Abstract:Traditional tin electrorefining proceeds in electrolyte containing H₂SO₄, SnSO₄ and cresol sulfonic acid (CSA). It is urgent to search novel environmental electrolyte additive to replace CSA due to its stench and toxicity. Influences of CSA and gallic acid (GA) on electrolyte stability and Sn(II) electrodeposit behavior were comparatively investigated through linear scanning voltammetry, Tafel test, titration analysis and SEM. The results show that GA presents stronger reducibility than that CSA does, and remarkably inhibits hydrogen evolution side reaction. Addition of GA stabilizes electrolyte acidity, and enhances Sn(II) concentration and Sn(II)/Sn(T) ratio. Compared with CSA, GA is more suitable to enhance electrolyte stability. Addition of CSA apparently inhibits Sn(II) electrodeposition and increases cathodic polarization. Therefore, CSA presents excellent flattening effect. However, GA shows smaller influence on Sn(II) electrodeposition dynamic, and decreases the flatness and compactness of cathodic tin. Moreover, addition of GA in high concentration results in the appearance of tin dendrites. Sodium ligninsulfonate (SL), as a leveling agent, is selected and combined with GA. Composite additive of SL and GA is demonstrated to improve compactness and flatness of cathodic tin. Consequently, SL-GA composite additive is a potential alternative to CAS. It could be a novel environmental-friendly additive for tin electrorefining.

Key words: tin electrorefining; cresol sulfonic acid; gallic acid; sodium ligninsulfonate; stability; morphology