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Journal of Electrochemical Science and Engineering, Vol. 16 , 2026.

Pregledni rad

https://doi.org/10.5599/jese.3045

Ultrasound-enhanced water electrolysis for hydrogen production: Mechanisms, metrology and energy metrics

ChenHongWen Zeng ; School of Mechanical Engineering, Universiti Sains Malaysia, Engineering Campus, Nibong Tebal 14300, Penang, Malaysia *
Yew Heng Teoh ; School of Mechanical Engineering, Universiti Sains Malaysia, Engineering Campus, Nibong Tebal 14300, Penang, Malaysia
Heoy Geok How ; Department of Engineering, School of Engineering, Computing and Built Environment, UOW Malaysia KDU Penang University College, 32, Jalan Anson, 10400 Georgetown, Penang, Malaysia
Mohamad Yusof Idroas ; School of Mechanical Engineering, Universiti Sains Malaysia, Engineering Campus, Nibong Tebal 14300, Penang, Malaysia
Thanh Danh Le ; College of Technology and Design, University of Economics Ho Chi Minh City (UEH), 59C Nguyen Dinh Chieu Street, Xuan Hoa Ward, Ho Chi Minh City 700000, VietNam

* Dopisni autor.

Puni tekst: engleski pdf 1.118 Kb

preuzimanja: 499

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Sažetak

Ultrasound intensifies hydrogen production in water electrolysis cells by thinning boun­dary layers, accelerating bubble detachment, and, in tuned windows, modulating cavi­tation chemistry, yet cross-study claims remain difficult to compare. Focusing on ultra­sound-enhanced water electrolysis (sono-electrolysis), this review aligns reporting with IEC 61161 (radiation-force acoustic power) and IEC 62127-2:2025 (hydrophone calibra­tion); requires delivered acoustic intensity at the electrode, Idel / W·cm⁻², with stated trace­ability; pairs isothermal control with uncertainty budgets; and benchmarks perfor­mance using Δ-metrics: Δj (current-density gain at fixed cell voltage), Δη (cell voltage/over­po­tential reduction at fixed current density) and ΔHPR (hydrogen production rate gain at matched electrical input), together with specific energy consumption (SEC, kWh·kg⁻¹ H₂). A window-based synthesis indicates that, under isothermal operation, 20 to 40 kHz with delivered intensity ≈0.2 to 1.0 W·cm⁻² reproducibly yields Δj ≈ 15 to 30 %, Δη ≈ 40 to 120 mV, ΔHPR ≈ 10 to 30 %, and net SEC improvements of ~8 to 12 % when auxiliary loads are included, whereas at higher dose (Idel ≈ 1.0 to 1.6 W·cm⁻²) non-uniform fields, cloud shielding, and heating can saturate or reverse benefits. To prevent metric conflation, hybrid sono-hydrogen routes are reviewed separately. The review concludes by proposing a minimum reporting set-frequency, waveform/duty and pulse repetition frequency, Idel (traceability/uncertainty), geometry/stand-off, electrolyte and dissolved gas, bulk tempe­rature and runtime, gas metrology with temperature/pressure cor­rections, SEC boun­daries and replicates/statistics, and by outlining priorities for operando cavitation-electro­chemistry co-registration, geometry/void-fraction-aware scale-up, and durability under combined fields, to support reproducible, energy-accounted, and comparable studies across laboratories.
 

Ključne riječi

Sono-electrolysis; acoustic cavitation; hybrid sono-hydrogen systems

Hrčak ID:

344848

URI

https://hrcak.srce.hr/344848

Datum izdavanja:

20.1.2026.

Posjeta: 706 *