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Assessing the feasibility of carbon dioxide mitigation options in terms of energy usage

Author

Listed:
  • Oytun Babacan

    (Imperial College London
    Imperial College London)

  • Sven Causmaecker

    (Imperial College London)

  • Ajay Gambhir

    (Imperial College London)

  • Mathilde Fajardy

    (Imperial College London
    Imperial College London)

  • A. William Rutherford

    (Imperial College London)

  • Andrea Fantuzzi

    (Imperial College London)

  • Jenny Nelson

    (Imperial College London
    Imperial College London)

Abstract

Measures to mitigate the emissions of carbon dioxide (CO2) can vary substantially in terms of the energy required. Some proposed CO2 mitigation options involve energy-intensive processes that compromise their viability as routes to mitigation, especially if deployed at a global scale. Here we provide an assessment of different mitigation options in terms of their energy usage. We assess the relative effectiveness of several CO2 mitigation routes by calculating the energy cost of carbon abatement (kilowatt-hour spent per kilogram CO2-equivalent, or kWh kgCO2e–1) mitigated. We consider energy efficiency measures, decarbonizing electricity, heat, chemicals and fuels, and also capturing CO2 from air. Among the routes considered, switching to renewable energy technologies (0.05–0.53 kWh kgCO2e–1 mitigated) offer more energy-effective mitigation than carbon embedding or carbon removal approaches, which are more energy intensive (0.99–10.03 kWh kgCO2e–1 and 0.78–2.93 kWh kgCO2e–1 mitigated, respectively), whereas energy efficiency measures, such as improving building lighting, can offer the most energy-effective mitigation.

Suggested Citation

  • Oytun Babacan & Sven Causmaecker & Ajay Gambhir & Mathilde Fajardy & A. William Rutherford & Andrea Fantuzzi & Jenny Nelson, 2020. "Assessing the feasibility of carbon dioxide mitigation options in terms of energy usage," Nature Energy, Nature, vol. 5(9), pages 720-728, September.
    • Handle: RePEc:nat:natene:v:5:y:2020:i:9:d:10.1038_s41560-020-0646-1
    DOI: 10.1038/s41560-020-0646-1
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    Citations

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    Cited by:

    1. Aljoša Slameršak & Giorgos Kallis & Daniel W. O’Neill, 2022. "Energy requirements and carbon emissions for a low-carbon energy transition," Nature Communications, Nature, vol. 13(1), pages 1-15, December.
    2. Hua, Weiqi & Chen, Ying & Qadrdan, Meysam & Jiang, Jing & Sun, Hongjian & Wu, Jianzhong, 2022. "Applications of blockchain and artificial intelligence technologies for enabling prosumers in smart grids: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 161(C).
    3. Liu, Xianglei & Cheng, Bo & Zhu, Qibin & Gao, Ke & Sun, Nan & Tian, Cheng & Wang, Jiaqi & Zheng, Hangbin & Wang, Xinrui & Dang, Chunzhuo & Xuan, Yimin, 2022. "Highly efficient solar-driven CO2 reforming of methane via concave foam reactors," Energy, Elsevier, vol. 261(PB).
    4. Behrang Shirizadeh & Manuel Villavicencio & Sebastien Douguet & Johannes Trüby & Charbel Bou Issa & Gondia Sokhna Seck & Vincent D’herbemont & Emmanuel Hache & Louis-Marie Malbec & Jerome Sabathier & , 2023. "The impact of methane leakage on the role of natural gas in the European energy transition," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    5. Xiaoyang Hou & Shuai Zhong & Jian’an Zhao, 2022. "A Critical Review on Decarbonizing Heating in China: Pathway Exploration for Technology with Multi-Sector Applications," Energies, MDPI, vol. 15(3), pages 1-23, February.
    6. Pavel Tcvetkov, 2021. "Climate Policy Imbalance in the Energy Sector: Time to Focus on the Value of CO 2 Utilization," Energies, MDPI, vol. 14(2), pages 1-22, January.
    7. Lisa Winkler & Drew Pearce & Jenny Nelson & Oytun Babacan, 2023. "The effect of sustainable mobility transition policies on cumulative urban transport emissions and energy demand," Nature Communications, Nature, vol. 14(1), pages 1-14, December.

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