Use of exploration methods to repurpose and extend the life of a super basin as a carbon storage hub for the energy transition
IF 2.7
3区 地球科学
Q2 GEOSCIENCES, MULTIDISCIPLINARY
J. Underhill, I. de Jonge-Anderson, A. D. Hollinsworth, L. C. Fyfe
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Given its favorable geology, infrastructure, and the location of major industrial emitters in adjacent land areas, offshore parts of the super basin are being evaluated and repurposed for renewable technologies like wind and geothermal energy, and as possible sites for subsurface carbon dioxide, hydrogen, compressed air, and methane gas storage. The use of a rich, dense, and high-fidelity seismic, well log, core, and pressure data sets acquired during petroleum exploration and production activities provide the basis for a play-based exploration assessment of the super basin’s carbon storage potential. The results of our analysis of the super basin’s offshore waters of the United Kingdom sector suggest that storage in traps containing Carboniferous and Permian (presalt) and Triassic (postsalt) clastic reservoirs have the potential to extend the life of the mature super basin during the energy transition. The detailed evaluation of the Rotliegend Group, from which most of the gas in the basin has been derived, enables a prospective subsalt carbon storage reservoir play fairway to be defined, common risks to be identified, and composite maps to be produced that show where the best storage Copyright ©2023. The American Association of Petroleum Geologists. All rights reserved. Gold Open Access. This paper is published under the terms of the CC-BY license. Manuscript received July 26, 2022; provisional acceptance September 20, 2022; revised manuscript received March 13, 2023; final acceptance March 20, 2023. DOI:10.1306/04042322097 AAPG Bulletin, v. 107, no. 8 (August 2023), pp. 1419–1474 1419 AUTHORS J. R. Underhill ~ Interdisciplinary Centre for Energy Transition, School of Geosciences, University of Aberdeen, King’s College, Aberdeen, Scotland, United Kingdom; john.underhill@abdn.ac.uk John R. Underhill is the director of the Interdisciplinary Centre for Energy Transition and professor of geoscience and energy transition at Aberdeen University, Scotland. He is also the academic executive director of the Centers of Doctoral Training in Oil and Gas and in GeoNetZero and served as Heriot-Watt University’s chief scientist. He populates the Scottish Science Advisory Council and UK Subsurface Task Force. John is a recognized expert on the North Sea Basin and is leading efforts to repurpose it for carbon storage and the energy transition. He has been an AAPG member for almost 40 years, during which time he has received AAPG’s George C. Matson, Grover E. Murray Distinguished Educator, and Ziad Beydoun awards, as well as the Geological Society’s Lyell Medal and their Energy Group’s Silver Medal. He is the corresponding author of this paper. I. de Jonge-Anderson ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, Heriot-Watt University (HWU), Edinburgh, Scotland, United Kingdom; I.Anderson@ hw.ac.uk Iain de Jonge-Anderson has a B.Sc. degree in petroleum geology from the University of Aberdeen (2011), an M.Sc. degree in petroleum geoscience from HWU (2013), and a Ph.D. in unconventional geomechanics (HWU, 2020). His research contribution to this paper was made whilst being a research associate evaluating carbon capture, utilization, and storage (CCUS) opportunities within the United Kingdom Southern North Sea. A. D. Hollinsworth ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, HWU, Edinburgh, Scotland, United Kingdom; A.Hollinsworth@hw.ac.uk locations are situated. Similarly, mapping of depleted fields and dry closures created by salt mobility (halokinesis) that contain Triassic Bacton Group (Bunter Sandstone Formation) reservoirs provides the basis on which to build a carbon storage prospect and lead inventory in the suprasalt section. In addition to the geological criteria, our results highlight the need to be aware of nongeological risks including the integrity of the legacy well stock and colocation issues that arise from the competition for offshore areas, especially wind farms fixed to the sea bed, since these can constrain the areas available for carbon storage that lie below them. INTRODUCTION AND AIMS Petroleum super basins are defined as those basins that have produced more than 5 billion BOE and hold additional recoverable reserves of 5 billion BOE or more (Sternbach, 2018, 2020). More than 40 super basins have been recognized globally, 10 of which contribute over three-quarters of the world’s total oil and gas production. With an increasing awareness of the need to pivot toward sustainable energy resources to meet global emission targets, there is more of a focus on super basins containing “advantaged resources” that can be decarbonized such that their indigenous reserves have a lower carbon footprint compared to oil and gas imports that would otherwise be needed, or areas that have the potential to be transformed for a low-carbon renewable energy future. Although not an energy source, carbon capture, utilization, and storage (CCUS) holds the potential by which emissions generated by power plants and heavy industrial sources may be sequestered and safely stored rather than being released into the atmosphere. In so doing, the possibility exists to ensure energy security is maintained and net zero emission targets achieved. The aim of this paper is to use play-based exploration (PBE) methods traditionally used in the subsurface interpretation of prospective petroleum basins to examine and test whether the AngloPolish Super Basin of northwestern continental Europe in general and the United Kingdom sector of the Southern North Sea in particular present a carbon storage opportunity. The results highlight the stratigraphic intervals and geographical areas that have the best potential for carbon storage as a means to meet net zero targets, transform the energy system, and extend the life of a petroleum super basin. THE ANGLO-POLISH SUPER BASIN Definition and Its Classification as a Petroleum Super Basin The Anglo-Polish Super Basin stretches from eastern England to central Poland, a distance of >900km and a width of >350km to Allan Hollinsworth has a B.Sc. degree in earth science (2015) and a Ph.D. in structural geology (2020), both obtained at the University of Glasgow. He undertook research relevant to this paper at HWU whilst undertaking a research project to evaluate CCUS opportunities within the United Kingdom Southern North Sea. He now holds a teaching fellowship at Bristol University. L. C. Fyfe ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, HWU, Edinburgh, Scotland, United Kingdom; L.Fyfe@hw.ac.uk Laura-Jane Fyfe holds a B.Sc. in geology and an M.Sc. in integrated petroleum geoscience from the University of Aberdeen, where she also completed her Ph.D. in petroleum exploration of Scotland’s inshore west coast basins. As a postdoctoral research associate at the Institute of GeoEnergy Engineering, HWU, she has collaborated with energy companies and academia on research focussing on petroleum exploration and the energy transition.","PeriodicalId":7124,"journal":{"name":"AAPG Bulletin","volume":"1 1","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2023-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"AAPG Bulletin","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1306/04042322097","RegionNum":3,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"GEOSCIENCES, MULTIDISCIPLINARY","Score":null,"Total":0}
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Abstract
The Anglo-Polish Super Basin forms an important petroleum province that stretches across northwestern Europe. It contains many giant gas fields, primarily located beneath a thick upper Permian (Zechstein Group) evaporite canopy and a smaller amount of oil and gas in Mesozoic reservoirs in the suprasalt section. Although exploration activity continues in the super basin, discoveries have diminished in size; many fields have been decommissioned; and it is beginning a transformation from an area with a rich petroleum heritage to a new, low-carbon energy hub. Given its favorable geology, infrastructure, and the location of major industrial emitters in adjacent land areas, offshore parts of the super basin are being evaluated and repurposed for renewable technologies like wind and geothermal energy, and as possible sites for subsurface carbon dioxide, hydrogen, compressed air, and methane gas storage. The use of a rich, dense, and high-fidelity seismic, well log, core, and pressure data sets acquired during petroleum exploration and production activities provide the basis for a play-based exploration assessment of the super basin’s carbon storage potential. The results of our analysis of the super basin’s offshore waters of the United Kingdom sector suggest that storage in traps containing Carboniferous and Permian (presalt) and Triassic (postsalt) clastic reservoirs have the potential to extend the life of the mature super basin during the energy transition. The detailed evaluation of the Rotliegend Group, from which most of the gas in the basin has been derived, enables a prospective subsalt carbon storage reservoir play fairway to be defined, common risks to be identified, and composite maps to be produced that show where the best storage Copyright ©2023. The American Association of Petroleum Geologists. All rights reserved. Gold Open Access. This paper is published under the terms of the CC-BY license. Manuscript received July 26, 2022; provisional acceptance September 20, 2022; revised manuscript received March 13, 2023; final acceptance March 20, 2023. DOI:10.1306/04042322097 AAPG Bulletin, v. 107, no. 8 (August 2023), pp. 1419–1474 1419 AUTHORS J. R. Underhill ~ Interdisciplinary Centre for Energy Transition, School of Geosciences, University of Aberdeen, King’s College, Aberdeen, Scotland, United Kingdom; john.underhill@abdn.ac.uk John R. Underhill is the director of the Interdisciplinary Centre for Energy Transition and professor of geoscience and energy transition at Aberdeen University, Scotland. He is also the academic executive director of the Centers of Doctoral Training in Oil and Gas and in GeoNetZero and served as Heriot-Watt University’s chief scientist. He populates the Scottish Science Advisory Council and UK Subsurface Task Force. John is a recognized expert on the North Sea Basin and is leading efforts to repurpose it for carbon storage and the energy transition. He has been an AAPG member for almost 40 years, during which time he has received AAPG’s George C. Matson, Grover E. Murray Distinguished Educator, and Ziad Beydoun awards, as well as the Geological Society’s Lyell Medal and their Energy Group’s Silver Medal. He is the corresponding author of this paper. I. de Jonge-Anderson ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, Heriot-Watt University (HWU), Edinburgh, Scotland, United Kingdom; I.Anderson@ hw.ac.uk Iain de Jonge-Anderson has a B.Sc. degree in petroleum geology from the University of Aberdeen (2011), an M.Sc. degree in petroleum geoscience from HWU (2013), and a Ph.D. in unconventional geomechanics (HWU, 2020). His research contribution to this paper was made whilst being a research associate evaluating carbon capture, utilization, and storage (CCUS) opportunities within the United Kingdom Southern North Sea. A. D. Hollinsworth ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, HWU, Edinburgh, Scotland, United Kingdom; A.Hollinsworth@hw.ac.uk locations are situated. Similarly, mapping of depleted fields and dry closures created by salt mobility (halokinesis) that contain Triassic Bacton Group (Bunter Sandstone Formation) reservoirs provides the basis on which to build a carbon storage prospect and lead inventory in the suprasalt section. In addition to the geological criteria, our results highlight the need to be aware of nongeological risks including the integrity of the legacy well stock and colocation issues that arise from the competition for offshore areas, especially wind farms fixed to the sea bed, since these can constrain the areas available for carbon storage that lie below them. INTRODUCTION AND AIMS Petroleum super basins are defined as those basins that have produced more than 5 billion BOE and hold additional recoverable reserves of 5 billion BOE or more (Sternbach, 2018, 2020). More than 40 super basins have been recognized globally, 10 of which contribute over three-quarters of the world’s total oil and gas production. With an increasing awareness of the need to pivot toward sustainable energy resources to meet global emission targets, there is more of a focus on super basins containing “advantaged resources” that can be decarbonized such that their indigenous reserves have a lower carbon footprint compared to oil and gas imports that would otherwise be needed, or areas that have the potential to be transformed for a low-carbon renewable energy future. Although not an energy source, carbon capture, utilization, and storage (CCUS) holds the potential by which emissions generated by power plants and heavy industrial sources may be sequestered and safely stored rather than being released into the atmosphere. In so doing, the possibility exists to ensure energy security is maintained and net zero emission targets achieved. The aim of this paper is to use play-based exploration (PBE) methods traditionally used in the subsurface interpretation of prospective petroleum basins to examine and test whether the AngloPolish Super Basin of northwestern continental Europe in general and the United Kingdom sector of the Southern North Sea in particular present a carbon storage opportunity. The results highlight the stratigraphic intervals and geographical areas that have the best potential for carbon storage as a means to meet net zero targets, transform the energy system, and extend the life of a petroleum super basin. THE ANGLO-POLISH SUPER BASIN Definition and Its Classification as a Petroleum Super Basin The Anglo-Polish Super Basin stretches from eastern England to central Poland, a distance of >900km and a width of >350km to Allan Hollinsworth has a B.Sc. degree in earth science (2015) and a Ph.D. in structural geology (2020), both obtained at the University of Glasgow. He undertook research relevant to this paper at HWU whilst undertaking a research project to evaluate CCUS opportunities within the United Kingdom Southern North Sea. He now holds a teaching fellowship at Bristol University. L. C. Fyfe ~ Institute of GeoEnergy Engineering, School of Energy, Geoscience, Infrastructure, and Society, HWU, Edinburgh, Scotland, United Kingdom; L.Fyfe@hw.ac.uk Laura-Jane Fyfe holds a B.Sc. in geology and an M.Sc. in integrated petroleum geoscience from the University of Aberdeen, where she also completed her Ph.D. in petroleum exploration of Scotland’s inshore west coast basins. As a postdoctoral research associate at the Institute of GeoEnergy Engineering, HWU, she has collaborated with energy companies and academia on research focussing on petroleum exploration and the energy transition.
利用勘探方法重新利用并延长超级盆地的使用寿命,使其成为能源转型的碳储存中心
英波超级盆地形成了一个重要的石油省,横跨欧洲西北部。它包含许多巨型气田,主要位于厚的上二叠统(Zechstein Group)蒸发岩冠层下方,以及少量的中生代盐上剖面储层。尽管超级盆地的勘探活动仍在继续,但发现的规模已经缩小;许多油田已经停产;它正开始从一个拥有丰富石油资源的地区转变为一个新的低碳能源中心。考虑到其优越的地质条件、基础设施和毗邻陆地的主要工业排放物的位置,超级盆地的海上部分正在进行评估,并重新利用风能和地热能等可再生能源技术,并可能成为地下二氧化碳、氢气、压缩空气和甲烷气体储存的场所。利用在石油勘探和生产活动中获得的丰富、密集、高保真的地震、测井、岩心和压力数据集,为基于油气藏的超级盆地碳储存潜力勘探评估提供了基础。对超级盆地英国部分近海海域的分析结果表明,在能量转换过程中,石炭系和二叠系(盐下)和三叠系(盐后)碎屑储层的圈闭具有延长成熟超级盆地寿命的潜力。Rotliegend组是盆地中大部分天然气的来源,通过对该组的详细评估,可以确定盐下储层的储层路径,识别常见风险,并生成复合图,显示最佳储层。美国石油地质学家协会。版权所有。金牌开放访问。本文在CC-BY许可条款下发布。2022年7月26日收稿;2022年9月20日临时验收;2023年3月13日收稿;2023年3月20日最终验收。DOI:10.1306/04042322097 AAPG Bulletin, v. 107, no。作者J. R. Underhill ~能源转型跨学科中心,阿伯丁大学,国王学院,阿伯丁,苏格兰,英国;john.underhill@abdn.ac.uk约翰·r·昂德希尔,能源转型跨学科中心主任,苏格兰阿伯丁大学地球科学与能源转型教授。他还是石油和天然气博士培训中心和GeoNetZero的学术执行主任,并担任赫瑞瓦特大学的首席科学家。他是苏格兰科学咨询委员会和英国地下工作组的成员。约翰是公认的北海盆地专家,他正在努力将其重新用于碳储存和能源转型。他是AAPG成员近40年,在此期间,他获得了AAPG的George C. Matson, Grover E. Murray杰出教育家和Ziad beydown奖,以及地质学会的莱尔奖章和他们的能源集团的银奖。他是这篇论文的通讯作者。I. de Jonge-Anderson ~赫瑞瓦特大学能源、地球科学、基础设施与社会学院地球能源工程研究所,英国苏格兰爱丁堡;Iain de Jonge-Anderson, 2011年获英国阿伯丁大学石油地质学学士学位,2013年获哈佛大学石油地球科学硕士学位,2020年获哈佛大学非常规地质力学博士学位。他对本文的研究贡献是在担任英国南北海评估碳捕集、利用和封存(CCUS)机会的研究助理期间完成的。A. D. Hollinsworth ~英国爱丁堡大学能源、地球科学、基础设施与社会学院地球能源工程研究所;A.Hollinsworth@hw.ac.uk位置位于。同样,对含有三叠纪巴克顿组(邦特砂岩组)储层的枯竭油田和干闭井进行测绘,为建立超盐段的碳储存前景和铅库存提供了基础。除了地质标准之外,我们的研究结果还强调了需要意识到非地质风险,包括遗留井库存的完整性和海上地区竞争产生的托管问题,特别是固定在海床上的风力发电场,因为这些可能会限制其下方可用的碳储存区域。石油超级盆地被定义为那些产量超过50亿桶油当量、额外可采储量超过50亿桶油当量的盆地(Sternbach, 2018, 2020)。 全球已经发现了40多个超级盆地,其中10个盆地的油气产量占全球总产量的四分之三以上。随着人们越来越意识到需要转向可持续能源以满足全球排放目标,人们越来越关注含有“优势资源”的超级盆地,这些资源可以脱碳,使其本土储量的碳足迹低于需要进口的石油和天然气,或者有潜力转型为低碳可再生能源未来的地区。虽然碳捕获、利用和封存(CCUS)不是一种能源,但它有可能将发电厂和重工业产生的碳隔离和安全封存,而不是释放到大气中。这样做,就有可能确保维持能源安全并实现净零排放目标。本文的目的是使用传统上用于潜在含油气盆地地下解释的基于游戏的勘探(PBE)方法来检查和测试欧洲大陆西北部的英波超级盆地,特别是北海南部的英国部分是否存在碳储存机会。研究结果突出了具有最佳储碳潜力的地层间隔和地理区域,作为实现净零目标、改造能源系统和延长石油超级盆地寿命的手段。英波超级盆地从英格兰东部延伸至波兰中部,距离超过900公里,宽度超过350公里。Allan Hollinsworth在格拉斯哥大学获得地球科学学士学位(2015年)和构造地质学博士学位(2020年)。他在HWU进行了与本文相关的研究,同时承担了一个评估英国南北海CCUS机会的研究项目。他现在在布里斯托尔大学担任教职。L. C. Fyfe ~能源、地球科学、基础设施与社会学院地球能源工程研究所,爱丁堡,苏格兰,英国;L.Fyfe@hw.ac.uk Laura-Jane Fyfe持有the University of Aberdeen的地质学学士学位和综合石油地球科学硕士学位,在那里她还完成了苏格兰近海西海岸盆地石油勘探的博士学位。作为地球能源工程研究所的博士后研究员,她与能源公司和学术界合作,研究重点是石油勘探和能源转型。
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