[1] Liu W-P (刘维屏). Environmental Chemistry of Pesticide. Beijing: Chemical Industry Press, 2006 (in Chinese) [2] Loos M, Krauss M, Fenner K. Pesticide nonextractable residue formation in soil: Insights from inverse modeling of degradation time series. Environmental Science & Technology, 2012, 46: 9830-9837 [3] Mamy L, Patureau D, Barriuso E, et al. Prediction of the fate of organic compounds in the environment from their molecular properties: A review. Critical Reviews in Environmental Science and Technology, 2015, 45: 1277-1377 [4] Postigo C, Barceló D. Synthetic organic compounds and their transformation products in groundwater: Occurrence, fate and mitigation. Science of the Total Environment, 2015, 503: 32-47 [5] Schuhmann A, Gans O, Weiss S, et al. A long-term lysimeter experiment to investigate the environmental dispersion of the herbicide chloridazon and its metabolites-comparison of lysimeter types. Journal of Soils and Sediments, 2016, 16: 1032-1045 [6] Masutti CSM, Mermut AR. Degradation of fipronil under laboratory conditions in a tropical soil from sirinhaem pernambuco, Brazil. Journal of Environmental Science and Health Part B, 2007, 42: 33-43 [7] Zhang X (张 昕), Zhang B-X (张炳欣), Zhao Y-H (赵宇华), et al. Ecological effects of multifunctional micro-flora agent in environment. Chinese Journal of Applied Ecology (应用生态学报), 2005, 16(10): 1909-1912 (in Chinese) [8] Wang G-L (王光利), Chen H-H (陈宏宏), Bi M (毕 萌), et al. Bioremediation of chlorothalonil-contaminated soil by utilizing Pseudomonas sp. strain CTN-3. Chinese Journal of Applied Ecology (应用生态学报), 2012, 23(3): 807-811 (in Chinese) [9] Hangler M, Jensen B. Inducible hydroxylation and de-methylation of the herbicide isoproturon by Cunninghamella and elegans. FEMS Microbiology Letters, 2007, 268: 254-260 [10] Benimeli CS, Amoroso MJ, Chaile AP, et al. Isolation of four streptomycetes strains capable of growth on organochlorine pesticides. Bioresource Technology, 2003, 89: 133-138 [11] Mostafa FLY, Helling CS. Isoproturon degradation as affected by the growth of two algal species at different concentrations and pH values. Journal of Environmental Science and Health Part B, 2001, 36: 709-727 [12] Hong W-L (洪文良), Wu X-M (吴小毛). Study on degradation characteristics of napropamide in tobacco soils. Guizhou Agricultural Sciences (贵州农业科学), 2012, 40(6): 201-206 (in Chinese) [13] Hong W-L (洪文良), Wu X-M (吴小毛). Effect of napropamide on soil microorganism population quantity and their biological activity. Guizhou Agricultural Sciences (贵州农业科学), 2013, 41(2): 120-l23 (in Chinese) [14] Ma A-J (马爱军), He R-H (何任红), Zhou L-X (周立祥). Behavior and mechanism of napropamide adsorption in soil-water environment. Acta Scientiae Circumstantiae (环境科学学报), 2007, 26(7): 1159-1163 (in Chinese) [15] Guo H (郭 华), Zhu H-M (朱红梅), Yang H (杨红). Degradation and adsorption behavior of napropamide in soils. Environmental Science (环境科学), 2008, 29(6): 1729-1736 (in Chinese) [16] Kim YK. Adsorption, desorption and movement of napropamide in soils. Journal of Civil Engineering, 2004, 8: 619-623 [17] Zhang R, Cui J, Zhu HM, et al. Effect of dissolved organic matters on napropamide availability and ecotoxicity in rapeseed (Brassica napus). Journal of Agricultural and Food Chemistry, 2010, 58: 3232-3240 [18] Walker A, Parekh NR, Roberts SJ, et al. Evidence for the enhanced biodegradation of napropamide in soil. Pesticide Science, 1993, 39: 55-60 [19] Walker A, Welch SJ, Roberts SJ. Induction and transfer of enhanced biodegradation of the herbicide napropamide in soils. Pesticide Science, 1996, 47: 131-135 [20] He L-J (何丽娟), Li Z-H (李正华), Hong Q (洪青), et al. Characterization of a phenanthrene-degrading strain and cloning of degradation-related gene. Chinese Journal of Applied and Environmental Biology (应用与环境生物学报), 2009, 15(5): 682-685 (in Chinese) [21] Dong X-Z (东秀珠), Cai M-Y (蔡妙英). Handbook of Common Bacteria Identification. Beijing: Science Press, 2001 (in Chinese) [22] Weisburg WG, Barns SM, Pelletier DA, et al. 16S ribosomal DNA amplification for phylogenetic study. Journal of Bacteriology, 1991, 173: 697-703 [23] Wang X-D (王学东). Study on Degradation and Meta-bolism of Herbicide in Non-cultivated Land. Ph D. Hang-zhou: Zhejiang University, 2003 (in Chinese) [24] Li S-B (李淑彬), Chen Z-J (陈振军), Qiu L-L (丘李莉), et al. Isolation and identification of Bacillus cereus strain Jp-A and its capability inphenol degradation. Chinese Journal of Applied Ecology (应用生态学报), 2006, 17(5): 920-924 (in Chinese) [25] Yu Y-L (虞云龙), Pan X-D (潘学冬), Chen Y-X (陈英旭). Dynamics of butachlor biodegradation in the root-zone soils and the soil inoculated with a mixture HD of bacterial strains dengrading butachlor. Acta Pedologica Sinica (土壤学报), 2002, 39(4): 575-581 (in Chinese) [26] Hong Y-C (洪永聪), Xin W (辛 伟), Cui D-J (崔德杰), et al. Characteristics of cypermethr in degrading enzymes secreted by Bacillus cereus strain TR2. Journal of Qingdao Agricultural University (青岛农业大学学报), 2007, 24(3): 185-188 (in Chinese) [27] Gao Q (高 强), Deng L-F (邓灵福), Zheng Y-L (郑永良), et al. Study on isolating and characterizing HS-MP12 a strain capable of degrading methyl para-thion. Journal of Safety and Environment (安全与环境学报), 2007, 7(3): 22-25 (in Chinese) [28] Yang C, Dong M, Yuan Y, et al. Reductive transformation of parathion and methyl parathion by Bacillus sp. Biotechnology Letters, 2007, 29: 487-493 [29] Singh BK, Walker A, Wright DJ. Bioremedial potential of fenamiphos and chlorpyrifos degrading isolates: Influence of different environmental conditions. Soil Biology and Biochemistry, 2006, 38: 2682-2693 [30] Yang C, Wang Y, Li J. Plant species mediate rhizosphere microbial activity and biodegradation dynamics in a riparian soil treated with bensulfuron-methyl. Clean: Soil, Air, Water, 2011, 39: 338-344 |