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Catalytic hydrogen production from fossil fuels via the water gas shift reaction

Author

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  • Gradisher, Logan
  • Dutcher, Bryce
  • Fan, Maohong

Abstract

The production of hydrogen is a highly researched topic for many reasons. First of all, it is a clean fuel that can be used instead of hydrocarbons, which produce CO2, a greenhouse gas emission that is thought to be the reason for climate change in the world. The largest source of hydrogen is the water gas shift (WGS) reaction, where CO and water are mixed over a catalyst to produce the desired hydrogen. Many researchers have focused on development of WGS catalysts with different metals. The most notable of these metals are precious and rare earth metals which, when combined, have unique properties for the WGS reaction. Research in this area is very important to the energy industry and the future of energy around the world. However, the progress made recently has not been reviewed, and this review was designed to fill the gap.

Suggested Citation

  • Gradisher, Logan & Dutcher, Bryce & Fan, Maohong, 2015. "Catalytic hydrogen production from fossil fuels via the water gas shift reaction," Applied Energy, Elsevier, vol. 139(C), pages 335-349.
  • Handle: RePEc:eee:appene:v:139:y:2015:i:c:p:335-349
    DOI: 10.1016/j.apenergy.2014.10.080
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    References listed on IDEAS

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    1. Soo, S.L. & Gibbs, R.T., 1979. "A steam process for coal gasification," Energy, Elsevier, vol. 4(2), pages 357-364.
    2. Maciel, Cristhiane Guimarães & Silva, Tatiana de Freitas & Assaf, Elisabete Moreira & Assaf, José Mansur, 2013. "Hydrogen production and purification from the water–gas shift reaction on CuO/CeO2–TiO2 catalysts," Applied Energy, Elsevier, vol. 112(C), pages 52-59.
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    Cited by:

    1. Chein, Rei-Yu & Yu, Ching-Tsung, 2017. "Thermodynamic equilibrium analysis of water-gas shift reaction using syngases-effect of CO2 and H2S contents," Energy, Elsevier, vol. 141(C), pages 1004-1018.
    2. Wang, Zhe & Fan, Weiyu & Zhang, Guangqing & Dong, Shuang, 2016. "Exergy analysis of methane cracking thermally coupled with chemical looping combustion for hydrogen production," Applied Energy, Elsevier, vol. 168(C), pages 1-12.
    3. Shahbeik, Hossein & Peng, Wanxi & Kazemi Shariat Panahi, Hamed & Dehhaghi, Mona & Guillemin, Gilles J. & Fallahi, Alireza & Amiri, Hamid & Rehan, Mohammad & Raikwar, Deepak & Latine, Hannes & Pandalon, 2022. "Synthesis of liquid biofuels from biomass by hydrothermal gasification: A critical review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 167(C).
    4. Chen, Wei-Hsin & Chen, Chia-Yang, 2020. "Water gas shift reaction for hydrogen production and carbon dioxide capture: A review," Applied Energy, Elsevier, vol. 258(C).
    5. Chen, Qindong & Hu, Song & Xu, Qiyong & Su, Sheng & Wang, Yi & Xu, Kai & He, Limo & Xiang, Jun, 2021. "Steam synergic effect on oxygen carrier performance and WGS promotion ability of iron-oxides," Energy, Elsevier, vol. 215(PA).
    6. Wachter, Philipp & Gaber, Christian & Demuth, Martin & Hochenauer, Christoph, 2020. "Experimental investigation of tri-reforming on a stationary, recuperative TCR-reformer applied to an oxy-fuel combustion of natural gas, using a Ni-catalyst," Energy, Elsevier, vol. 212(C).
    7. Sun, Zhao & Chen, Shiyi & Ma, Shiwei & Xiang, Wenguo & Song, Quanbin, 2016. "Simulation of the calcium looping process (CLP) for hydrogen, carbon monoxide and acetylene poly-generation with CO2 capture and COS reduction," Applied Energy, Elsevier, vol. 169(C), pages 642-651.
    8. Danilov, Nikolay & Lyagaeva, Julia & Vdovin, Gennady & Medvedev, Dmitry, 2019. "Multifactor performance analysis of reversible solid oxide cells based on proton-conducting electrolytes," Applied Energy, Elsevier, vol. 237(C), pages 924-934.
    9. Luu, Minh Tri & Milani, Dia & Sharma, Manish & Zeaiter, Joseph & Abbas, Ali, 2016. "Model-based analysis of CO2 revalorization for di-methyl ether synthesis driven by solar catalytic reforming," Applied Energy, Elsevier, vol. 177(C), pages 863-878.
    10. Chen, Guanyi & Tao, Junyu & Liu, Caixia & Yan, Beibei & Li, Wanqing & Li, Xiangping, 2017. "Hydrogen production via acetic acid steam reforming: A critical review on catalysts," Renewable and Sustainable Energy Reviews, Elsevier, vol. 79(C), pages 1091-1098.
    11. Wang, Dandan & Li, Sheng & He, Song & Gao, Lin, 2019. "Coal to substitute natural gas based on combined coal-steam gasification and one-step methanation," Applied Energy, Elsevier, vol. 240(C), pages 851-859.
    12. Seadira, Tumelo W.P. & Masuku, Cornelius M. & Scurrell, Michael S., 2020. "Solar photocatalytic glycerol reforming for hydrogen production over Ternary Cu/THS/graphene photocatalyst: Effect of Cu and graphene loading," Renewable Energy, Elsevier, vol. 156(C), pages 84-97.
    13. Lee, Chan Hyun & Lee, Ki Bong, 2017. "Sorption-enhanced water gas shift reaction for high-purity hydrogen production: Application of a Na-Mg double salt-based sorbent and the divided section packing concept," Applied Energy, Elsevier, vol. 205(C), pages 316-322.

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    More about this item

    Keywords

    Water gas shift reaction; Steam reforming; Coal gasification; H2 production;
    All these keywords.

    JEL classification:

    • H2 - Public Economics - - Taxation, Subsidies, and Revenue

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