Creating a carbon dioxide removal solution by combining rapid mineralization of CO2 with direct air capture

被引:50
|
作者
Gutknecht, Valentin [1 ]
Snaebjornsdottir, Sandra Osk [2 ]
Sigfusson, Bergur [2 ]
Aradottir, Edda Sif [2 ]
Charles, Louise [1 ]
机构
[1] Climeworks, Birchstr 155, CH-8050 Zurich, Switzerland
[2] Reykjavik Energy, Baejarhols 1, IS-109 Reykjavik, Iceland
来源
CARBON IN NATURAL AND ENGINEERED PROCESSES | 2018年 / 146卷
基金
欧盟地平线“2020”;
关键词
Carbon Dioxide Removal; negative emissions technologies; CarbFix; Reykjavik Energy; Carbon Capture and Storage; CO2; mineralization; Direct air capture; DAC; Climeworks; STORAGE;
D O I
10.1016/j.egypro.2018.07.017
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
As a part of the EU-funded CarbFix2 project, Climeworks and Reykjavik Energy have partnered to combine direct air capture (DAC) technology with the injection of CO2 into basalts, for permanent storage by mineralization of the injected carbon. This is the world's first DAC installation that is combined with mineral storage of CO2. There is large potential for further optimization and substantial scale up of this joint operation. The organizations are developing an integrated CO2 removal solution that may be expanded and applied globally. This type of solution has been recognized as a crucial component in efforts to mitigate global warming. Copyright (C) 2018 Elsevier Ltd. All rights reserved.
引用
收藏
页码:129 / 134
页数:6
相关论文
共 50 条
  • [1] Indoor CO2 removal: decentralized carbon capture by air conditioning
    Tian, H.
    Zhu, L.
    Ni, J.
    Wei, T.
    Wang, P.
    Xiao, H.
    Chen, X.
    [J]. MATERIALS TODAY SUSTAINABILITY, 2023, 22
  • [2] Simultaneous capture and mineralization of coal combustion flue gas carbon dioxide (CO2)
    Reddy, Katta J.
    John, Sanil
    Weber, Hollis
    Argyle, Morris D.
    Bhattacharyya, Pradip
    Taylor, David T.
    Christensen, Mikol
    Foulke, Thomas
    Fahlsing, Paul
    [J]. 10TH INTERNATIONAL CONFERENCE ON GREENHOUSE GAS CONTROL TECHNOLOGIES, 2011, 4 : 1574 - 1583
  • [3] Pricing CO2 Direct Air Capture
    Sutherland, Brandon R.
    [J]. JOULE, 2019, 3 (07) : 1571 - 1573
  • [4] Evaluating feedstocks for carbon dioxide removal by enhanced rock weathering and CO2 mineralization
    Paulo, Carlos
    Power, Ian M.
    Stubbs, Amanda R.
    Wang, Baolin
    Zeyen, Nina
    Wilson, Sasha
    [J]. APPLIED GEOCHEMISTRY, 2021, 129
  • [5] Simulation of carbon dioxide direct air capture plant using potassium hydroxide aqueous Solution: Energy optimization and CO2 purity enhancement
    Zolfaghari, Zahra
    Aslani, Alireza
    Zahedi, Rahim
    Kazzazi, Sina
    [J]. ENERGY CONVERSION AND MANAGEMENT-X, 2024, 21
  • [6] Integrated CO2 Capture and Removal via Carbon Mineralization with Inherent Regeneration of Aqueous Solvents
    Liu, Meishen
    Hohenshil, Allison
    Gadikota, Greeshma
    [J]. ENERGY & FUELS, 2021, 35 (09) : 8051 - 8068
  • [7] Direct Air Capture carbon dioxide by the 2D single atom solution compressor
    Wu, Yuansheng
    Zhou, Chenyang
    Li, Yuan
    Yu, Yunsong
    Zhang, Zaoxiao
    Wang, Geoff
    [J]. SEPARATION AND PURIFICATION TECHNOLOGY, 2025, 353
  • [8] The thermodynamics of direct air capture of carbon dioxide
    Lackner, Klaus S.
    [J]. ENERGY, 2013, 50 : 38 - 46
  • [9] Direct Air Capture of CO2 by Physisorbent Materials
    Kumar, Amrit
    Madden, David G.
    Lusi, Matteo
    Chen, Kai-Jie
    Daniels, Emma A.
    Curtin, Teresa
    Perry, John J.
    Zaworotko, Michael J.
    [J]. ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2015, 54 (48) : 14372 - 14377
  • [10] A method for siting adsorption-based direct air carbon capture and storage plants for maximum CO2 removal
    Rezo, D.
    Postweiler, P.
    Engelpracht, M.
    Meuleneers, L.
    von der Assen, N.
    [J]. CARBON NEUTRALITY, 2024, 3 (01):
12345