Effects of sulfide on sulfate reducing bacteria in response to Cu(II), Hg(II) and Cr(VI) toxicity 被引量：3

Effects of sulfide on sulfate reducing bacteria in response to Cu(II), Hg(II) and Cr(VI) toxicity

导出

摘要 Sulfate reducing bacteria (SRB) is identified as the primary organisms responsible for the treatment of heavy metal wastewater. However, most heavy metals can inhibit the growth of SRB during heavy metal treatment processes. Sulfide is a metabolic product of SRB and it can precipitate or reduce heavy metals. This study focused on the effects of sulfide on SRB resistance to Cu(II), Hg(I) and Cr(VI) toxicity. First, we considered the existence style of various heavy metals with and without sulfide addition by sequential extraction experiments. Second, the particle size distribution was evaluated and the cell structure during the metabolism of a SRB culture, containing different heavy metals, was analyzed by particle size distribution and TEM analyses. Third, the evolution of sulfate under the influence of different concentrations of heavy metals with and without sulfide addition was investigated to evaluate SRB activity. The results indicated that sulfide played an important role in alleviating and even eliminating the toxicity of Cu(II), Hg(II) and Cr(VI). We also discuss the mechanism of sulfide on SRB resistance to Cu(II), Hg(I) and Cr(VI) toxicity. Sulfate reducing bacteria (SRB) is identified as the primary organisms responsible for the treatment of heavy metal wastewater. However, most heavy metals can inhibit the growth of SRB during heavy metal treatment processes. Sulfide is a metabolic product of SRB and it can precipitate or reduce heavy metals. This study focused on the effects of sulfide on SRB resistance to Cu(Ⅱ), Hg(I) and Cr(VI) toxicity. First, we considered the existence style of various heavy metals with and without sulfide addition by sequential extraction experiments. Second, the particle size distribution was evaluated and the cell structure during the metabolism of a SRB culture, containing different heavy metals, was analyzed by particle size distribution and TEM analyses. Third, the evolution of sulfate under the influence of different concentrations of heavy metals with and without sulfide addition was investigated to evaluate SRB activity. The results indicated that sulfide played an important role in alleviating and even eliminating the toxicity of Cu(Ⅱ), Hg(Ⅱ) and Cr(VI). We also discuss the mechanism of sulfide on SRB resistance to Cu(Ⅱ), Hg(I) and Cr(VI) toxicity.

作者 SHENG YuXing CAO HongBin LI YuPing ZHANG Yi

机构地区 National Engineering Laboratory for Hydrometallurgical Cleaner Production Technology Key Laboratory of Green Process and Engineering

出处《Chinese Science Bulletin》 SCIE EI CAS 2011年第9期862-868,共7页

基金 supported by the National Natural Science Foundation of China (20877075) the National High-Technology R&D Program of China (2006BAC02A05) the National Key Basic Research Program of China (2007CB613501)

关键词硫酸盐还原菌 CR(VI) 汞毒性硫化铜金属硫化物铬(VI) 作者废水生物处理 sulfide heavy metal toxicity sulfate reducing bacteria copper chromium mercury

分类号 X172 [环境科学与工程—环境科学]

引文网络
相关文献

参考文献22

1Sampaio R M M, Timmers R A, Xu Y, et al. Selective precipitition of Cu from Zn in a pS controlled continuously stirred tank reactor. J Hazard Mater, 2009, 165:256-265.
2Glombitza F. Treatment of acid lignite mine flooding water by means of microbial sulfate reduction. Waste Manage, 2001, 21:197-203.
3Tabak H H, Scharp R, Burckle J, et al. Advances in biotreatment of acid mine drainage and biorecovery of metals: 1. Metal precipitation for recovery and recycle. Biodegradation, 2003, 14:423--436.
4Foucher S, Battaglia-Brunet F, Ignatiadis I, et al. Treatment by sulfate-reducing bacteria of Chessy acid-mine drainage and metals recovery. Chem Eng Sci, 2001, 56:1639-1645.
5Tatsunori N, Satoshi H, Aldhiko M, et al. Distribution and diversity of thermophilic sulfate-reducing bacteria within a Cu-Pb-Zn mine (Toyoha, Japan). FEMS Microbiol Ecol, 2002, 41:199-209.
6Sierra-Alvarez R, Karri S, Freeman S, et al. Biological treatment of heavy metals in acid mine drainage using sulfate reducing bioreactors. Water Sci Technol, 2006, 54:179-185.
7Fang H H P, Xu L C, Chan K Y. Effects of toxic metals and chemicals on biofilm and biocorrosion. Water Res, 2002, 36:4709-4716.
8Poulson S R, Colbery P J S, Drever J I. Toxicity of heavy metals(Ni, Zn) to Desulfovibrio desulfuricals. Geomicrobiol J, 1997, 14:41-49.
9Olive J H, Li H G, Jin M C. Effects of metal additions on sulfate reduction activity in wastewaters. Toxicol Environ Chem, 1994, 46:197-212.
10Mafia T A, Carla C, Bo M. Precipitation of Zn(II), Cu(II) and Pb(II) at bench-scale using biogenic hydrogen sulfide from the utilization of volatile fatty acids. Chemosphere, 2007, 66:1677-1683.

同被引文献15

1陈守煜.工程可变模糊集理论与模型——模糊水文水资源学数学基础[J].大连理工大学学报,2005,45(2):308-312. 被引量：213
2朱文杰,汪杰,陈晓耘,扎西次仁,杨韵,宋瑛.发光细菌一新种──青海弧菌[J].海洋与湖沼,1994,25(3):273-279. 被引量：76
3陈守煜,李敏.基于可变模糊集理论的水资源可再生能力评价模型[J].水利学报,2006,37(4):431-435. 被引量：55
4陆坤明.WHO《饮用水水质准则》第3版(2004)“水安全计划”简介[J].净水技术,2006,25(6):21-26. 被引量：26
5常文越,陈晓东,王磊.土著微生物修复铬(Ⅵ)污染土壤的条件实验研究[J].环境保护科学,2007,33(1):42-44. 被引量：11
6Hong Wang Xue Jiang Wang Jian Fu Zhao Ling Chen.Toxicity assessment of heavy metals and organic compounds using CellSense biosensor with E.coli[J].Chinese Chemical Letters,2008,19(2):211-214. 被引量：15
7Ahmed Zahoor,Abdul Rehman.Isolation of Cr(Ⅵ) reducing bacteria from industrial effuents and their potential use in bioremediation of chromium containing wastewater[J].Journal of Environmental Sciences,2009,21(6):814-820. 被引量：18
8LIU RuiPing QU JiuHui.Control of health risks in drinking water through point-of-use systems[J].Chinese Science Bulletin,2009,54(12):1996-2001. 被引量：4
9陈燕飞.pH对微生物的影响[J].太原师范学院学报（自然科学版）,2009,8(3):121-124. 被引量：93
10许友泽,杨志辉,向仁军.铬污染土壤的微生物修复[J].环境化学,2011,30(2):555-560. 被引量：25

引证文献3

1SHI JianSheng,MA Rong,LIU JiChao,ZHANG YiLong.Suitability assessment of deep groundwater for drinking, irrigation and industrial purposes in Jiaozuo City, Henan Province, north China[J].Chinese Science Bulletin,2013,58(25):3098-3110. 被引量：2
2程潜,高宇,朱振宇,胡婷婷,嵇宏杰,杨宇.Cr(Ⅵ)污染的微生物修复技术及研究进展[J].环境污染与防治,2018,40(9):1068-1073. 被引量：1
3王丹,周彦宏,白林明,延卫,李珊珊.明亮发光杆菌培养的响应面优化及其对常见金属离子的毒性评价研究[J].环境科学学报,2022,42(5):454-464.

二级引证文献3

1Lin Xueyu.A small but important step to enhance groundwater research in China[J].Chinese Science Bulletin,2013,58(25):3043-3043.
2Fengshan Ma,Aihua Wei,Qinghai Deng,Haijun Zhao.Hydrochemical Characteristics and the Suitability of Groundwater in the Coastal Region of Tangshan, China[J].Journal of Earth Science,2014,25(6):1067-1075. 被引量：8
3何雨江,陈德文,张成,袁广祥.土壤重金属铬污染修复技术的研究进展[J].安全与环境工程,2020,27(3):126-132. 被引量：16

1唐文伟,曾新平,顾国维.乳化液废水湿式氧化后SBR处理研究[J].环境科学,2007,28(9):1993-1997. 被引量：5
2确定环境中汞污染的来源[J].环境污染与防治,2008,30(3):106-107.
3江英.确定环境中汞污染的来源[J].中国环境科学,2008,28(4):374-374.
4王婷,周俊,徐为中,张雪英.生长因子对SRB处理硫酸盐废水的影响研究[J].工业水处理,2016,36(6):38-42. 被引量：6
5陈涛,陈薇薇,孙成勋.硫酸盐还原菌(SRB)厌氧生物技术处理脱硫废水的可行性探讨[J].中国农村水利水电,2014(2):18-22. 被引量：18
6汪爱河,胡凯光,廖建军,熊日新.硫酸盐还原菌处理重金属废水研究进展[J].湿法冶金,2006,25(4):172-174. 被引量：4
7崔梅.双硫腙比色法测定汞[J].环境与发展,2011,23(9):199-199. 被引量：10
8蒋梦,王迪,刘潇威.水中汞形态分析研究进展[J].环境科学与技术,2011,34(S2):123-126. 被引量：3
9曹慧泉,李广敏,颜慧成,罗登,仇圣桃,夏政海.低碳贝氏体钢中硫化物的析出行为[J].钢铁研究学报,2010,22(3):56-60. 被引量：2
10王雄,吴昌华,利锋,段志鹏,曾祥云,陈亚灵,王旭光.垃圾焚烧发电厂周边甲基汞浓度分布特征及风险评估[J].环境科学与技术,2013,36(10):197-204. 被引量：1

Chinese Science Bulletin

2011年第9期

浏览历史

内容加载中请稍等...

Effects of sulfide on sulfate reducing bacteria in response to Cu(II), Hg(II) and Cr(VI) toxicity 被引量：3

参考文献22

同被引文献15

引证文献3

二级引证文献3

相关作者

相关机构

相关主题

浏览历史