Arsenite-arsenate separation analysis technique using anion exchange resin

Journal of groundwater hydrology Pub Date : 2020-02-28 DOI:10.5917/jagh.62.75

H. Sugita, Terumi Oguma, Ming Zhang, J. Hara, Y. Kawabe

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Abstract

Arsenite-arsenate separation analysis technique using a commercial anion exchange resin column with quaternary ammonium cations as anion exchange groups was studied. The selection of the optimum conditions for the valence-dependent separation of inorganic arsenic and the influence of coexisting anions were examined experimentally. By calculation based on the first dissociation constants of arsenite and arsenate, the optimum pH range of the test solution for valence separation of arsenic was estimated to be 4.3 to 7.1. When the test solution adjusted to the above pH was passed through the column, the arsenic in the test solution was separated appropriately by valence, because the arsenite is not adsorbed and the arsenate is adsorbed on the resin. Also, the arsenate adsorbed on the resin could be easily recovered almost completely by using HCl or HNO 3. The strength of the inhibition effect of coexisting anions on the recovery of arsenic was clarified to be “CH 3COO<< Cl < NO 3 < SO 4”. The arsenite-arsenate separation analysis technique proposed in this study separated and recovered arsenite and arsenate with an experimental error of about 6% under the experimental conditions.

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阴离子交换树脂分离砷酸盐分析技术

研究了以季铵盐阳离子为阴离子交换基团的商业阴离子交换树脂分离分析亚砷酸盐的技术。实验考察了无机砷价依赖分离的最佳条件的选择和共存阴离子的影响。根据亚砷酸盐和砷酸盐的第一解离常数计算，估计出砷价分离试验溶液的最佳pH范围为4.3 ~ 7.1。当调整到上述pH值的测试溶液通过柱时，由于砷酸盐不吸附，砷酸盐吸附在树脂上，因此测试溶液中的砷被价态适当分离。此外，吸附在树脂上的砷酸盐可以很容易地被HCl或hno3完全回收。共存阴离子对砷回收的抑制强度为“CH 3COO<< Cl < no3 < so4”。本研究提出的亚砷酸盐分离分析技术在实验条件下分离回收亚砷酸盐和砷酸盐，实验误差约为6%。

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Journal of groundwater hydrology

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