Removal Efficiency and Mechanism for Cl- from Strongly Acidic Wastewater by VC-Assisted Cu2O: Comparison Between Synthesis Methods.
Ying Yu, Dong Li, Jialin Ma, Zhoujing Yan, Haoran Liu, Wenyue Dou, Haotian Hao
Abstract
Open AccessThe discharge of strongly acidic industrial wastewater containing high concentration of chloride ions (Cl-) has become one of the major environmental challenges faced globally. For the removal of extremely stable Cl- in acidic aqueous conditions, precipitation method possesses major advantages of strong adaptability and simple operation. This study proposed a novel cuprous oxide (Cu2O) method assisted by ascorbic acid (VC) for the removal of Cl- from strongly acidic wastewater. First, liquid-phase reduction was chosen as the optimal Cu2O synthesis method based on product purity and composition. Then, parameter optimization results show that increased reagent dosage and acidity significantly enhanced Cl- removal efficiency, while other factors had negligible impacts. After treatment with the sole addition of Cu2O, the dosed Cu2O existed in four forms, including cuprous chloride (CuCl), copper ion (Cu2+), elemental copper (Cu0), and Cu2O, among which the generation of Cu2+ and Cu0, through the oxidation and disproportionation of cuprous ion (Cu+), served as the main reason for the unsatisfactory efficiency in the removal of Cl-. Fortunately, VC is precisely capable of inhibiting the side reactions of Cu+, and under the assistance of 0.10 g VC, the removal of Cl- by Cu2O was greatly improved with the multiple of theoretical reagent dosage decreasing from 12 to 3, the residual concentration of Cu2+ decreasing from 1197 to 18.4 mg/L and the residual concentration of Cl- decreasing from 88.4 to 53.8 mg/L, thus validating the feasibility of this method.