污染性油泥中石油烃降解菌的分离与鉴定
|
摘要
石油开采过程中会产生大量有毒的含油污泥,严重污染环境。拟从2个不同油田的含油污泥中分离出高效石油烃降解菌,以期获得具有普适性、可强化生物降解的基础菌剂来经济高效地处理油泥。从2个油田共分离出3株石油烃降解菌1-A1、2-B1和2-B2,经鉴定分别为戴尔夫特菌(Delftia sp.)、寡养单胞菌(Stenotrophomonas sp.)和芽孢杆菌(Bacillus sp.),3株菌在48 h内生长趋势相同。石油烃降解性能测定表明,菌株1-A1、2-B1和2-B2均能高效降解石油烃,48 h内降解率分别为73. 42%、90. 9%和80. 48%。表明可从油泥中获得石油烃降解菌作为油泥生物修复的基础菌剂,为未来油泥的微生物修复提供了一定的科学依据。
A large amount of toxic contaminated oil sludge will be generated in the process of oil extraction,causing heavy pollution to the surrounding environment. In order to treat the contaminated oil sludge in an efficient and low-cost way,we planned to separate highefficiency hydrocarbon degradation bacteria from contaminated oil sludge samples in two different regional oilfields in this study,and expected to obtain adaptable and biodegradable basic microbial agents. In this paper,three hydrocarbon degradation bacteria 1-A1,2-B1 and 2-B2 were isolated from two oilfields,which were identified as Delftia sp.,Stenotrophomonas sp.,and Bacillus sp. These three strains showed the same growth trend within 48 hours. 1-A1,2-B1 and 2-B2 could degrade petroleum hydrocarbon efficiently,and the degradation rates within 48 hours were 73. 42%,90. 9% and 80. 48%,respectively.
A large amount of toxic contaminated oil sludge will be generated in the process of oil extraction,causing heavy pollution to the surrounding environment. In order to treat the contaminated oil sludge in an efficient and low-cost way,we planned to separate highefficiency hydrocarbon degradation bacteria from contaminated oil sludge samples in two different regional oilfields in this study,and expected to obtain adaptable and biodegradable basic microbial agents. In this paper,three hydrocarbon degradation bacteria 1-A1,2-B1 and 2-B2 were isolated from two oilfields,which were identified as Delftia sp.,Stenotrophomonas sp.,and Bacillus sp. These three strains showed the same growth trend within 48 hours. 1-A1,2-B1 and 2-B2 could degrade petroleum hydrocarbon efficiently,and the degradation rates within 48 hours were 73. 42%,90. 9% and 80. 48%,respectively.
引文
[1] Chagasspinelli A C,Kato M T,de Lima E S,et al. Bioremediation of a tropical clay soil contaminated with diesel oil[J]. Journal of Environmental Management,2012,113(1):510-516.
[2]詹研.中国土壤石油污染的危害及治理对策[J].环境污染与防治,2008,30(3):91-93.
[3] Ward O, Singh A, Van H J. Accelerated biodegradation of petroleum hydrocarbon waste[J]. Journal of Industrial Microbiology&Biotechnology,2003,30(5):260-270.
[4] Marín J A,Moreno J L,Hernández T,et al. Bioremediation by composting of heavy oil refinery sludge in semiarid conditions[J].Biodegradation,2006,17(3):251-261.
[5]王玉华,陈传帅,孟娟,等.含油污泥处置技术的新发展及其应用现状[J].安全与环境工程,2018,25(3):103-110.
[6]江闯,赵宁华,魏宏斌,等.类芬顿氧化法处理TPH污染土壤的试验研究[J].中国给水排水,2018(3):97-99.
[7]李燕妮.细菌菌群降解石油的影响因素及应用研究[D].天津:天津理工大学,2013.
[8] Maddela N R, Scalvenzi L, Venkateswarlu K. Microbial degradation of total petroleum hydrocarbons in crude oil:a fieldscale study at the low-land rainforest of Ecuador[J]. Environmental Technology,2017,38(20):1-8.
[9]刘晓春,阎光绪,郭绍辉,等.微生物降解土壤中石油污染物的研究进展[J].污染防治技术,2007,20(6):51-54.
[10]姜海荣,倪永清,宋丽军,等.新鲜哈密瓜汁中可培养细菌的分离鉴定及系统发育分析[J].食品与生物技术学报,2010,29(3):426-431.
[11]曾润颖,赵晶.深海细菌的分子鉴定分类[J].微生物学通报,2002,29(6):12-16.
[12]许甜甜,陈军. Sphingobium sp.和Delftia sp.复合降解苯酚的研究[J].上海师范大学学报(自然科学版),2012,41(1):94-98.
[13]肖诚斌,宁君,闫海,等.新筛选菌种Delftia sp. XYJ5生物降解苯胺的途径[J].中国化学工程学报(英文版),2009,17(3):500-505.
[14]武洪杰,谭周亮,刘庆华,等.一株高浓度苯胺、苯酚降解菌的分离鉴定及降解特性[J].应用与环境生物学报,2010,16(2):252-255.
[15]肖建军,李亚龙,杨琦.寡养单胞菌降解石油污染土壤中的甲苯[J].环境工程,2018(4):186-189.
[16]郑金秀,张甲耀,赵晴,等.高效石油降解菌的选育及其降解特性研究[J].环境科学与技术,2006,29(3):1-2.
[17]李宝.油泥的微生物修复实验研究——以河南双河油田为例[D].北京:中国石油大学(北京),2005.
[18] Varjani S J. Microbial Degradation of Petroleum Hydrocarbons[J].Bioresource Technology,2016,223:277-286.
[2]詹研.中国土壤石油污染的危害及治理对策[J].环境污染与防治,2008,30(3):91-93.
[3] Ward O, Singh A, Van H J. Accelerated biodegradation of petroleum hydrocarbon waste[J]. Journal of Industrial Microbiology&Biotechnology,2003,30(5):260-270.
[4] Marín J A,Moreno J L,Hernández T,et al. Bioremediation by composting of heavy oil refinery sludge in semiarid conditions[J].Biodegradation,2006,17(3):251-261.
[5]王玉华,陈传帅,孟娟,等.含油污泥处置技术的新发展及其应用现状[J].安全与环境工程,2018,25(3):103-110.
[6]江闯,赵宁华,魏宏斌,等.类芬顿氧化法处理TPH污染土壤的试验研究[J].中国给水排水,2018(3):97-99.
[7]李燕妮.细菌菌群降解石油的影响因素及应用研究[D].天津:天津理工大学,2013.
[8] Maddela N R, Scalvenzi L, Venkateswarlu K. Microbial degradation of total petroleum hydrocarbons in crude oil:a fieldscale study at the low-land rainforest of Ecuador[J]. Environmental Technology,2017,38(20):1-8.
[9]刘晓春,阎光绪,郭绍辉,等.微生物降解土壤中石油污染物的研究进展[J].污染防治技术,2007,20(6):51-54.
[10]姜海荣,倪永清,宋丽军,等.新鲜哈密瓜汁中可培养细菌的分离鉴定及系统发育分析[J].食品与生物技术学报,2010,29(3):426-431.
[11]曾润颖,赵晶.深海细菌的分子鉴定分类[J].微生物学通报,2002,29(6):12-16.
[12]许甜甜,陈军. Sphingobium sp.和Delftia sp.复合降解苯酚的研究[J].上海师范大学学报(自然科学版),2012,41(1):94-98.
[13]肖诚斌,宁君,闫海,等.新筛选菌种Delftia sp. XYJ5生物降解苯胺的途径[J].中国化学工程学报(英文版),2009,17(3):500-505.
[14]武洪杰,谭周亮,刘庆华,等.一株高浓度苯胺、苯酚降解菌的分离鉴定及降解特性[J].应用与环境生物学报,2010,16(2):252-255.
[15]肖建军,李亚龙,杨琦.寡养单胞菌降解石油污染土壤中的甲苯[J].环境工程,2018(4):186-189.
[16]郑金秀,张甲耀,赵晴,等.高效石油降解菌的选育及其降解特性研究[J].环境科学与技术,2006,29(3):1-2.
[17]李宝.油泥的微生物修复实验研究——以河南双河油田为例[D].北京:中国石油大学(北京),2005.
[18] Varjani S J. Microbial Degradation of Petroleum Hydrocarbons[J].Bioresource Technology,2016,223:277-286.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |