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臭氧氧化分解饮用水中嗅味物质2-甲基异莰醇 被引量:34

Removal of 2-Methylisoborneol in Drinking Water by Ozonation
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摘要 比较了几种常见氧化剂对饮用水中嗅味物质2甲基异莰醇(2-methyli soborneol,MIB)的氧化去除效果.结果表明,KMn04、NaClO、H2O2等氧化剂的氧化作用对水中MIB的去除效果均较差,而臭氧却能有效地将其氧化;考察了pH对臭氧化去除MIB的影响规律,发现pH在7.0~10.0条件下,随着pH值增加MIB去除率增加,但当pH达到10.0左右时,MIB的去除率反而下降;MIB的臭氧化去除效果随着自由基捕获剂(重碳酸盐和叔丁醇)的浓度增加而明显地降低,说明臭氧化去除水中MIB主要遵循自由基作用机理;以松花江江水为本底进行试验和与蒸馏水进行试验的结果相差不大,原因可能是由于松花江水体中碳酸盐浓度较低(小于50mg/L),对自由基捕获能力较小,同时江水中的部分腐殖质(NOM)对臭氧去除MIB的过程起到了促进作用. The removal efficiencies of 2 methylisoborneol(MIB) by KMnO4, NaCIO, H2O2, O3 were compared, and it was found that ozone was the most effective oxidant for MIB removal. By investigating the factors of the removal of MIB by ozone, it was found that the removal of MIB increased with pH increase. And MIB was removed more than 90% after 20min when pH was 7.0- 10.0. But MIB removal efficiency decreased when pH reached 10.0. However, it decreased in the presence of bicarbonate and tert butanol that scavenge 'OH in water. It indicated that MIB degradation mainly followed radical mechanism. The removal efficiency of MIB in Songhua River was almost the same as the results obtained in distilled water. One possible reason is that the carbonate concentration is low(less than 50 mg/L), in that way, 'OH may be less scavenged. Also, NOM may promote the removal of MIB by ozone in Songhua River.
作者 马军 李学艳 陈忠林 齐飞
机构地区 哈尔滨工业大学市政环境工程学院
出处 《环境科学》 EI CAS CSCD 北大核心 2006年第12期2483-2487,共5页 Environmental Science
基金 国家自然科学基金项目(50378028)
关键词 嗅味物质 2-甲基异莰醇 臭氧 羟基自由基 饮用水 taste and odor 2-methylisoborneol ozone hydroxyl radical drinking water
分类号 X52 [环境科学与工程—环境工程] TU991.2 [建筑科学—市政工程]
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参考文献13

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引证文献34

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环境科学
2006年 第12期

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