菌株M降解硝基苯的特性及动力学研究

中国农学通报 ›› 2011, Vol. 27 ›› Issue (24): 277-281.

菌株M降解硝基苯的特性及动力学研究

颜立敏杨春艳徐炎华

收稿日期:2011-04-29 修回日期:2011-06-14 出版日期:2011-09-25 发布日期:2011-09-25

The Study on Characteristic and Kinetic of Nitrobenzene Biodegradation by Strain M

Received:2011-04-29 Revised:2011-06-14 Online:2011-09-25 Published:2011-09-25

摘要/Abstract

摘要：

从受硝基苯污染的土壤筛选出能以硝基苯为唯一碳源菌株M，其最佳培养条件：pH值为7，温度30℃，摇床转速200 r/min，接种量10%（v/v）。在此最佳条件下，考察了菌株M对硝基苯浓度的耐受性、降解动力学、培养基的TOC和生物毒性。菌株M对硝基苯的最大耐受浓度为900 mg/L。300 mg/L的硝基苯经菌株M降解后的代谢产物的TOC从1400 mg/L降到400 mg/L，生物毒性在12 h内逐渐降低直至无毒。当硝基苯浓度≤415.92 mg/L时，菌株M降解硝基苯符合零级动力学方程。菌株M对硝基苯的降解也符合Andrews抑制模型，模型参数分别为qmax=60 h-1，Ks=100 mg/L，Ki＝350 mg/L。

关键词: 水葫芦, 水葫芦, 固碳机理, 厌氧发酵, 两阶段模型

Abstract:

A strain named as M, which can use nitrobenzene as a sole carbon source, was screened from the nitrobenzene contaminated soil. The optimum culture condition of stain M was pH 7, temperature 30℃, rotation speed 200 r/min and inoculated volume of M 10% (v/v). The tolerance concentration, biodegradation kinetics, the TOC and biotoxicity of metabolite of nitrobenzene of strain M were studied under the optimum condition. The highest tolerance concentration of nitrobenzene was 900 mg/L. In the degradation process for 300 mg/L nitrobenzene, the TOC decreased from 1400 mg/L to 400mg/L and the biotoxicity of the metabolite decreased gradually till nontoxic within 12 h. The degradation kinetics of strain M was well fit with zero-level kinetic equation when the concentration of nitrobenzene was less than 415.92 mg/L. Meantime, the degradation kinetics of strain M was well fit with Andrews kinetic model with qmax=60 h-1, Ks=100 mg/L, Ki＝350 mg/L.

颜立敏杨春艳徐炎华. 菌株M降解硝基苯的特性及动力学研究[J]. 中国农学通报, 2011, 27(24): 277-281.

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