Toward Off-Grid Photovoltaics-Driven Hydrogen Production: A Conceptual Study on Biomass-Assisted Fe3+/Fe2+ Mediated Co-Electrolysis
Chunhua Zhu, Jie Yao, Meng Du, Henghui Xu, Jintao Yu, Haotian Zhu, Zeyu Zhou, Jubing Zhang

TL;DR
This study explores a new method for low-energy hydrogen production using iron ions and biomass, which could be powered by off-grid solar energy.
Contribution
The study introduces a biomass-assisted Fe3+/Fe2+ mediated co-electrolysis approach to reduce energy consumption in hydrogen production.
Findings
Fe2+ oxidation replaces OER with a much lower initial oxidation potential of 0.5 V.
Chlorella pyrenoidosa achieves a 90.5% Fe3+ reduction rate at 190 °C.
Optimized conditions yield a current density of 280 mA/cm2, higher than similar studies.
Abstract
As a conceptual study for low-energy hydrogen production, potentially coupled with off-grid photovoltaics, this work focuses on overcoming the constraint of the oxygen evolution reaction (OER), which features a high anode potential and significant overpotential. To reduce energy consumption, the Fe2+ oxidation reaction is employed to replace OER, coupled with Fe2+ regeneration using natural biomass. Experimental results reveal that Fe2+ oxidation reaction is an effective substitute, with an initial oxidation potential of 0.5 V (vs. Hg/Hg2SO4), much lower than that of OER. Fe2+ regeneration is notably influenced by both biomass type and reaction temperature. Chlorella pyrenoidosa (CP) achieves the highest Fe3+ reduction rate of 90.5% at 190 °C. Water-soluble organic compounds generated during biomass oxidation exert a negative impact on Fe2+ electrooxidation by accumulating on or coating…
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Taxonomy
TopicsElectrocatalysts for Energy Conversion · Chemical Looping and Thermochemical Processes · Advanced battery technologies research
