Copper, Iron and Aluminium Electrochemical Corrosion Investigation during Electrolysis and Temperature Increasing

Q4 Physics and Astronomy
M. Yarmolenko, Sergii O. Mogilei
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Abstract

An experimental method to calculate average charge of metal ions by electrolysis at different temperatures is proposed. Aluminium undergoes dissolution to the Al3+ ions at all temperatures. Iron undergoes dissolution to the Fe2+ or the Fe3+ ions and copper undergoes dissolution to the Cu+ or the Cu2+. It depends on temperature and electric current density. Direct electric current value and anode mass decreasing were measured during electrolysis into concentrated NaCl solution in water (5 mol/kg or 23.1%, freezing point equals -22°C, pH 6.5–7.5) at room temperature and 100°C. The average charges of copper, iron, and aluminium ions were calculated using Faraday’s law of electrolysis at electric current density 3,000 A/m2 (or 30 A/dm2): +3 for aluminium; +2 for iron; and +1 for copper at room temperature, and +3 for aluminium; +2 for iron; and +1.5 for copper at temperature 100°C. The main condition was zAl=3. We concluded that calculations of the average metal ions charges, zFe and zCu, were correct since zAl=3. The result is as follows: the Al3+, the Fe2+, and the Cu+ ions dissolve into concentrated NaCl solution in water at room temperature; the Al3+, the Fe2+, the Cu+ and the Cu2+ ions (50%/50%) dissolve into the solution at temperature 100°C. We have obtained experimentally and by mathematical modelling that aluminium anodes (cylindrical or spherical) dissolve into the solution more rapidly with temperature increasing during electrolysis accordingly to the Arrhenius law, while copper anodes (cylindrical or spherical) dissolve more slowly with temperature increasing from room temperature to temperature 180°C like “inverse Arrhenius law”. Iron electrochemical corrosion rate practically does not depend on temperature below 100°C (and, obviously, up to 180°C) like “zeroth Arrhenius law”. The spherical anode effect is greater than the cylindrical anode effect in 1.5 times.
电解和升温过程中铜、铁和铝的电化学腐蚀研究
本文提出了一种通过电解计算不同温度下金属离子平均电荷的实验方法。铝在所有温度下都会溶解为 Al3+ 离子。铁溶解为 Fe2+ 或 Fe3+ 离子,铜溶解为 Cu+ 或 Cu2+。这取决于温度和电流密度。在室温和 100°C 下电解浓 NaCl 水溶液(5 mol/kg 或 23.1%,凝固点等于 -22°C,pH 值 6.5-7.5)时,测量了直接电流值和阳极质量的减少。在电流密度为 3,000 A/m2 (或 30 A/dm2 )时,利用法拉第电解定律计算出铜、铁和铝离子的平均电荷:室温下,铝为 +3;铁为 +2;铜为 +1;100°C 时,铝为 +3;铁为 +2;铜为 +1.5。主要条件是 zAl=3。我们得出结论,由于zAl=3,金属离子平均电荷zFe 和 zCu 的计算是正确的。结果如下:Al3+、Fe2+ 和 Cu+ 离子溶解在室温下的浓 NaCl 水溶液中;Al3+、Fe2+、Cu+ 和 Cu2+ 离子(50%/50%)溶解在温度为 100°C 的溶液中。我们通过实验和数学建模得出,根据阿伦尼乌斯定律,铝阳极(圆柱形或球形)在电解过程中会随着温度的升高而更快地溶解到溶液中,而铜阳极(圆柱形或球形)则会随着温度从室温升高到 180°C 而更慢地溶解到溶液中,就像 "阿伦尼乌斯逆定律 "一样。铁的电化学腐蚀速率在 100°C 以下(显然在 180°C 以下)实际上与温度无关,就像 "零阿伦尼乌斯定律 "一样。球形阳极效应比圆柱阳极效应大 1.5 倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Defect and Diffusion Forum
Defect and Diffusion Forum Physics and Astronomy-Radiation
CiteScore
1.20
自引率
0.00%
发文量
127
期刊介绍: Defect and Diffusion Forum (formerly Part A of ''''Diffusion and Defect Data'''') is designed for publication of up-to-date scientific research and applied aspects in the area of formation and dissemination of defects in solid materials, including the phenomena of diffusion. In addition to the traditional topic of mass diffusion, the journal is open to papers from the area of heat transfer in solids, liquids and gases, materials and substances. All papers are peer-reviewed and edited. Members of Editorial Boards and Associate Editors are invited to submit papers for publication in “Defect and Diffusion Forum” . Authors retain the right to publish an extended and significantly updated version in another periodical.
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