化学
吸附
水溶液
硫代硫酸盐
活性炭
无机化学
弗伦德利希方程
亚铁氰化钾
亚铁氰化物
核化学
离子交换
碳纤维
氰化物
动力学
朗缪尔吸附模型
吸附
铜
金属
离子强度
离子
有机化学
物理化学
电极
硫黄
复合数
材料科学
复合材料
作者
Hong Yu,Futing Zi,Xianzhi Hu,Yanhe Nie,Pengzhi Xiang,Jiao Xu,Heng Chi
标识
DOI:10.1016/j.hydromet.2015.04.009
摘要
In this technical note, the adsorption of the gold–thiosulfate complex ion ([Au(S2O3)2]3 −) on cupric ferrocyanide (CuFC)-impregnated activated carbon in aqueous solutions was investigated to identify a better adsorbent for the gold thiosulfate process. This study was performed using cupric ferrocyanide (CuFC)-impregnated activated carbon (AC-CuFC) and an artificial, aqueous solution of [Au(S2O3)2]3 −. Variation in major factors was investigated for the determination of the appropriate dosages of cupric salts, potassium ferrocyanide, impregnation time and roasting temperature to obtain a high recovery of gold from simulated thiosulfate leach solutions. The experimental results have shown that [Au(S2O3)2]3 − strongly adsorbs onto the AC-CuFC and the adsorption capacity of [Au(S2O3)2]3 − on the AC-CuFC in aqueous solution increased with increasing temperature, leading to a gold adsorption capacity for AC-CuFC of 1.474 kg/t at a gold concentration of 100 mg/L at 30 °C. It was determined that the adsorption followed the Freundlich isotherm well, and a pseudo-second order kinetic model is suitable for the adsorption kinetic. That finding indicates that the gold adsorption is multimolecular chemical adsorption. EDX and FTIR suggested that the adsorption process consisted of two steps: first, [Au(S2O3)2]3 − diffused to the surface of AC-CuFC, and ion-exchange reaction for Au and Cu happened, then Au(I) was likely reduced to native gold by carbon or [Fe(CN)6]4 −.
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