance information in order to support the widest possible range of uses. In particular, we build and store comprehensive links to the original sources of isotopic data so that (i) users can easily track down additional context and interpretation of datasets, and (ii) generators of isotopic data are appropriately acknowledged for their contributions.This system delivers complete datasets including (i) full analytical and derived data as published by the original author, (ii) additional, normalised derived data recalculated specifically to maximise inter-comparability of data from disparate sources, (iii) metadata related to the analytical setup, (iv) a broad range of sample information including sampling location, rock type, geological province and stratigraphic unit information, and (v) descriptions of (and links to) source publications. The data is delivered through the Geoscience Australia web portal (www.portal.ga.gov.au), and can also be accessed through any web portal capable of consuming Open Geospatial Consortium (OGC)-compliant web services, or any GIS system capable of consuming Web Map Services (WMS) or Web Feature Services (WFS).Version 1.0 of this Record (Waltenberg et al., 2021) described the database system and web service tables, and featured normalised Lu-Hf data that utilised CHondritic Uniform Reservoir (CHUR) parameters from Blichert-Toft and Albarède (1997). It also presented full tabulated datasets compiled from the North Australian Craton as part of the initial EFTF (2016–2020) program, comprising 5974 individual analyses from 149 unique rock samples. This update (version 1.1) enacts minor changes to some field names within the web services tables to ensure consistency with other web services offered by GA, and for normalised Lu-Hf data, it applies the CHUR parameters of Bouvier et al. (2008) to the entire dataset. The digital datasets presented by Waltenberg et al. (2021) have also been supplemented by more recent analyses collected as part of GA projects in Queensland and New South Wales, in collaboration with the relevant State geological surveys. Version 1.1 does not include an updated tabular data release; the digital dataset available via the web portal now comprises 7630 individual analyses from 180 unique rock samples.

Published

2023

33. Regional stratigraphic correlation transects across the Great Artesian, Lake Eyre basins and Upper Darling Floodplain region (part 2) ‒ Infilling data and knowledge gaps

Author

N., Rollet and C.J., Norton

Subjects

Great Artesian Basin, Borehole log correlation, EARTH SCIENCES, Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy), Stratigraphy, Jurassic, Exploring For The Future (EFTF), Published_External, Cretaceous

Abstract

This report presents a stratigraphic review of some key boreholes across the Jurassic-Cretaceous Eromanga, Surat and Carpentaria basins that form the groundwater Great Artesian Basin (GAB), as well as across the overlying Cenozoic Lake Eyre Basin (LEB), completed during the National Groundwater Systems (NGS) Project. The NGS Project is 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 study presented here builds on previous work (Norton & Rollet, 2022a) undertaken as part of the ‘Assessing the Status of Groundwater in the Great Artesian Basin’ Project, commissioned by the Australian Government through the National Water Infrastructure Fund – Expansion. Although not intended to be a major re-interpretation of existing data, this stratigraphy review updates stratigraphic picks where necessary to obtain a consistent interpretation across the study area, based on the refined geological and hydrostratigraphical framework developed through this project. Problems and inconsistencies in the input data or current interpretations have been highlighted to suggest where further studies or investigations may be useful. This study includes Phase 2 of the National Groundwater Systems Project, which was undertaken by Catherine Jane Norton in collaboration with Geoscience Australia; and compiled, processed and correlated a variety of borehole log data to review the stratigraphy and improve the understanding of distribution and characteristics of Jurassic and Cretaceous sediments across the Eromanga and Surat basins and overlying LEB. To complement the previous 322 key boreholes compiled in Phase 1 (Norton & Rollet, 2022) additional stratigraphic correlations have been made between geological units of similar age (constrained using palynological data) from 706 key boreholes along 35 regional transects across the GAB and from 406 key boreholes along 20 regional transects across the central LEB. Also included in this study is Phase 3 in-fill work of four additional transects, extending the study further south in New South Wales, to tie in to the Cenozoic of the Murray Basin. This later phase 3 of the project also included a review and quality control of approximately 2,572 central LEB boreholes, and the addition of 278 boreholes in the GAB in southern Queensland and New South Wales. Phase 3 also expanded on the results used for mapping regional sand/shale ratios that began in the previous phase (Evans et al., 2020; Norton & Rollet, 2022a). Normalised Gamma Ray (GR) calculations have now been made for 1,778 LEB boreholes and 676 GAB boreholes spanning the entire sequence from the surface, through the Cenozoic and down to the base Jurassic unconformity. The previous phase, mentioned above, concentrated on either just the LEB or the GAB intervals from Cadna-owie Formation to base Jurassic. An additional 17 transects in the LEB and 27 transects in the GAB were created to visualise the lithological variation. The distribution of generalised sand/shale ratios are used to estimate the thickness of sand and shale in different formations, with implications for formation porosity and the hydraulic properties of aquifers and aquitards. This study fills data gaps identified in the previous study (Norton & Rollet, 2022) and refines the regional distribution of lithological heterogeneity in each hydrogeological unit, contributing to an improved understanding of connectivity within and between aquifers. The datasets compiled and examined in this study are in Appendix A. Attempts were made to standardise lithostratigraphic units, which are currently described using varying nomenclature, to produce a single chronostratigraphic chart across the entirety of the GAB and LEB basins. The main stratigraphic correlation infill in the GAB and LEB regions focused on: • The transition between the Eromanga and Surat basins in New South Wales and the tie-in to existing transects in Queensland and South Australia, • The Eromanga Basin in South Australia and Queensland and the tie-in to Phase 1 transects, • The central Eromanga Basin and Frome Embayment areas, extending the GAB units to the overlying Lake Eyre Basin stratigraphy to better assess potential connectivity between these basins, • The transition between the Lake Eyre and Murray Basins in the Upper Darling Floodplain (UDF) area in New South Wales and the tie-in to Phase 1 transects in New South Wales. This report and associated data package provide a data compilation on 706 and 278 key boreholes in the Surat and Eromanga basins respectively, to assist in updating the geological framework for the GAB and LEB. Recommendations are provided for further studies to continue refining the understanding of the stratigraphy in the Great Artesian and Lake Eyre basins.

Published

2023

34. Satellite Selfies Australia from Space Education Poster

Author

T., Sullivan, S., Blewett, K., Buffinton, and C., Krause

Subjects

earth observations, Educational Product, coast, Bushfire, DEA – Digital Earth Australia, EDUCATION, true colour, false colour, Published_External, flood, satellite images, satelite, agriculture

Abstract

The A1 poster incorporates 4 images of Australia taken from space by Earth observing satellites. The accompanying text briefly introduces sensors and the bands within the electromagnetic spectrum. The images include examples of both true and false colour and the diverse range of applications of satellite images such as tracking visible changes to the Earth’s surface like crop growth, bushfires, coastal changes and floods. Scientists, land and emergency managers use satellite images to analyse vegetation, surface water or human activities as well as evaluate natural hazards.

Published

2023

35. Feasibility of underground hydrogen storage with salt caverns in the offshore Polda Basin, South Australia

Author

L., Wang, S., Rees, A.L., Carr, and A.J., Feitz

Subjects

renewable hydrogen, Exploring for the Future, storage capacity, EARTH SCIENCES, halite cavern, halite deposit, Polda Basin, underground hydrogen storage, Kilroo Formation, Published_External

Abstract

Geoscience Australia has conducted a feasibility analysis on underground gas/hydrogen storage (UGS/UHS) through creating salt caverns in the offshore Polda Basin, South Australia. The Mercury structure in the offshore part of the Polda Basin has massive halite deposits in the Neoproterozoic Kilroo Formation at depth intervals of 1376.8–2383.8 mSS (mSS: depth (m) below mean sea level) (salt pillows), 2383.8–2538.8 mSS and 2807.8–3083.8 mSS (salt interbeds). The halite is distributed over 217 km2 approximately 20 km N-S and approximately 20 km E-W, forming an anticlinal structure near Mercury 1 well. Well data (Mercury 1) suggests the total net thickness of halite is up to 1000 m over the lower Kilroo Formation and 468 m above 2000 mSS, which is within the depth range considered suitable for UHS. The potential storage site analysed is located approximately 50-70 km offshore, west of the Eyre Peninsula and approximately 200 km from Port Lincoln. The lower thermal gradient (cold basin) observed, and overburden and formation fracture gradients, are favourable for salt cavern design. The 1376.8–1539.8 mSS and 1575.6–2367.6 mSS halite intervals in Mercury 1 were identified as potential candidates for cavern creation in the future UHS program. A conceptual design of a halite cavern is presented for the depth range of 1650–2000 mSS. The cylindrical halite cavern is evaluated for two diameters (60 m and 100 m) with the calculated hydrogen storage capacity of approximately 240 GWh and 665 GWh (equivalent to approximately 7200 and 20000 tonnes), respectively. Potentially multiple halite caverns could be built within the thick halite deposits of the Mercury structure. Compared to one of Australia’s non-hydrocarbon energy storage resources currently under construction (Snowy 2.0 hydropower) at 350 GWh, UHS within a halite cavern in the offshore Polda Basin provides an alternative for large-scale energy storage that is potentially quicker to build, has less environmental footprints and is not impacted by drought.

Published

2023

36. Mesoproterozoic basins of Australia

Author

J., Anderson, L., Carr, and C., Carson

Subjects

basin, Mesoproterozoic, EFTF - Exploring for the Future, review, Australia, GEOLOGY, Published_External

Abstract

The preserved successions from the Mesoproterozoic Era (1600 to 1000 Ma) are a relatively understudied part of Australian geological evolution, especially considering that this era has a greater time span than the entire Phanerozoic. These rocks are mostly known in variably-preserved sedimentary basins overlying Paleoproterozoic or Archean cratons or at the margins of these cratons. Some metamorphosed equivalents occur within the orogens between or marginal to these cratons. Both energy and mineral resources are hosted in Australian Mesoproterozoic basins, including the highly-prospective organic rich shale units within the Beetaloo Sub-basin (Northern Territory), which form part of the Beetaloo Petroleum Supersystem. The primary aim for this record is to provide a consolidated state of knowledge of Australian basins or successions similar in age to that of the Mesoproterozoic Beetaloo Petroleum Supersystem. The findings of this report will assist prioritising future work, through improved geological understanding and resource prospectivity. This report presents an overview of 14 Mesoproterozoic-age sedimentary basins or successions and their current level of understanding, including location, basin architecture, stratigraphy and depositional environments, age constraints and mineral and energy resources. Basins or successions included in this record are unmetamorphosed or metamorphosed to very low-grade conditions. Recommendations are made for future work to address the main knowledge gaps identified from this review. While some of these basins have been the focus of recent intense study and data acquisition, the extent of knowledge varies broadly across basins. All basins reviewed in this record would benefit from further geochemical and geochronological analyses, and stratigraphic study to better understand the timing of depositional events and their correlation with nearby basins. Elucidation of the post-depositional history of alteration, migration of fluids and/or hydrocarbons would facilitate future exploration and resource evaluation.

Published

2023

37. A preliminary 3D model of the Boree Salt in the Adavale Basin, Queensland

Author

S., Rees, R., Paterson, A., Feitz, L., Wang, and J., Keetley

Subjects

INFORMATION AND COMPUTING SCIENCES, Adavale Basin, EARTH SCIENCES, Australia's Future Energy Resources, Salt, Exploring For The Future, Published_External, EFTF

Abstract

All commercially produced hydrogen worldwide is presently stored in salt caverns. In eastern Australia, the only known thick salt accumulations are found in the Boree Salt of the Adavale Basin in central Queensland. Although the number of wells penetrating the basin is limited, salt intervals up to 555 m thick have been encountered. The Boree Salt consists predominantly of halite and is considered to be suitable for hydrogen storage. Using well data and historical 2D seismic interpretations, we have developed a 3D model of the Adavale Basin, particularly focussing on the thicker sections of the Boree Salt. Most of the salt appears to be present at depths greater than 2000 m, but shallower sections are found in the main salt body adjacent to the Warrego Fault and to the south at the Dartmouth Dome. The preliminary 3D model developed for this study has identified three main salt bodies that may be suitable for salt cavern construction and hydrogen storage. These are the only known large salt bodies in eastern Australia and therefore represent potentially strategic assets for underground hydrogen storage. There are still many unknowns, with further work and data acquisition required to fully assess the suitability of these salt bodies for hydrogen storage. Recommendations for future work are provided. Citation: Paterson R., Feitz A. J., Wang L., Rees S. & Keetley J., 2022. From A preliminary 3D model of the Boree Salt in the Adavale Basin, Queensland. In: Czarnota, K. (ed.) Exploring for the Future: Extended Abstracts, Geoscience Australia, Canberra, https://dx.doi.org/10.26186/146935

Published

2022

38. AusSeabed Strategy

Author

K., Baldry and AusSeabed Steering Committee

Subjects

AusSeabed, Seabed mapping, Published_External, Marine Geoscience

Abstract

The AusSeabed Strategy aims to set a framework for the Program to operate. It defines the Programs vision, mission, role, outcomes and program goals. It will be revised every 3 years in-line with the rotation of the AusSeabed Steering Committee.

Published

2022

39. Exploring for the Future program Showcase 2022 - Day 2 Data, toolbox and geology sessions

Author

M., Costelloe, L., Gow, A., Ray, M., Webster, M., Bonnardot, H., Carey, A., Schofield, C., Carson, and M., Haynes

Subjects

EARTH SCIENCES, Published_External, ENVIRONMENTAL SCIENCES

Abstract

The Exploring for the Future program Showcase 2022 was held on 8-10 August 2022. Day 2 (9th August) included talks on two themes moderated by Marina Costelloe. Data and toolbox theme: - Data acquisition progress - Dr Laura Gow - Quantitative tool development: HiQGA.jl and HiPerSeis - Dr Anandaroop Ray - Data delivery advances: Underpinned by careful data curation - Mark Webster Geology theme: - Mapping Australia's geology: From the surface down to great depths - Dr Marie-Aude Bonnardot - Towards a national understanding of Groundwater - Dr Hashim Carey - Uncovering buried frontiers: Tennant Creek to Mount Isa - Anthony Schofield and Dr Chris Carson - Lithospheric characterisation: Mapping the depths of the Australian tectonic plate - Dr Marcus Haynes You can access the recording of the talks from YouTube here: [will be inserted when available]

Published

2022

40. Unravelling the pre-1860–1850 Ma ‘basement’ history of the Mount Isa Inlier

Author

C., Lewis, R.J., Bultitude, L.J., Hutton, K., Waltenberg, R.A., Armstrong, and N., Evans

Subjects

Kalkadoon, metamorphic, Kurbayia Metamorphic Complex, geochronology, Lu-Hf Isotopes, U-Pb, zircon, Mount Isa, O Isotopes, magmatic, Leichhardt, Age, Kalkadoon Supersuite, titanite, Radiometric Age, U-Pb Dating, Published_External, isotopes

Abstract

The Kalkadoon-Leichhardt Domain of the Mount Isa Inlier has been interpreted to represent the ‘basement’ of the larger inlier, onto which many of the younger, economically prospective sedimentary and volcanic units were deposited. The domain itself is dominated by 1860–1850 Ma granitic to volcanic Kalkadoon Supersuite rocks, but these units are interpreted to have been emplaced/erupted onto older units of the Kurbayia Metamorphic Complex. This study aims to provide insights into a number of geological questions: 1. What is the isotopic character of the pre-1860–1850 Ma rocks? 2. How do these vary laterally within the Kalkadoon-Leichhardt Domain? 3. What is the tectonic/stratigraphic relationship between the 1860–1850 Ma rocks of the Mount Isa Inlier and c. 1850 Ma rocks of the Tennant Creek region and Greater McArthur Basin basement? Detrital zircon U–Pb results indicate the presence of 2500 Ma detritus within the Kurbayia Metamorphic Complex, suggesting that the Kalkadoon-Leichhardt Domain was a sedimentary depocentre in the Paleoproterozoic and potentially had sources such as the Pine Creek Orogen, or, as some authors suggest, potential sources from cratons in northern North America. Existing Hf and Nd-isotopic data suggest that the ‘basement’ units of the Mount Isa Inlier have early Proterozoic model ages (TDM) of 2500–2000 Ma. Oxygen and Hf-isotopic studies on samples from this study will allow us to test these models, and provide further insights into the character and history of these ‘basement’ rocks within the Mount Isa Inlier, and northern Australia more broadly.

Published

2022

41. New U–Pb SHRIMP geochronology from NDI Carrara 1: implications for regional geological evolution and stratigraphic correlations

Author

C., Carson, N., Kositcin, P.A., Henson, C., Delle Piane, V., Crombez, E., Grosjean, A.J.M., Jarrett, and G., Butcher

Subjects

Exploring for the Future, Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy), EARTH SCIENCES, Geochronology, chronostratigraphy, Carrara Sub-basin, NDI Carrara 1, Published_External, Barkly Tablelands, Paleoproterozoic, SHRIMP Zircon geochronology, South Nicholson NDI module

Abstract

To test existing geological interpretations and the regional stratigraphic relationships of the Carrara Sub-basin with adjacent resource-rich provinces, the deep stratigraphic drill hole NDI Carrara 1 was located on the western flanks of the Carrara Sub-basin, on the seismic line 17GA-SN1. The recovery of high quality near-continuous core from the Carrara Sub-basin, in concert with the spectrum of baseline analytical work being conducted by Geoscience Australia through the EFTF program, as well as other work by government and university researchers is greatly improving our understanding of this new basin. While recently published geochemistry baseline datasets have provided valuable insight into the Carrara Sub-basin, the age of the sedimentary rocks intersected by NDI Carrara 1 and their chronostratigraphic relationships with adjacent resource rich regions has remained an outstanding question. In this contribution, we present new sensitive high-resolution ion microprobe (SHRIMP) geochronology results from NDI Carrara 1 and establish regional stratigraphic correlations to better understand the energy and base-metal resource potential of this exciting frontier basin in northern Australia.

Published

2022

42. AusSeabed Annual Highlights Report 2021/22

Author

K., Baldry and AusSeabed Program

Subjects

AusSeabed, Published_External, Marine Geoscience, Seabed Mapping, Annual Report

Abstract

Established in 2018, AusSeabed is a collaborative national seabed mapping initiative focused on delivering freely accessible seabed mapping data and coordinating efforts to map the gaps across the Australian maritime region of responsibility. AusSeabed is driven by a cross-sector steering committee bringing together organisations from the government, academia and private sectors to ensure an inclusive and diverse representation of the seabed mapping community. The Annual Highlights Report presents the key achievements of the AusSeabed program over the 2021/22 financial year. The report is structured in five sections, the first four are aligned to the 2021/22 work plan objectives and the fifth highlights engagement activities over the past year.

Published

2022

43. From Australian iron ore to green steel: the opportunity for technology-driven decarbonisation

Author

M., Haynes, C., Wang, S.D.C., Walsh, Z., Weng, A., Feitz, D., Summerfield, and I., Lutalo

Subjects

Exploring for the Future, ECONOMICS, CHEMICAL SCIENCES, EARTH SCIENCES, Economic Fairways, Iron ore, Green steel, ENGINEERING, Published_External, Australia's Resources Framework, EFTF, Hydrogen

Abstract

Australian iron ore is predominantly exported and used for steelmaking internationally. However, steelmaking is an energy- and carbon-intensive heavy industry, and its electrification in the coming decades will likely disrupt the existing iron ore–steel value chains. Green steel—produced using hydrogen and electricity from renewable energy sources—presents both opportunities and challenges for Australia. Indeed, with abundant renewable energy potential and iron-ore resources, Australia could lead this global transformation. Here, we examine the interrelationships between the Australian iron-ore industry, the production of green-hydrogen from renewable energy sources, and an emergent green steelmaking process. In particular, we undertake detailed case studies to estimate current green steel production costs within two regions; the Pilbara Craton in Western Australia and the Eyre Peninsula in South Australia. While existing technology is not well suited to Australian hematite ores, our analysis highlights the site-specific competitiveness of small-scale, magnetite-fed, off-grid operations. The results underscore the advantages of a well-optimised system in decreasing hydrogen and energy storage requirements, and decreasing production costs. While our results also suggest that grid-connected projects could reduce costs through flexible operation, more work is required to understand the limitations of these conclusions. The results underscore the need to develop technologies to utilise hematite ores in green steelmaking, but also highlight the opportunity for this emerging industry to commercialise Australia’s magnetite resources. Citation: Wang C., Walsh S. D. C., Haynes M. W., Weng Z., Feitz A., Summerfield D., & Lutalo I., 2022. From Australian iron ore to green steel: the opportunity for technology-driven decarbonisation. In: Czarnota, K. (ed.) Exploring for the Future: Extended Abstracts, Geoscience Australia, Canberra, https://dx.doi.org/10.26186/147005

Published

2022

44. Neoproterozoic and Cambrian chemostratigraphic mega-sequences of the Officer Basin; a regional framework to assist petroleum and mineral exploration

Author

D., Edwards, S., Munday, L., Wang, D., Riley, and K., Khider

Subjects

Exploring for the Future, carbon isotopes, EARTH SCIENCES, Officer Basin, Officer-Musgrave, chemostratigraphy, Published_External, GEOCHEMISTRY, EFTF

Abstract

Well and seismic correlation schemes exist for the Western Australian and South Australian parts of the Officer Basin but there are inconsistencies between the western and eastern regions. Hence, as part of the Exploring for the Future Officer-Musgrave Project, a chemostratigraphic correlation has been determined for the sedimentary fill of the Officer Basin with emphasis on Neoproterozoic to Cambrian rocks. The correlations have been developed on whole rock inorganic geochemical data obtained from the analysis of 10 study wells which span the basin from Western Australia and into South Australia. A total of 8 chemostratigraphic mega-sequences (MS) are recognised across the basin, that in turn are subdivided into a total of 24 chemostratigraphic sequences. MS1 to MS6 include the Neoproterozoic to Cambrian sedimentary rocks and are the focus of this study. The Neoproterozoic–Cambrian mega-sequences MS1 to MS4 broadly correspond to the previously defined Centralian supersequences CS1 to CS4 and provide robust well-control to the regional seismic correlations. Confidence in the correlation of these old rocks are important since they contain both potential source and reservoir rocks for petroleum generation and accumulation. MS7 is equivalent to the Permian Paterson Formation, while MS8 is equivalent to the Mesozoic section. The elemental data has also been used to elucidate aspects of the petroleum system by characterising reservoirs and identifying fine-grained siliciclastics deposited in anoxic environments which may have source potential. This work is expected to further improve geological knowledge and reduce the energy exploration risk of the Officer Basin, a key focus of this program. Citation: Edwards D.S., Munday S., Wang L., Riley D. & Khider K., 2022. Neoproterozoic and Cambrian chemostratigraphic mega-sequences of the Officer Basin; a regional framework to assist petroleum and mineral exploration. In: Czarnota, K. (ed.) Exploring for the Future: Extended Abstracts, Geoscience Australia, Canberra, https://dx.doi.org/10.26186/146285

Published

2022

45. Exploring for the Future in the Officer Musgrave region

Author

L., Carr, L.K., Carr, P., Henson, L., Wang, A., Bailey, T., Fomin, C., Boreham, D., Edwards, C., Southby, N., Symington, M., Smith, L., Halas, and T., Jones

Subjects

EARTH SCIENCES, Officer-Musgrave, Exploring For The Future, Published_External, EFTF

Abstract

To unlock the potential of one of the largest underexplored onshore areas in Australia, the Exploring for the Future Officer-Musgrave project is delivering a wide array of publicly available new analyses and data. The collection of new AEM data, as well as the reprocessing of existing industry acquired AEM data is expected to improve the understanding of groundwater systems in the Officer-Musgrave region. New regional scale data acquisition and analysis, including stratigraphic, petrophysical and geomechanical studies from existing wells, focus on advancing understanding of petroleum systems elements and assist the exploration and evaluation of conventional and unconventional petroleum resources. Here we provide an overview of available new datasets and insights into the stratigraphy of the Officer Basin. Further analysis is underway including well log digitisation, fluid inclusion analysis and a petrographic report on Officer Basin wells. This work is expected to further improve geological knowledge and reduce the energy exploration risk of the Officer Basin, a key focus of this program. Citation: Carr L. K., Henson P., Wang L., Bailey A., Fomin T., Boreham C., Edwards D., Southby C., Symington N., Smith M., Halas L. & Jones T, 2022. Exploring for the Future in the Officer Musgrave region. In: Czarnota, K. (ed.) Exploring for the Future: Extended Abstracts, Geoscience Australia, Canberra, https://dx.doi.org/10.26186/146988

Published

2022

46. Wind retrofit for older masonry buildings

Author

M., Wehner and M., Edwards

Subjects

EARTH SCIENCES, Unreinforced masonry, Severe wind, Published_External, Retrofit

Abstract

This document is aimed to be a resource for you when discussing retrofit needs and options with clients and translating their retrofit objectives to detailed design, documentation and implementation. The primary focus is the most vulnerable building construction type in Australia, older unreinforced masonry, but the principles are also informative to address other high risk building types. The objective is cost-effective retrofit measures with minimised disruption to occupants that can address a significant portion of the earthquake risk to the building owner and the community more broadly. It presents information that explains the nature of wind hazard in Western Australia, the risk it presents and the vulnerability factors that contribute to it. It further describes the common failure modes that can be highlighted to clients and a range of measures that can be employed to preclude these. It also links to other resources that can be drawn upon in developing tailored design solutions that the construction industry can readily implement.

Published

2022

47. How Post-Earthquake Rapid Deployment Kits (RDKs) Work

Author

L., Soroka

Subjects

Land Access, Earthquake, Geoscience Knowledge Sharing, RDK, Field Activity, EARTH SCIENCES, Community Safety, EDUCATION, Published_External, Stakeholder Engagement, Land Access Stakeholder Engagement

Abstract

This animation shows what happens when rapid deployment kits (RDKs) are deployed after an earthquake. It is part of a series of Field Activity Technique Engagement Animations. The target audience are the communities that are impacted by GA's data acquisition activities. There is no sound or voice over. The 2D animation includes a simplified view of what rapid deployment kits (RDKs) look like, what is measured, and how scientists use the data.

Published

2022

48. InSAR processing over the Great Artesian Basin and analysis over the western Eromanga Basin and northern Surat Basin

Author

J., McCubbine, Z., Du, C., Ojha, M., Garthwaite, and N., Brown

Subjects

InSAR, Great Artesian Basin, Eromanga Basin, Surat Basin, EARTH SCIENCES, groundwater, Published_External

Abstract

This Geoscience Australia Record reports on Interferometric Synthetic Aperture Radar (InSAR) processing over the Great Artesian Basin (GAB) to support an improved understanding of the groundwater system and water balance across the region. InSAR is a geodetic technique that can identify ground surface movement from satellite data at a regional scale and is therefore a valuable and widely used technique for measuring patterns in surface movement over time; including the movement of fluids (i.e. water or gas) beneath the surface.This Record is the one of two Geoscience Australia Records that describe ground surface movement monitoring Geoscience Australia have undertaken in the GAB in recent years. Namely;1. Ground surface movement in the northern Surat Basin derived from campaign GPS measurements. (Garthwaite et al., 2022).2. InSAR processing over the Great Artesian Basin and analysis over the western Eromanga Basin and northern Surat Basin (this Record).We have produced ground surface motion data products, which cover about 90% of the GAB for the period of time between January 2016 and August 2020. The data products were created using Sentinel-1 Synthetic Aperture Radar (SAR) data and an InSAR processing workflow designed for large spatial scale processing. The large spatial scale InSAR processing workflow includes using GAMMA software to (i) pre-process SAR images to align the pixels, (ii) generate interferograms and short temporal baseline surface displacement maps and PyRate software to (iii) combine these outputs in an inversion to form pixel-wise time series ground surface displacement data and fit ground surface velocities to the displacement data. The raw SAR data and these subsequent data products of the workflow are partitioned into overlapping frames; the final stage of the large scale processing workflow is to combine the partitioned data into a single map using a mosaicking algorithm. The results of this processing chain demonstrate the feasibility of developing a regional scale ground surface movement reconnaissance tool (i.e. subsidence and uplift). We provide a summary of the processing chain and data products and a focused assessment for two case study areas in the western Eromanga Basin (South Australia) and northern Surat Basin (Queensland). Over these case study areas we examine the relationship between the InSAR derived ground surface movement and available groundwater level data. We also assess how land use types may influence the InSAR derived ground surface motion data by comparing the InSAR data to the “land types” over the region which we classify using a machine learning algorithm with Sentinel-2 optical imagery data. From our analysis we observe little ground surface motion over the western Eromanga Basin. The surface movement rate over the entire area is estimated to be mostly within ±10 mm/yr. Groundwater level time series data from well monitoring sites in the area did not appear to have any significant trends either. However, large and broad scale ground surface motion (both uplift and subsidence) was observed in the InSAR processing results over the northern Surat Basin. A 75 km x 150 km scale uplift signal, with rates of up to 20 mm/yr, was located over an area we classified as cultivated land, where InSAR signals are likely to be influenced by near-surface cultivation activities (such as irrigation) rather than subsurface groundwater level changes. Furthermore, two approximately 75km x 75 km areas were identified which had subsidence signals of up to -20 mm/yr. Over the same area, groundwater level time series data show long-term negative trends in the water head level. For a more direct comparison between the InSAR results and the well data, we fitted a first order poroelastic model to transform the InSAR derived ground surface motion rates into modelled pore-pressure decline/groundwater drawdown rates. We compared the model to the groundwater time series data in the Walloon Coal Measures, Surat Basin, and found good agreement, which indicates that the observed subsidence signals could be attributable to pore-pressure decline due to the falling water head level.We finally provide some preliminary analysis comparing our InSAR results to the results from an Office of Groundwater Impact Assessment (OGIA) InSAR study and a Geoscience Australia GPS land movement study to assist in validating the Geoscience Australia InSAR results. Overall, the comparisons are encouraging, showing a high correlation against the OGIA InSAR results and GPS results. Further work, is required to further validate our results and reduce uncertainty in our analysis process.

Published

2022

49. Exploring for the Future AEM workshop: Perth, 2022

Author

A., Ray, K., Czarnota, K., Gessner, Y., LeyCooper, S., Wong, and N., Symington

Subjects

inverse theory, EFTF - Exploring for the Future, AEM Acquisition, AEM Interpretation, Electrical and Electromagnetic Methods in Geophysics, GEOLOGY, GEOPHYSICS, Basin Analysis, Integrating geophysics and geology, Published_External, HiQGA.jl, Airborne Electromagnetics - AEM

Abstract

As part of the Exploring For the Future program 2022 showcase, Geoscience Australia (GA) in collaboration with the Australian Institute of Geoscientists held an Airborne Electromagnetics (AEM) workshop in Perth on 11th August 2022. The workshop comprised the following: - An introduction to GA's 20 km spaced continent-wide AusAEM program, by Karol Czarnota - How the Western Australia government has successfully used 20 km spaced AEM data, by Klaus Gessner - An introduction to AEM, surveying, and quality control given by Yusen Ley-Cooper - An introduction to inverse theory presented by Anandaroop Ray - Hands-on AEM modeling and inversion using HiQGA.jl by Anandaroop Ray - Integrating geophysics and geology in subsurface interpretation, by Sebastian Wong - Avoiding the 10 most common pitfalls in AEM interpretation according to Neil Symington YoutTube video from the workshop, as well as data and code to follow along with the videos can be found on GA's GitHub at this link.

Published

2022

50. Exploring for the Future program Showcase 2022 - Day 3 Minerals, Energy and Groundwater Systems and Resource Potential sessions

Author

K., Czarnota, D., Robinson, S., Buckerfield, L., Carr, D., Huston, A., Ford, A., Kalinowski, and A., Feitz

Subjects

EARTH SCIENCES, Showcase, Exploring For The Future, Published_External, EFTF

Abstract

The Exploring for the Future program Showcase 2022 was held online on 8-10 August 2022. Day 3 (10th August) included talks on two themes moderated by David Robinson. Minerals, energy and groundwater systems theme: - Upper Darling Floodplain - Dr Sarah Buckerfield - Geoscience insights from Energy Resources - Lidena Carr - Mineral systems insights: New concepts from old data - Dr David Huston Resource potential theme: - Mineral Potential: Narrowing the exploration search space - Dr Arianne Ford - CO2-Enhanced oil recovery: Application to residual oil zones - Dr Aleks Kalinowski - Hydrogen and green steel - Dr Andrew Feitz You can access the recording of the talks from YouTube here: [link will be inserted when available]

Published

2022