MAGNEX and PILCCU in Finland: deployment of CO2 mineralisation in circular economies

Baltic Carbon Forum Pub Date : 2023-10-13 DOI:10.21595/bcf.2023.23569

Ron Zevenhoven, Päivö Kinnunen, Jarkko Levänen, Heikki Pirinen, Erkki Levänen

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Abstract

Two ongoing projects in Finland, MAGNEX ( Viable magnesium ecosystem: exploiting Mg from magnesium silicates with carbon capture and utilization ) and PILCCU ( Piloting of ÅA CCU ) aim at using CO 2 mineralisation technology for the overlapping purposes of large-scale CO 2 emissions mitigation and bringing several valuable material streams into circular economies, including construction. Of central importance are magnesium-based materials, such as magnesium carbonate hydrate (MCH), besides (amorphous) silica and several metallic species. On top of revenues from these, CO 2 emissions mitigation lowers the financial penalty from CO 2 emission rights under for example the European ETS. The ÅA process routes are stepwise processes based on extraction of magnesium (and other species) from serpentinite-containing mining tailings from Finland, followed by precipitation of metallic species, carbonation using a CO 2 containing gas-stream (no separate capture step needed) and recovery of solvent salt, respectively. Several separation steps involve (ion-selective) membrane electrodialysis. Besides ongoing mapping and characterisation of Finnish rock resources as tailings or other side-streams at metal and mineral mines in Finland, the projects address public acceptance, legislation and other non-technical issues related to large-scale roll-out of this type of CCU technology. For the use of the solids, magnesium-based cement binders and plaster-like recipes are investigated as well as applications for the (amorphous) silica and other residues, including the use of MCH for cyclic thermal energy storage (TES). Special focus is on accelerating the carbonation step and the final outcome of MCH production, considering pressure (including supercritical CO 2 levels), and the role of recoverable catalysts and other additives. The work receives funding from the Academy of Finland (2022-2025) and from Business Finland plus industry partners (2022-2024), respectively.

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芬兰的MAGNEX和PILCCU:循环经济中二氧化碳矿化的部署

芬兰正在进行的两个项目，MAGNEX(可行的镁生态系统:通过碳捕获和利用从硅酸镁中开采镁)和PILCCU (ÅA CCU试点)，旨在利用二氧化碳矿化技术实现大规模二氧化碳减排的重叠目的，并将几种有价值的材料流引入循环经济，包括建筑。最重要的是镁基材料，如碳酸镁水合物(MCH)，以及(无定形)二氧化硅和几种金属。在这些收入的基础上，二氧化碳减排降低了二氧化碳排放权(例如欧洲排放权交易体系)带来的经济处罚。ÅA工艺路线是基于从芬兰含蛇纹岩的采矿尾矿中提取镁(和其他物种)，然后分别沉淀金属物种，使用含二氧化碳的气流进行碳化(不需要单独的捕获步骤)和回收溶剂盐的逐步过程。几个分离步骤涉及(离子选择性)膜电渗析。除了正在进行的芬兰岩石资源的测绘和特征描述，如芬兰金属和矿物矿山的尾矿或其他侧流，这些项目还涉及与大规模推广这种CCU技术有关的公众接受、立法和其他非技术问题。对于固体材料的使用，研究了镁基水泥粘结剂和类似石膏的配方，以及(无定形)二氧化硅和其他残留物的应用，包括MCH用于循环热能储存(TES)。特别侧重于加速碳化步骤和MCH生产的最终结果，考虑压力(包括超临界CO 2水平)以及可回收催化剂和其他添加剂的作用。这项工作分别获得芬兰科学院(2022-2025)和芬兰商业及行业合作伙伴(2022-2024)的资助。

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Baltic Carbon Forum

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