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Hydrogen production from natural gas, sequestration of recovered CO2 in depleted gas wells and enhanced natural gas recovery

Author

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  • Blok, K.
  • Williams, R.H.
  • Katofsky, R.E.
  • Hendriks, C.A.

Abstract

If fuel cells are introduced for vehicular applications, hydrogen might become an energy carrier for transport applications. Manufacture via steam-reforming of natural gas is a low-cost option for hydrogen production. This study deals with the feasibility of combining the production of hydrogen from natural gas with CO2 removal. When hydrogen is produced from natural gas, a concentrated stream of CO2 is generated as a by-product. If manufacture is carried out near a depleted natural gas field, the separated CO2 can be compressed and injected into the field and securely sequestered there. The incremental cost of the produced hydrogen (for CO2 compression plus transport, injection and storage) would typically be about 7% relative to the case where the separated CO2 is vented. Moreover, CO2 injection leads to enhanced natural gas recovery as a result of reservoir repressurization. Though the extra natural gas is somewhat contaminated with CO2, it is a suitable feedstock for hydrogen production. Taking credit for enhanced natural gas recovery reduces the penalty for sequestration to a net incremental cost of typically 2%. These cost penalties are much lower than those typical of CO2 removal schemes associated with electricity production. Attention is required for optimum plant siting in order to keep CO2 transport costs low.

Suggested Citation

  • Blok, K. & Williams, R.H. & Katofsky, R.E. & Hendriks, C.A., 1997. "Hydrogen production from natural gas, sequestration of recovered CO2 in depleted gas wells and enhanced natural gas recovery," Energy, Elsevier, vol. 22(2), pages 161-168.
    • Handle: RePEc:eee:energy:v:22:y:1997:i:2:p:161-168
    DOI: 10.1016/S0360-5442(96)00136-3
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    Citations

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    Cited by:

    1. Anderson, Soren T. & Newell, Richard G., 2003. "Prospects for Carbon Capture and Storage Technologies," Discussion Papers 10879, Resources for the Future.
    2. Singh, A.K. & Goerke, U.-J. & Kolditz, O., 2011. "Numerical simulation of non-isothermal compositional gas flow: Application to carbon dioxide injection into gas reservoirs," Energy, Elsevier, vol. 36(5), pages 3446-3458.
    3. Hamelinck, C.N & Faaij, A.P.C & Turkenburg, W.C & van Bergen, F & Pagnier, H.J.M & Barzandji, O.H.M & Wolf, K.-H.A.A & Ruijg, G.J, 2002. "CO2 enhanced coalbed methane production in the Netherlands," Energy, Elsevier, vol. 27(7), pages 647-674.
    4. Wang, Qiuying & Zhu, Xiaomei & Sun, Bing & Li, Zhi & Liu, Jinglin, 2022. "Hydrogen production from methane via liquid phase microwave plasma: A deoxidation strategy," Applied Energy, Elsevier, vol. 328(C).
    5. Biagi, James & Agarwal, Ramesh & Zhang, Zheming, 2016. "Simulation and optimization of enhanced gas recovery utilizing CO2," Energy, Elsevier, vol. 94(C), pages 78-86.
    6. Keipi, Tiina & Li, Tian & Løvås, Terese & Tolvanen, Henrik & Konttinen, Jukka, 2017. "Methane thermal decomposition in regenerative heat exchanger reactor: Experimental and modeling study," Energy, Elsevier, vol. 135(C), pages 823-832.
    7. Abánades, A. & Rubbia, C. & Salmieri, D., 2012. "Technological challenges for industrial development of hydrogen production based on methane cracking," Energy, Elsevier, vol. 46(1), pages 359-363.
    8. Wang, Junye, 2015. "Barriers of scaling-up fuel cells: Cost, durability and reliability," Energy, Elsevier, vol. 80(C), pages 509-521.
    9. Chaubey, Rashmi & Sahu, Satanand & James, Olusola O. & Maity, Sudip, 2013. "A review on development of industrial processes and emerging techniques for production of hydrogen from renewable and sustainable sources," Renewable and Sustainable Energy Reviews, Elsevier, vol. 23(C), pages 443-462.
    10. Wang, Yangyang & Liu, Yangyang & Xu, Zaifeng & Yin, Kexin & Zhou, Yaru & Zhang, Jifu & Cui, Peizhe & Ma, Shinan & Wang, Yinglong & Zhu, Zhaoyou, 2024. "A review on renewable energy-based chemical engineering design and optimization," Renewable and Sustainable Energy Reviews, Elsevier, vol. 189(PB).
    11. Abdirizak Omar & Mouadh Addassi & Volker Vahrenkamp & Hussein Hoteit, 2021. "Co-Optimization of CO 2 Storage and Enhanced Gas Recovery Using Carbonated Water and Supercritical CO 2," Energies, MDPI, vol. 14(22), pages 1-21, November.
    12. Tzimas, Evangelos & Peteves, Stathis D., 2005. "The impact of carbon sequestration on the production cost of electricity and hydrogen from coal and natural-gas technologies in Europe in the medium term," Energy, Elsevier, vol. 30(14), pages 2672-2689.

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