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Analysis of the Main Hydrogen Production Technologies

Author

Listed:
  • Juan Taumaturgo Medina Collana

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

  • Luis Carrasco-Venegas

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

  • Carlos Ancieta-Dextre

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

  • Oscar Rodriguez-Taranco

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

  • Denis Gabriel-Hurtado

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

  • Jorge Montaño-Pisfil

    (Faculty of Electrical and Electronic Engineering, Renewable Energy and Hydrogen Research Center Universidad Nacional del Callao, Callao 07011, Peru)

  • Cesar Rodriguez-Aburto

    (Faculty of Electrical and Electronic Engineering, Renewable Energy and Hydrogen Research Center Universidad Nacional del Callao, Callao 07011, Peru)

  • Wilmer Chávez-Sánchez

    (Faculty of Electrical and Electronic Engineering, Renewable Energy and Hydrogen Research Center Universidad Nacional del Callao, Callao 07011, Peru)

  • Cesar Santos-Mejía

    (Faculty of Electrical and Electronic Engineering, Renewable Energy and Hydrogen Research Center Universidad Nacional del Callao, Callao 07011, Peru)

  • Pablo Morcillo-Valdivia

    (Faculty of Electrical and Electronic Engineering, Renewable Energy and Hydrogen Research Center Universidad Nacional del Callao, Callao 07011, Peru)

  • Nelson Herrera-Espinoza

    (Faculty of Chemical Engineering, Research Center for Water Treatment Processes Engineering, National University of Callao, Juan Pablo II 306 Avenue, Bellavista 07011, Peru)

Abstract

Hydrogen, as a clean energy source, has enormous potential in addressing global climate change and energy security challenges. This paper discusses different hydrogen production methodologies (steam methane reforming and water electrolysis), focusing on the electrolysis process as the most promising method for industrial-scale hydrogen generation. The review delved into three main electrolysis methods, including alkaline water electrolysis, proton exchange membrane electrolysis, and anion exchange membrane electrolysis cells. Also, the production of hydrogen as a by-product by means of membrane cells and mercury cells. The process of reforming natural gas (mainly methane) using steam is currently the predominant technique, comprising approximately 96% of the world’s hydrogen synthesis. However, it is carbon intensive and therefore not sustainable over time. Water, as a renewable resource, carbon-free and rich in hydrogen (11.11%), offers one of the best solutions to replace hydrogen production from fossil fuels by decomposing water. This article highlights the fundamental principles of electrolysis, recent membrane studies, and operating parameters for hydrogen production. The study also shows the amount of pollutant emissions (g of CO 2 /g of H 2 ) associated with a hydrogen color attribute. The integration of water electrolysis with renewable energy sources constitutes an efficient and sustainable strategy in the production of green hydrogen, minimizing environmental impact and optimizing the use of clean energy resources.

Suggested Citation

  • Juan Taumaturgo Medina Collana & Luis Carrasco-Venegas & Carlos Ancieta-Dextre & Oscar Rodriguez-Taranco & Denis Gabriel-Hurtado & Jorge Montaño-Pisfil & Cesar Rodriguez-Aburto & Wilmer Chávez-Sánchez, 2025. "Analysis of the Main Hydrogen Production Technologies," Sustainability, MDPI, vol. 17(18), pages 1-30, September.
    • Handle: RePEc:gam:jsusta:v:17:y:2025:i:18:p:8367-:d:1752195
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    References listed on IDEAS

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    1. Squadrito, Gaetano & Maggio, Gaetano & Nicita, Agatino, 2023. "The green hydrogen revolution," Renewable Energy, Elsevier, vol. 216(C).
    2. Ana P. R. A. Ferreira & Raisa C. P. Oliveira & Maria Margarida Mateus & Diogo M. F. Santos, 2023. "A Review of the Use of Electrolytic Cells for Energy and Environmental Applications," Energies, MDPI, vol. 16(4), pages 1-33, February.
    3. Andrea Dumančić & Nela Vlahinić & Minea Skok, 2024. "Replacing Gray Hydrogen with Renewable Hydrogen at the Consumption Location Using the Example of the Existing Fertilizer Plant," Sustainability, MDPI, vol. 16(15), pages 1-33, July.
    4. Leiming Wang & Wei Liu & Haipeng Sun & Li Yang & Liang Huang, 2024. "Advancements and Policy Implications of Green Hydrogen Production from Renewable Sources," Energies, MDPI, vol. 17(14), pages 1-14, July.
    5. Can Yin & Lifu Jin, 2025. "Estimating Hydrogen Price Based on Combined Machine Learning Models by 2060: Especially Comparing Regional Variations in China," Sustainability, MDPI, vol. 17(3), pages 1-16, January.
    6. Xi Yang & Chris P. Nielsen & Shaojie Song & Michael B. McElroy, 2022. "Breaking the hard-to-abate bottleneck in China’s path to carbon neutrality with clean hydrogen," Nature Energy, Nature, vol. 7(10), pages 955-965, October.
    7. Behgol Bagheri & Hiromu Kumagai & Michio Hashimoto & Masakazu Sugiyama, 2025. "Techno-Economic Assessment of Green Hydrogen Production in Australia Using Off-Grid Hybrid Resources of Solar and Wind," Energies, MDPI, vol. 18(13), pages 1-18, June.
    8. Cátia Ribeiro & Diogo M. F. Santos, 2025. "Transitioning Ammonia Production: Green Hydrogen-Based Haber–Bosch and Emerging Nitrogen Reduction Technologies," Clean Technol., MDPI, vol. 7(2), pages 1-26, June.
    9. Seyed Mehdi Alizadeh & Yasin Khalili & Mohammad Ahmadi, 2024. "Comprehensive Review of Carbon Capture and Storage Integration in Hydrogen Production: Opportunities, Challenges, and Future Perspectives," Energies, MDPI, vol. 17(21), pages 1-35, October.
    10. Xu, Boshi & Yang, Yang & Li, Jun & Ye, Dingding & Wang, Yang & Zhang, Liang & Zhu, Xun & Liao, Qiang, 2024. "A comprehensive study of parameters distribution in a short PEM water electrolyzer stack utilizing a full-scale multi-physics model," Energy, Elsevier, vol. 300(C).
    11. Ning Lin & Mariam Arzumanyan & Edna Rodriguez Calzado & Jean-Philippe Nicot, 2025. "Water Requirements for Hydrogen Production: Assessing Future Demand and Impacts on Texas Water Resources," Sustainability, MDPI, vol. 17(2), pages 1-25, January.
    12. Katharina Hembach-Stunden & Maximilian Banning & Lisa Becker & Christian Lutz & Patrick Matschoss & Uwe Klann & Juri Horst, 2024. "Future Installation, Production and Global Trade of Clean Energy Technologies," Sustainability, MDPI, vol. 16(23), pages 1-25, November.
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