<div>A PowerPoint presentation given by Chief of Minerals, Energy and Groundwater Division Dr Andrew Heap at NT Resources Week 2023. </div><div><br></div><div>This presentation had the theme of 'Precompetitive geoscience - Uncovering our critical minerals potential.'</div>

<diThe Permian and Triassic Pedirka and Simpson basins in central Australia have proven petroleum potential with a non-commercial oil discovery in the Poolowanna Trough and several wells showing evidence for residual oil columns. However, these basins remain underexplored with only 42 wells drilled and relatively sparse 2D seismic coverage. Consequently, our knowledge of the structural and stratigraphic framework of the basins continues to grow as new data sets are acquired. Understanding the area’s resource potential continues to improve as new insights are gained into the presence and effectiveness of the main risk elements (reservoir, seal, hydrocarbon charge and trapping mechanisms) associated with a variety of sub-surface resources. Geoscience Australia, the Northern Territory Geological Survey, and the South Australian Department of Energy and Mining are collaborating on the Australia’s Future Energy Resources project under the Exploring for the Future program. One of the aims of this collaborative project is to assess the resource potential for conventional and unconventional hydrocarbons and carbon capture and storage (CCS) resources in the Pedirka, Simpson and western Eromanga basins. A play-based exploration approach is being used to systematically evaluate the key risk elements for each regional reservoir-seal interval (i.e. (play intervals) through the analysis of drilling results and spatial data to map sweet spots. These assessments aim to reduce exploration uncertainties by providing spatially-enabled assessments of the energy resources and CCS potential of the region. A key requirement for undertaking play-based resource assessments is to develop a chronostratigraphic geological framework that defines the main regional play intervals. Regional play schemes have been developed and applied over several decades for petroleum explorers in Western Australia, but have not yet become readily available for explorers in central and eastern Australian onshore basins. This paper presents a chronostratigraphic play scheme that is being applied to resource assessments in the Pedirka and Simpson basins. The scheme includes two Triassic play intervals correlating to the Peera Peera and Walkandi formations, and three Permian play intervals correlating to the Purni Formation and the Crown Point Formation. This Abstract was submitted/presented to the 2022 Central Australian Basins Symposium IV (CABS) 29-30 August (https://agentur.eventsair.com/cabsiv/)

<div>A keynote talk talk given at Uncover Curnamona 2022 by Angela O'Rourke outlining the rationale, work program and new data acquisition for Geoscience Australia's Darling-Curnamona-Delamerian Project within Exploring for the Future</div> This presentation was given to the 2022 Uncover Curnamona 2022 Conference 31 May - 2 June:<br>(https://www.gsa.org.au/common/Uploaded%20files/Events/Uncover%20Curnamona%202021/UC2022_short_program_A4_web%20(003).pdf)

NDI Carrara 1 is the first stratigraphic test of the Carrara Sub-basin, a newly discovered depocentre in the South Nicholson region that was identified on newly acquired seismic surveys undertaken as part of the Exploring for the Future program. NDI Carrara 1 intersected a thick sequence of Proterozoic aged siliciclastic and carbonate rocks, which host several intervals of interest to hydrocarbon explorers due to affinities with the known Proterozoic shale gas plays of the Beetaloo Sub-basin and the Lawn Hill Platform. These include two organic-rich black shale sequences and a thick sequence of interbedded black shales and silty-sandstones where numerous hydrocarbon shows are demonstrated. An extensive suite of wireline logs was acquired from total depth to the near surface, and continuous core was recovered through the Proterozoic interval. Geoscience Australia and partners are undertaking an extensive program of analytical work to understand the depositional, structural, and diagenetic history of the sediments intersected by NDI Carrara 1, alongside their resource potential. This study characterises petrophysical and geomechanical properties of the Proterozoic interval of NDI Carrara 1 through interpretation of wireline logging data and integration of some of this interpretation with results of geochemical analyses. High interpreted TOC content and a high calculated net shale ratio, alongside high estimated hydrocarbon saturations suggest a high potential for unconventional gas resources in the Proterozoic shale intervals of the Carrara Sub-basin; an assessment supported by gas peaks, particularly methane, measured in mud-logging gas profiles during drilling. Shale brittleness indices and interpreted present-day stresses highlight areas that are likely to be favourable for unconventional gas techniques and which may form attractive shale gas plays. Interpretation of the L210 and L212 seismic surveys suggests that the intersected sequences are laterally extensive and continuous throughout the Carrara Sub-basin, potentially forming a significant new hydrocarbon province and continuing the Proterozoic shale play fairway across the Northern Territory and northwest Queensland. This Abstract was submitted/presented to the 2022 Central Australian Basins Symposium IV (CABS) 29-30 August (https://agentur.eventsair.com/cabsiv/)

<div>The mineral potential toolkit (aka minpot-toolkit) provides tools to facilitate mineral potential analysis, from spatial associations to feature engineering and fully integrated mineral potential mapping.</div>

<div>The study utilised Geoscience Australia’s vast data collection of mineral occurrences to identify the range of historical discoveries within the Officer-Musgrave, Darling-Curnamona - Delameian and Barkly - Isa - Georgetown Deep Dive areas. A literature review shed light on exploration discovery methods, commodity grades, exploration histories and deposit types. Many critical mineral occurrences were overlooked or ignored in the past, as the commodity discovered was not of interest or value at the time, or grades were regarded as sub-economic. However, with modern methods of mining, ore treatment techniques and increased demand, reassessment could now provide new opportunities.</div>

<div>The resources industry is a key driver of Australia’s economic prosperity. The resources industry – which includes mining, oil and gas and exploration and mining services – accounted for 18 per cent of Australia’s gross domestic product (GDP) and employed 200,000 people in 2021–22 (Australian Bureau of Statistics, 2023a). This success is driven by a significant resource endowment, a skilled labour force, substantial capital investment, and the availability of world class precompetitive geoscience data and analysis that supports the resources industry in discovering and extracting resources. &nbsp;</div><div>Precompetitive geoscience data and analysis refers to geological, geophysical, geochemical, and other types of data collected by government agencies. This data is made freely available to all as a public good and provides a foundational understanding of a region’s resource potential before exploration and extraction activities take place. &nbsp;</div><div>Precompetitive geoscience data and analysis plays an important role in supporting resource exploration. Industry surveys conducted by GA suggest that precompetitive geoscience data and analysis is used by over 80 per cent of companies operating in the non-ferrous metals extraction industry and oil and gas extraction industry. The data and analysis help companies to identify highly prospective areas, thereby reducing costs and risks to industry. This stimulates exploration tenement uptake and exploration activity in the most prospective regions, which is required for the discovery and extraction of resources from greenfield sites and expanded brownfield sites. &nbsp;</div><div>Mineral exploration would be significantly more expensive and carry a higher risk in the absence of precompetitive geoscience data and analysis. This would likely decrease the amount of exploration occurring in Australia, as the expected return on exploration would be lower than could be gained elsewhere. A decline in exploration would lead to a subsequent decline in the rate of resource discovery. Over the long-term, this would lead to a reduction in resource extraction at greenfield sites (and to a lesser extent, at brownfield sites) in Australia. Through this relationship, the initial provision of precompetitive data underpins a significant amount of value within the Australian economy, which is easily overlooked. &nbsp;</div><div>It is in this context that Deloitte Access&nbsp;Economics was engaged by GA to estimate the economic contribution of precompetitive geoscience data and analysis in 2021–22. GA is the national public sector geoscience organisation and is primarily responsible for generating and curating Australia’s precompetitive geoscience data and analysis, along with state and territory geological surveys and various research initiatives. &nbsp;</div><div>Precompetitive geoscience data&nbsp;and analysis&nbsp;production: The analysis reveals that Australia’s precompetitive geoscience data and analysis producers had a direct economic contribution of $71 million in value added and supported 432 FTE jobs in 2021–22. &nbsp;</div><div>This value added is derived from wages and salaries paid to employees in the data production process, representing close to half of the total expenditure on data production ($151 million). GA is the largest producer of precompetitive geoscience data and analysis in Australia and therefore had the highest value added among data producers. This is driven in large part through activities conducted as part of GA’s Exploring for the Future program. &nbsp;</div><div>Precompetitive geoscience data&nbsp;and analysis use: Survey data by GA indicates that precompetitive geoscience data and analysis is used widely for resource exploration and extraction,&nbsp;particularly for the discovery of nonferrous metal ores and oil and gas.&nbsp;</div><div>&nbsp;Precompetitive geoscience data and analysis allows resource companies to make more targeted&nbsp;investment decisions and deploy their labour more efficiently, resulting in cost&nbsp;savings. &nbsp;</div><div>The direct economic contribution of precompetitive geoscience data and analysis use in 2021–22 consists of: &nbsp;</div><div>• $5.5 billion direct value added and 24,361 FTE jobs supported by the use of precompetitive geoscience data and analysis in exploration and mining support services &nbsp;</div><div>• $24.0 billion direct value added and 34,244 FTE jobs supported by the use of precompetitive geoscience data and analysis for non-ferrous metal ore&nbsp;extraction &nbsp;</div><div>• $46.5 billion direct value added and 21,305 FTE jobs supported by the use of precompetitive geoscience data and analysis for oil and gas extraction &nbsp;</div><div>These estimates are considered conservative. </div><div><br></div><div><br></div>

<div>The Roebuck Basin on Australia’s offshore north-western margin is the focus of regional energy exploration activity. Drilling in the Roebuck Basin resulted in oil and gas discoveries at Phoenix South&nbsp;1 (2014), Roc&nbsp;1 (2015–2016) and Dorado&nbsp;1 (2018) in the Bedout Sub-basin (Figure 1‑2) and demonstrated the presence of a petroleum system in Lower Triassic strata. These discoveries have been evaluated for development and production with infill drilling at Roc&nbsp;2 (2016), Phoenix South&nbsp;2 (2016), Phoenix South&nbsp;3 (2018), Dorado&nbsp;2 (2019), and Dorado&nbsp;3 (2019). Recent drilling by Santos (2022) has resulted in the discovery of oil at Pavo&nbsp;1 (2022) and hydrocarbon shows at Apus&nbsp;1 (2022).</div><div><br></div><div>To complement this industry work, Geoscience Australia’s Offshore Energy Systems program produces pre-competitive information to assist with the evaluation of the energy and resource potential of the central North West Shelf, including both hydrogen and helium resources, and to attract exploration investment to Australia. As part of this program, determination of the molecular and noble gas isotopic composition of natural gases from selected petroleum wells in the Roebuck Basin were undertaken by Smart Gas Sciences, under contract to Geoscience Australia, with results from these analyses being released in this report. This report provides additional gas data to determine the sources of natural gases in the Roebuck Basin and build on previously established gas-gas correlations. Noble gas isotopic data can be used in conjunction with carbon and hydrogen isotopic data to determine the origin of both inorganic and organic (hydrocarbon) gases. This information can be used in future geological programs to determine the source and distribution of hydrogen and helium in natural gases and support acreage releases by the Australian Government.</div><div><br></div>

<div>The Carpentaria Basin is a Mesozoic basin located in the northernmost part of Australia and is centered around the Gulf of Carpentaria . It forms part of the Great Australian Superbasin that includes the Eromanga, Surat, Nambour and Clarence-Morton basins to the south, the Laura Basin, to the east, and the Papuan Basin to the north. In a west-east direction it extends for about 1250 km from the area of Katherine in the Northern Territory to the Great Dividing Range in Queensland. A small portion of the basin reaches the east coast of Queensland in the Olive River region. In a north-south direction it extends for over 1000 km from Cape York to Cloncurry, in Queensland. The basin has a total area of over 750,000 km2, comparable in size to the state of New South Wales. From a geographic standpoint the sediments of the Carpentaria Basin occur in three areas: offshore below the Gulf of Carpentaria, onshore to the west in the Northern Territory, and onshore to the east in Queensland. This report focuses on the geology and energy resource potential of the onshore areas of the basin but, to provide a broader understanding of the basin evolution there is, of necessity, some discussion of the geology offshore.</div><div><br></div>

<div>NDI Carrara 1 is a 1750 m stratigraphic drill hole completed in 2020 as part of the MinEx CRC National Drilling Initiative (NDI) in collaboration with Geoscience Australia under the Exploring for the Future program and the Northern Territory Geological Survey. It is the first stratigraphic test of the Carrara Sub-basin, a recently discovered depocentre in the South Nicholson region. The drill hole intersected Cambrian and Proterozoic sediments consisting of organic-rich black shales and a thick sequence of interbedded black shales and silty sandstones with hydrocarbon shows. A comprehensive analytical program carried out by Geoscience Australia on the recovered core samples from 283 m to total depth at 1751&nbsp;m provides critical data for calibration of burial and thermal history modelling.</div><div>Using data from this drilling campaign, burial and thermal history modelling was undertaken to provide an estimate of the time-temperature maxima that the sub-basin has experienced, contributing to an understanding of hydrocarbon maturity. Proxy kerogen kinetics are assessed to estimate the petroleum prospectivity of the sub-basin and attempt to understand the timing and nature of hydrocarbon generation. Combined, these newly modelled data provide insights into the resource potential of this frontier Proterozoic hydrocarbon province, delivering foundational data to support explorers across the eastern Northern Territory and northwest Queensland.</div> <b>Citation:</b> Palu Tehani J., Grosjean Emmanuelle, Wang Liuqi, Boreham Christopher J., Bailey Adam H. E. (2023) Thermal history of the Carrara Sub-basin: insights from modelling of the NDI Carrara 1 drill hole. <i>The APPEA Journal</i><b> 63</b>, S263-S268. https://doi.org/10.1071/AJ22048