氢
无机化学
电解质
制氢
电化学
溶解
阴极保护
阳极
金属
铝
电极
化学
极化(电化学)
阴极
电凝
材料科学
可逆氢电极
冶金
镁
过氧化氢
硫酸盐
电解水
过渡金属
限制电流
化学工程
化学反应
析氧
电催化剂
作者
Meysam Rahmanian,Nael G. Yasri,Edward P.L. Roberts
出处
期刊:ACS ES&T water
[American Chemical Society]
日期:2026-02-04
卷期号:6 (2): 922-935
标识
DOI:10.1021/acsestwater.5c01000
摘要
Understanding hydrogen evolution in electrocoagulation remains challenging because most studies have not simultaneously quantified gas production and metal dissolution, limiting mechanistic insight into super-faradaic behavior. We investigate aluminum and iron electrodes under galvanostatic and potentiodynamic conditions, measuring the hydrogen production and metal dissolution rates. Iron is included as a baseline as its near-faradaic behavior enables validation of the experimental method. Simultaneous evaluation of cathodic and anodic processes revealed distinct electrode behaviors. Aluminum cathodes exhibited super-faradaic hydrogen evolution, reaching 2.5–3× theoretical values at low current densities (0.1–2.0 mA cm –2 ), while anodic hydrogen generation occurred only in chloride-containing electrolytes. Electrolyte composition strongly modulated aluminum: cathodic hydrogen was enhanced in NaCl and Na 2 SO 4, moderate in synthetic groundwater (SGW), and suppressed in NaNO 3, while anodic hydrogen appeared only in NaCl and SGW and was nearly absent in sulfate and nitrate due to passivation. Dissolved Al and an Al-assisted Volmer–Heyrovský pathway, where one electron is supplied electrochemically and the other by Al, explain the excess hydrogen and cathodic Al dissolution. Comparison of hydrogen evolution rates with polarization currents confirmed that combined electrochemical and chemical pathways drive aluminum’s super-faradaic behavior. These results clarify the combination of electrochemical and chemical reactions as the origin of aluminum’s anomalous efficiencies.
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