Monometallic nano-catalysts for the reduction of perchlorate in water

2007 Cleantech Conference and Trade Show Cleantech 2007 Pub Date : 2019-01-01 DOI:10.1201/9780429187469-66

D. M. Wang, H. Lin, C. Huang

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Abstract

Perchlorate removal in a clean, cost-effective and publicly acceptable approach is one of the important issues in current drinking water treatment practice. Catalytic membrane (CM) was prepared by coating monometallic catalysts of the nano-size onto supports by chemical or electrochemical method. The support materials were stainless steel and graphite. Nano-catalysts were made of transitional metals from the first, the second and the third row of the periodic table. The CM was characterized by surface analysis techniques including SEM, XPS and BET. The CM was used as cathode where the reduction of perchlorate occurred through hydrogen atoms that were generated on the CM surface. All experiments were performed at ambient conditions. It was found that for the first time perchlorate could be reduced readily by hydrogen atoms in the presence of catalyst. At a maximum perchlorate concentration of 100 mg/L, it is possible to achieve a > 90% removal in 8 h using nano-catalysts such as Sn, Ti, and Co. The rate constants were between 5.1 and 9.6 μM-L -1 -hr -1 among the 18 different monometallic nanocatalysts tested. Chloride was the major end product, whereas a small quantity of chlorite was observed in the presence of Co catalyst. Membrane coated with metallic nano-catalysts at different mass showed different reduction rate, e.g., the optimum surface coverage for Sn was 0.6 to 0.7 mg per gram stainless steel membrane.

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还原水中高氯酸盐的单金属纳米催化剂

以清洁、经济、可接受的方法去除高氯酸盐是当前饮用水处理实践中的重要问题之一。采用化学或电化学方法将纳米尺度的单金属催化剂涂覆在载体上，制备了催化膜。支撑材料为不锈钢和石墨。纳米催化剂由元素周期表第一、第二和第三行过渡金属制成。采用SEM、XPS和BET等表面分析技术对其进行表征。CM用作阴极，高氯酸盐通过CM表面生成的氢原子进行还原。所有实验均在环境条件下进行。研究首次发现，高氯酸盐在催化剂的作用下容易被氢原子还原。在高氯酸盐最大浓度为100 mg/L的条件下，采用Sn、Ti、Co等纳米催化剂可在8 h内达到> ~ 90%的去除率。18种不同的单金属纳米催化剂的速率常数在5.1 ~ 9.6 μM-L -1 -hr -1之间。氯化物是主要的最终产物，而在Co催化剂存在下观察到少量亚氯酸盐。不同质量的金属纳米催化剂对膜的还原率不同，不锈钢膜对Sn的最佳表面覆盖率为0.6 ~ 0.7 mg / g。

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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2007 Cleantech Conference and Trade Show Cleantech 2007

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