{"title":"Geological carbon storage in northern Irish basalts: prospectivity and potential","authors":"Graham D. M. Andrews","doi":"10.3389/fclim.2023.1207668","DOIUrl":null,"url":null,"abstract":"Carbon mineralization and storage in basaltic rock sequences is a developing technology but faces challenges with uptake and increases in scale. Northern Ireland (UK) is a useful analog for many parts of the world where thick basalt sequences could be used to aid in reaching carbon reduction and removal targets. Here I reanalyze and reinterpret available lithological, geochemical, and geophysical data to assess carbon storage potential. The physical and geochemical properties of the basalts are indistinguishable from those used for successful carbon sequestration in Iceland and Washington State (USA). Based on the thickness, composition, and potential permeability, I propose that this is a viable location for a series of small-volume stores (total volume ~9–12 MT CO 2 ) suitable for capture at industrial point-sources or purpose-built CO 2 “harvesting” facilities. The case for exploiting the CO 2 storage potential in Northern Ireland is strengthened by (1) an increasingly urgent need to find socially and economically just decarbonization pathways needed to meet NI's targets, (2) increasing realization among policy experts that point-source CO 2 capture and industrial decarbonization will be insufficient to meet those goals, due in part, to the size of the agricultural sector, and (3) the coincidence with plentiful renewable energy and geothermally-sourced industrial heat. These serendipitous relationships could be leveraged to develop CO 2 -“farms” where direct air capture operations are supplied by renewable energy (biomass and geothermal) and on-site geological storage. I envisage that these sites could be supplemented by CO 2 from locally produced biomass as farmers are encouraged to transition away from raising livestock. Because CO 2 can be captured directly from the atmosphere or via suitable biomass anywhere, NI's small size and position on the periphery of the UK and Europe need not be a disadvantage. Instead, NI's access to geological storage, renewable energy, and agricultural land may be a boon, and provide new opportunities to become a leader in carbon removal in basalt-covered regions.","PeriodicalId":33632,"journal":{"name":"Frontiers in Climate","volume":"33 1","pages":"0"},"PeriodicalIF":3.3000,"publicationDate":"2023-09-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Frontiers in Climate","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3389/fclim.2023.1207668","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENVIRONMENTAL SCIENCES","Score":null,"Total":0}
引用次数: 0
Abstract
Carbon mineralization and storage in basaltic rock sequences is a developing technology but faces challenges with uptake and increases in scale. Northern Ireland (UK) is a useful analog for many parts of the world where thick basalt sequences could be used to aid in reaching carbon reduction and removal targets. Here I reanalyze and reinterpret available lithological, geochemical, and geophysical data to assess carbon storage potential. The physical and geochemical properties of the basalts are indistinguishable from those used for successful carbon sequestration in Iceland and Washington State (USA). Based on the thickness, composition, and potential permeability, I propose that this is a viable location for a series of small-volume stores (total volume ~9–12 MT CO 2 ) suitable for capture at industrial point-sources or purpose-built CO 2 “harvesting” facilities. The case for exploiting the CO 2 storage potential in Northern Ireland is strengthened by (1) an increasingly urgent need to find socially and economically just decarbonization pathways needed to meet NI's targets, (2) increasing realization among policy experts that point-source CO 2 capture and industrial decarbonization will be insufficient to meet those goals, due in part, to the size of the agricultural sector, and (3) the coincidence with plentiful renewable energy and geothermally-sourced industrial heat. These serendipitous relationships could be leveraged to develop CO 2 -“farms” where direct air capture operations are supplied by renewable energy (biomass and geothermal) and on-site geological storage. I envisage that these sites could be supplemented by CO 2 from locally produced biomass as farmers are encouraged to transition away from raising livestock. Because CO 2 can be captured directly from the atmosphere or via suitable biomass anywhere, NI's small size and position on the periphery of the UK and Europe need not be a disadvantage. Instead, NI's access to geological storage, renewable energy, and agricultural land may be a boon, and provide new opportunities to become a leader in carbon removal in basalt-covered regions.
玄武岩层序碳矿化与封存技术是一项发展中的技术,但随着吸收和规模的扩大,面临着挑战。北爱尔兰(英国)是世界上许多地方的一个有用的类比,在那里厚的玄武岩序列可以用来帮助实现碳减排和去除目标。在这里,我重新分析和解释现有的岩性、地球化学和地球物理数据,以评估碳储存潜力。玄武岩的物理和地球化学性质与冰岛和华盛顿州(美国)用于成功固碳的玄武岩没有区别。根据厚度、成分和潜在渗透性,我认为这是一个可行的位置,适合在工业点源或专门建造的二氧化碳“收集”设施中捕获一系列小容量存储(总容积约9-12 MT CO 2)。开发北爱尔兰二氧化碳储存潜力的理由得到了以下方面的加强:(1)越来越迫切地需要找到实现NI目标所需的社会和经济上公正的脱碳途径;(2)政策专家越来越认识到,由于农业部门的规模,点源二氧化碳捕获和工业脱碳不足以实现这些目标;(3)与丰富的可再生能源和地热工业热的巧合。这些偶然的关系可以用来开发二氧化碳“农场”,在那里,直接的空气捕获操作由可再生能源(生物质能和地热)和现场地质储存提供。我设想,随着农民被鼓励从饲养牲畜过渡到畜牧业,这些地方可以由当地生产的生物质产生的二氧化碳来补充。因为二氧化碳可以直接从大气中捕获,也可以通过合适的生物质在任何地方捕获,NI的小尺寸和在英国和欧洲外围的位置不一定是一个劣势。相反,NI对地质储存、可再生能源和农业用地的利用可能是一个福音,并为成为玄武岩覆盖地区碳去除的领导者提供了新的机会。