生物海绵铁体系降解硝基苯的特性及机理初探

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摘要

采用硝基苯（NB）模拟废水对生物海绵铁体系进行驯化，考察了NB初始浓度、海绵铁投加量、初始pH值、温度等因素对生物海绵铁体系降解NB的影响，初步探讨了生物海绵铁体系高效降解NB的机理.结果表明：生物海绵铁体系较普通活性污泥系统对NB适应性及氧化作用更强，驯化至第28d对300mg/L NB废水去除率稳定在98%以上，驯化周期比普通活性污泥体系缩短28d；海绵铁的加入大大促进了微生物对NB的降解，NB初始浓度及pH值对生物海绵铁体系降解速率影响较大，该体系适宜的温度范围较广，10~40℃均能高效降解NB，生物海绵铁体系对NB的降解符合零级反应动力学规律；生物海绵铁体系中活性氧化物（ROS）含量明显高于海绵铁体系及污泥体系，尤其是介入铁泥的生物海绵铁体系ROS含量更高，为体系发生较强类Fenton效应提供了条件.在实验确定的最佳工况下，经NB驯化的铁泥与海绵铁形成的生物海绵铁体系，NB降解速率为31.49min^-1，6hNB降解率及TOC去除率分别高达92.0%和63.1%，较单独海绵铁体系与单独铁泥体系降解率的叠加值分别高出22.3%和11.4%.本研究为经济有效地处理NB废水提供了新思路.

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	郑莹
	牟彪
	王萍
	王亚娥
	李杰

关键词 ：硝基苯, 海绵铁, 类Fenton效应, 铁细菌

Abstract：

The biological sponge iron system was acclimated by nitrobenzene simulated wastewater in present study. Meanwhile, the mechanism and the effects of systemic conditions, such as initial concentration of nitrobenzene, sponge iron dosage, initial pH value and temperature, on the degradation of nitrobenzene by domesticated sponge iron system were investigated. The results showed that:compared with the activated sludge system, the biological sponge iron system had a better adaptability and oxidability for degradation of nitrobenzene. The removal rate of nitrobenzene was more than 98% with initial concentration of nitrobenzene at 300mg/L when the biological sponge iron system domesticated to 28th day, and the acclimation cycles was shortened by 28days compared with the activated sludge system. The addition of sponge iron can improve the degradation rate of microbial system. The initial concentration of nitrobenzene and the pH value have an obvious influence on the degradation rate of the system. The suitable temperature range was wider. It can efficiently degrade nitrobenzene from 10 to 40℃. The degradation reaction of nitrobenzene by biological sponge iron system followed zero-order kinetics model. The content of reactive oxygen species (ROS) in the biological sponge system, especially inoculated with iron sludge, was significantly higher than that of in the sponge iron system and the sludge system, which provided stronger Fenton-like effect. Under the optimum conditions, the degradation of nitrobenzene in the biological sponge iron system inoculated with domesticated iron sludge was 31.5min^-1. Besides, the degradation rate of nitrobenzene and TOC were 92.0% and 63.1% respectively, which were 22.3% and 11.4% higher than the superposed values for degradation rates of nitrobenzene in sponge iron system and in iron sludge system alone. This study provides a new idea to treat nitrobenzene wastewater efficiently and economically.

Key words： nitrobenzene sponge iron fenton-like effect iron bacteria

收稿日期: 2018-12-13

X703

基金资助:

国家自然科学基金资助项目（51468030）

通讯作者: 王亚娥,教授,wye@mail.Lzjtu.cn E-mail: wye@mail.Lzjtu.cn

作者简介: 郑莹(1993-),女,江西宜春人,兰州交通大学硕士研究生,研究方向为水污染控制.

引用本文:

郑莹, 牟彪, 王萍, 王亚娥, 李杰. 生物海绵铁体系降解硝基苯的特性及机理初探[J]. 中国环境科学, 2018, 38(7): 2535-2541. ZHENG Ying, MU Biao, WANG Ping, WANG Ya-e, LI Jie. Preliminary investigation on degradation characteristics and mechanism of nitrobenzene by biological sponge iron system. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(7): 2535-2541.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2018/V38/I7/2535

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