COMPREHENSIVE STUDY OF ELECTROLYTE TYPE, ELECTRODE MATERIAL, AND SYSTEM EFFICIENCY IN SOLAR-POWERED ALKALINE WATER ELECTROLYSIS FOR HYDROGEN PRODUCTION

Authors

  • Bakhramov Sh.K. Andijan State Technical Institute, Andijan, Uzbekistan
  • Ibrohimov O.B. Andijan State Technical Institute, Andijan, Uzbekistan 2nd-year students (group 21-24)
  • Keldiboyev I.I. Andijan State Technical Institute, Andijan, Uzbekistan 2nd-year students (group 21-24)
  • Yunusov Kh.F. Andijan State Technical Institute, Andijan, Uzbekistan 1st-year student (group 59-25)
  • Bakhramov Sh.K Andijan State Technical Institute, Andijan, Uzbekistan

DOI:

https://doi.org/10.37547/

Keywords:

alkaline electrolysis, KOH, NaOH, electrode material, Ni-Mo alloy, NiFe oxide, MPPT, solar energy, hydrogen production, efficiency.

Abstract

This paper presents the combined results of three interrelated studies: (1) the effect of electrolyte type — KOH, NaOH, and K₂CO₃ — on hydrogen production in an alkaline electrolyzer; (2) the effect of electrode material — 316L stainless steel, pure Ni, Ni-Mo alloy, NiFe oxide, and Ni-Mo/NiFe composite — on electrochemical efficiency; and (3) an overall system efficiency analysis of a photovoltaic (PV) array integrated with an alkaline electrolyzer via an MPPT controller. Experimental results show that 30% KOH provides the highest ionic conductivity (620 mS/cm), while the Ni-Mo/NiFe composite electrode achieves the lowest overpotential. Combined with an MPPT controller, a 5 kW PV system can produce 160–180 kg of green hydrogen per year under Andijan, Uzbekistan climatic conditions.

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References

[1] IEA. Global Hydrogen Review 2023. International Energy Agency, Paris, 2023. 245 p.

[2] Zeng K., Zhang D. Recent progress in alkaline water electrolysis for hydrogen production and applications. Progress in Energy and Combustion Science. 2010; 36: 307–326.

[3] Republic of Uzbekistan. Presidential Decree No. PD-60 "On the Concept of Development of the Energy Sector of the Republic of Uzbekistan". Tashkent, 18 April 2023.

[4] Pletcher D., Li X. Prospects for alkaline zero gap water electrolysers for hydrogen production. International Journal of Hydrogen Energy. 2011; 36(23): 15089–15104.

[5] Schalenbach M. et al. Acidic or alkaline? Towards a new perspective on the efficiency of water electrolysis. Journal of The Electrochemical Society. 2016; 163(11): F3197–F3208.

[6] Gong M. et al. Nanoscale nickel oxide/nickel heterostructures for active hydrogen evolution electrocatalysis. Nature Communications. 2014; 5: 4695.

[7] Terlouw T. et al. Large-scale hydrogen production via water electrolysis: a techno-economic and environmental assessment. Energy & Environmental Science. 2022; 15: 3583–3602.

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Published

2026-06-25

Issue

Vol. 6 No. 6 (2026): International Bulletin of Applied Science and Technology

Section

Articles

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How to Cite

COMPREHENSIVE STUDY OF ELECTROLYTE TYPE, ELECTRODE MATERIAL, AND SYSTEM EFFICIENCY IN SOLAR-POWERED ALKALINE WATER ELECTROLYSIS FOR HYDROGEN PRODUCTION. (2026). International Bulletin of Applied Science and Technology, 6(6), 600-603. https://doi.org/10.37547/

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