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A proposed global layout of carbon capture and storage in line with a 2 °C climate target

Author

Listed:
  • Yi-Ming Wei

    (Beijing Institute of Technology
    Beijing Institute of Technology
    Beijing Key Lab of Energy Economics and Environmental Management)

  • Jia-Ning Kang

    (Beijing Institute of Technology
    Beijing Institute of Technology
    Beijing Key Lab of Energy Economics and Environmental Management)

  • Lan-Cui Liu

    (Beijing Normal University)

  • Qi Li

    (Chinese Academy of Sciences)

  • Peng-Tao Wang

    (Beijing Institute of Technology
    China University of Mining & Technology, Beijing)

  • Juan-Juan Hou

    (Beijing Normal University)

  • Qiao-Mei Liang

    (Beijing Institute of Technology
    Beijing Institute of Technology
    Beijing Key Lab of Energy Economics and Environmental Management)

  • Hua Liao

    (Beijing Institute of Technology
    Beijing Institute of Technology
    Beijing Key Lab of Energy Economics and Environmental Management)

  • Shi-Feng Huang

    (China Institute of Water Resources and Hydropower Research)

  • Biying Yu

    (Beijing Institute of Technology
    Beijing Institute of Technology
    Beijing Key Lab of Energy Economics and Environmental Management)

Abstract

A straightforward global layout of carbon capture, utilization and storage (CCUS) is imperative for limiting global warming well below 2 °C. Here, we propose a cost-effective strategy for matching carbon sources and sinks on a global scale. Results show 3,093 carbon clusters and 432 sinks in 85 countries and regions are selected to achieve 92 GtCO2 mitigation by CCUS, 64% of which will be sequestered into sedimentary basins for aquifer storage and 36% will be used for CO2-EOR (enhanced oil recovery). Of the identified source–sink matching, 80% are distributed within 300 km and are mainly located in China, the United States, the European Union, Russia and India. The total cost is ~0.12% of global cumulative gross domestic product. Of countries with CO2-EOR, 75% will turn into profitable at the oil price over US$100 per barrel. These findings indicate our proposed layout is economically feasible. However, its implementation requires global collaboration on financial and technological transfer.

Suggested Citation

  • Yi-Ming Wei & Jia-Ning Kang & Lan-Cui Liu & Qi Li & Peng-Tao Wang & Juan-Juan Hou & Qiao-Mei Liang & Hua Liao & Shi-Feng Huang & Biying Yu, 2021. "A proposed global layout of carbon capture and storage in line with a 2 °C climate target," Nature Climate Change, Nature, vol. 11(2), pages 112-118, February.
    • Handle: RePEc:nat:natcli:v:11:y:2021:i:2:d:10.1038_s41558-020-00960-0
    DOI: 10.1038/s41558-020-00960-0
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    Citations

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    Cited by:

    1. Changwan Gu & Jingjing Xie & Xiaoyu Li & Xu Gao, 2023. "Levelized Cost Analysis for Blast Furnace CO 2 Capture, Utilization, and Storage Retrofit in China’s Blast Furnace–Basic Oxygen Furnace Steel Plants," Energies, MDPI, vol. 16(23), pages 1-20, November.
    2. Ikonnikova, Svetlana A. & Scanlon, Bridget R. & Berdysheva, Sofia A., 2023. "A global energy system perspective on hydrogen Trade: A framework for the market color and the size analysis," Applied Energy, Elsevier, vol. 330(PA).
    3. Jing-Li Fan & Zezheng Li & Xi Huang & Kai Li & Xian Zhang & Xi Lu & Jianzhong Wu & Klaus Hubacek & Bo Shen, 2023. "A net-zero emissions strategy for China’s power sector using carbon-capture utilization and storage," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    4. Kang, Jia-Ning & Wei, Yi-Ming & Liu, Lan-cui & Wang, Jin-Wei, 2021. "Observing technology reserves of carbon capture and storage via patent data: Paving the way for carbon neutral," Technological Forecasting and Social Change, Elsevier, vol. 171(C).
    5. He, Jianjian & Yang, Yi & Liao, Zhongju & Xu, Anqi & Fang, Kai, 2022. "Linking SDG 7 to assess the renewable energy footprint of nations by 2030," Applied Energy, Elsevier, vol. 317(C).
    6. Xu, Liang & Li, Qi & Myers, Matthew & Cao, Xiaomin, 2023. "Investigation of the enhanced oil recovery mechanism of CO2 synergistically with nanofluid in tight glutenite," Energy, Elsevier, vol. 273(C).
    7. Jing, Jing & Yang, Yanlin & Cheng, Jianmei & Ding, Zhaojing & Wang, Dandan & Jing, Xianwen, 2023. "Analysis of the effect of formation dip angle and injection pressure on the injectivity and migration of CO2 during storage," Energy, Elsevier, vol. 280(C).
    8. Minwoo Hyun & Aleh Cherp & Jessica Jewell & Yeong Jae Kim & Jiyong Eom, 2021. "Feasibility trade-offs in decarbonisation of power sector with high coal dependence: A case of Korea," Papers 2111.02872, arXiv.org.
    9. Brenda H. M. Silveira & Hirdan K. M. Costa & Edmilson M. Santos, 2023. "Bioenergy with Carbon Capture and Storage (BECCS) in Brazil: A Review," Energies, MDPI, vol. 16(4), pages 1-18, February.
    10. Andrew K. Chu & Sally M. Benson & Gege Wen, 2022. "Deep-Learning-Based Flow Prediction for CO 2 Storage in Shale–Sandstone Formations," Energies, MDPI, vol. 16(1), pages 1-21, December.
    11. Muhammad Hammad Rasool & Maqsood Ahmad & Muhammad Ayoub, 2023. "Selecting Geological Formations for CO 2 Storage: A Comparative Rating System," Sustainability, MDPI, vol. 15(8), pages 1-39, April.
    12. Masood S. Alivand & Omid Mazaheri & Yue Wu & Ali Zavabeti & Andrew J. Christofferson & Nastaran Meftahi & Salvy P. Russo & Geoffrey W. Stevens & Colin A. Scholes & Kathryn A. Mumford, 2022. "Engineered assembly of water-dispersible nanocatalysts enables low-cost and green CO2 capture," Nature Communications, Nature, vol. 13(1), pages 1-11, December.

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