Please wait a minute...
 
国土资源遥感  2014, Vol. 26 Issue (3): 16-23    DOI: 10.6046/gtzyyg.2014.03.03
  综述 本期目录 | 过刊浏览 | 高级检索 |
遥感技术在微生物复垦中的应用研究
陈书琳, 毕银丽
中国矿业大学(北京)地球科学与测绘工程学院, 北京 100083
Application of remote sensing technology to microbial reclamation
CHEN Shulin, BI Yinli
College of Geoscience and Surveying Engineering, China University of Mining & Technology, Beijing 100083, China
全文: PDF(786 KB)   HTML  
输出: BibTeX | EndNote (RIS)      
摘要 微生物复垦是矿区生态重建的有效途径。遥感技术特别是高光谱遥感技术可以快速准确地获取微生物复垦后植被的生长状态和土壤性状改良的实时信息,为评估微生物复垦技术对矿区土地恢复和生态重建的作用提供了技术支撑。概述了遥感技术在矿区植被恢复、矿渣石排土场复垦、采矿沉陷地复垦和复垦区重金属污染监测等方面的应用和研究现状,以及微生物技术在改良煤矸石环境、治理采矿沉陷地和修复重金属污染场地中的作用和研究现状,分析了遥感技术应用于监测微生物复垦效果的理论依据,并讨论了今后遥感技术在微生物复垦中的应用潜力,以期为未来快速、准确、无损地监测微生物复垦植被的生长状况提供新方法,并为评价微生物技术在矿区生态重建中的作用提供参考。
服务
把本文推荐给朋友
加入引用管理器
E-mail Alert
RSS
作者相关文章
盖颖颖
周斌
孙元芳
周燕
关键词 溢油HJ-1墨西哥湾纹理特征决策树    
Abstract:Microbial reclamation is an effective means for ecological restoration in coal mining. Remote sensing, especially hyperspectral remote sensing, can rapidly and precisely determine the growth status of plants in the field and the improvement of soil properties, thus providing important technical support for implementation of microbial technology to land restoration and ecological environment rehabilitation in coal mining. This paper summarized in detail the application of remote sensing to monitoring the plants recovery, reclamation of waste dump of tail slag and subsidence and pollution of heavy metals in reclaimed areas, and the application of microbial technology to improving the environment of coal wastes, managing mining subsidence land and restoring land polluted by heavy metals. Some ideas of remote sensing technology applied in microbial reclamation for future research were discussed in this paper, which could provide an important reference and guideline for quick, accurate and undamaged monitoring of growth of plants reclaimed with microorganism and estimation of microbial technology implemented in ecological restoration in coal mining in the future.
Key wordsoil spill    HJ-1    Gulf of Mexico    texture characteristic    decision tree
收稿日期: 2013-09-01      出版日期: 2014-07-01
ZTFLH:  TP79  
  S154  
  O657.3  
基金资助:“十二五”科技支撑计划——晋陕蒙接壤区煤炭基地生态建设关键技术与示范项目(编号:2012BAC10B03)和教育部博士点基金项目(编号:20090023110009)共同资助。
作者简介: 陈书琳(1978-),女,博士研究生,主要从事微生物复垦的高光谱遥感监测研究。Email:chen_sl@163.com。
引用本文:   
陈书琳, 毕银丽. 遥感技术在微生物复垦中的应用研究[J]. 国土资源遥感, 2014, 26(3): 16-23.
CHEN Shulin, BI Yinli. Application of remote sensing technology to microbial reclamation. REMOTE SENSING FOR LAND & RESOURCES, 2014, 26(3): 16-23.
链接本文:  
http://www.gtzyyg.com/CN/10.6046/gtzyyg.2014.03.03      或      http://www.gtzyyg.com/CN/Y2014/V26/I3/16
[1] 苏伟,孙中平,吕海军,等.基于多时相Landsat遥感影像的海州露天煤矿排土场植被时空特征分析[J].生态学报,2009,29(11):5860-6868. Su W,Sun Z P,Lyu H J,et al.Monitoring of temporal and spatial change of vegetation in waste dump of Haizhou opencast coalmine area using multitemporal landsat remote sensing images[J].Acta Ecologica Sinica,2009,29(11):5860-6868.
[2] 孟丹,张志,冯稳.基于GeoEye-1和DEM的富家坞铜矿区固体废弃物危险性分析[J].国土资源遥感,2011,23(2):130-134. Meng D,Zhang Z,Feng W.The risk analysis of solid waste of the Fujawu copper ore district based on GeoEye-1 and DEM[J].Remote Sensing for Land and Resources,2011,23(2):130-134.
[3] 刘广,郭华东,Hanssen R,等.InSAR技术在矿区沉降监测中的应用研究[J].国土资源遥感,2008,20(2):51-55. Liu G,Guo H D,Hanssen R,et al.The application of InSAR technology to mining area subsidence monitoring[J].Remote Sensing for Land and Resources,2008,20(2):51-55.
[4] 卢霞,刘少峰,胡振琪,等.矿区水污染遥感识别研究[J].矿业研究与开发,2006,26(4):89-92. Lu X,Liu S F,Hu Z F,et al.Study on remote sensing identification of water pollution in a mining area[J].Mining Research and Development,2006,26(4):89-92.
[5] 李娜,杨锋杰,吕建升.植物光谱效应在尾矿生态恢复评价中的应用[J].国土资源遥感,2007,19(2):75-77. Li N,Yang F J,Lyu J S.The application of plant spectral effects to the estimation of mining tailing ecological restoration[J].Remote Sensing for Land and Resources,2007,19(2):75-77.
[6] 董霁红,于敏,赵银娣,等.矿区复垦土壤重金属含量分布与光谱特征研究——以徐州市柳新矿区为例[J].中国矿业大学学报,2012,41(5):827-832. Dong J H,Yu M,Zhao Y D,et al.Research on the distribution and spectral characteristics of heavy metal content in reclaimed soil of mining areas:A case study of Liuxin mining district in Xuzhou city[J].Journal of China University of Mining & Technology,2012,41(5):827-832.
[7] 施魁元.高光谱分辨率遥感技术及其在植被监测中的应用[J].黑龙江生态工程职业学院学报,2008,21(5):68-70. Shi K Y.Hyperspectral resolution technology and its application in monitoring plants[J].Journal of Heilongjiang Vocational Institute of Ecological Engineering,2008,21(5):68-70.
[8] Purevdorj T,Tateishi R,Ishiyama T,et al.Relationships between percent vegetation cover and vegetation indices[J].International Journal of Remote Sensing,1998,19(18):3519-3535.
[9] 胡振琪,陈涛.基于ERDAS的矿区植被覆盖度遥感信息提取研究:以陕西省榆林市神府煤矿区为例[J].西北林学院学报,2008,23(2):164-167. Hu Z Q,Chen T.ERDAS aided exbraction of vegetation fraction from remote sensing information in coalmine area based:A case study of Shenfu coalmine[J].Journal of Northwest Forestry University,2008,23(2):164-167.
[10] Arzu erener.Remote sensing of vegetation health for reclaimed areas of Seyitmer open cast coal mine[J].International Journal of Coal Geology,2011,86(1):20-26.
[11] 叶宝莹,白中科,孔登魁,等.安太堡露天煤矿土地破坏与土地复垦动态变化的遥感调查[J].北京科技大学学报,2008,30(9):972-976. Ye B Y,Bai Z K,Kong D K,et al.Dynamic change of land destroy and reclamation on ATB opencast coal mine[J].Journal of University of Science and Technology Beijing,2008,30(9):972-976.
[12] 荆青青,张志,王旭.基于ASTER遥感影像的煤矸石分布信息提取方法[J].煤炭科学技术,2008,36(5):93-96. Jing Q Q,Zhang Z,Wang X.Collecting method of coal refuse distribution information based on ASTER remote sensing images[J].Coal Science and Technology,2008,36(5):93-96.
[13] 韩云霞,李民赞,李道亮.基于光谱学与遥感技术的矿区废弃地土壤特性参数分析[J].吉林大学学报:工学版,2009,39(1):254-258. Han Y X,Li M Z,Li D L.Estimation of soil properties in mine wasteland based on spectroscopy and remote sensing[J].Journal of Jilin University:Engineering and Technology Edition,2009,39(1):254-258.
[14] 郝启勇,韦欣,隋建红,等.基于遥感技术的兖济滕矿区采煤沉陷区现状及动态变化特征[J].山东国土资源,2012,28(5):41-43. Hao Q Y,Wei X,Sui J H,et al.Present condition and dynamic change characteristics of coal mining subsidence areas in Yanjiteng mining areas based on remote sensing technology[J].Land and Resources in Shandong Province,2012,28(5):41-43.
[15] 许长辉,高井祥,王坚,等.多源多时相遥感数据融合在煤矿塌陷地中应用研究[J].水土保持研究,2008,15(1):92-95. Xu C H,Gao J X,Wang J,et al.Application of RS data fusion of multi-source and multi-temporal in coal mine subsidence[J].Research of Soil and Water Conservation,2008,15(1):92-95.
[16] 姚光华,徐升,涂昌鹏.浅谈遥感技术在采煤沉陷区含水层动态分析中的应用[J].中国矿业,2012,21(5):118-121. Yao G H,Xu S,Tu C P.Research thinking of the remote sensing technology in the dynamic analysis of water-bearing zone[J].China Mining Magazine,2012,21(5):118-121.
[17] 于君宝,刘景双,王金达,等.矿山复垦土壤重金属元素时空变化研究[J].水土保持学报,2000,14(4):30-33. Yu J B,Liu J S,Wang J D,et al.Space time variation of heavy metal elements content in covering soil of coal mine reclamation area[J].Journal of Soil and Water Conservation,2000,14(4):30-33.
[18] 谭德军,谢巨天,简季,等.万盛采矿区粉尘污染农作物光谱特性分析[J].国土资源遥感,2013,25(2):121-130. Tan D J,Xie J T,Jian J,et al.Analysis on spectral characteristics of dust polluted crops in Wansheng coal mining district[J].Remote Sensing for Land and Resources,2013,25(2):121-130.
[19] 陈绍杰,陈颖,杜培军,等.基于HJ-1遥感数据的矿区水体污染监测与分析——以龙岩紫金山金铜矿为例[J].测绘,2011,34(6):252-255. Chen S J,Chen Y,Du P J,et al.Monitoring and analyzing of water quality based on HJ-1 satellite remote sensing data[J].Surveying and Mapping,2011,34(6):252-255.
[20] 胡玉玲.基于HJ-1高光谱数据的矿区植被污染监测[D].泰安:山东科技大学,2011. Hu Y L.Vegetation stress level monitoring mining area based on HJ-1 hyperspectral data[D].Taian:Shandong University of Science and Technology,2011.
[21] 马彦卿.微生物复垦技术在矿区生态重建中的应用[J].采矿技术,2001,1(2):66-68. Ma Y Q.Application of microbial reclamation technology to ecological restoration in coal mining area[J].Mining Technology,2001,1(2):66-68.
[22] 毕银丽,胡瑜,苏高华,等.微生物对煤矿固体废弃物的脱硫效应[J].环境工程学报,2008,2(1):92-96. Bi Y L,Hu Y,Su G H,et al.Desulphurization effects of microoganisms on gangue in coal mine areas[J].Chinese Journal of Environmental Engineering,2008,2(1):92-96.
[23] 毕银丽,吴王燕,刘银平.丛枝菌根在煤矸石山土地复垦中的应用[J].生态学报,2007,27(9):3738-3743. Bi Y L,Wu W Y,Liu Y P.Application of arbuscular mycorrhizas in land reclamation of coal spoil heaps[J].Acta Ecologica Sinica,2007,27(9):3738-3743.
[24] 毕银丽,柳博会.煤矸石微生物脱硫试验研究[J].环境污染与防治,2007,29(3):161-164. Bi Y L,Liu B H.Study on microbial desulphurization of coal waste[J].Environmental Pollution & Control,2007,29(3):161-164.
[25] 唐云,杨强,张覃.氧化亚铁硫杆菌浸出高硫煤矸石中硫的试验研究[J].选煤技术,2010,219(2):4-7,78. Tang Y,Yang Q,Zhang Q.Experimental study on using thiobacillus ferrooxidans leaching sulfur from high-sulfur coal gangue[J].Coal Preparation Technology,2010,219(2):4-7,78.
[26] 谢英荷,洪坚平,李青萍,等.在煤矸石风化物和生黄土上种植三叶草接种根瘤菌的效应[J].土壤肥料,1995(1):41-43. Xie Y H,Hong J P,Li Q P,et al.Effect of clover inoculated with Rhizobium planted on coal wastes weathering and loess[J].Soils and Fertilizers,1995(1):41-43.
[27] Feng G,Zhang Y F,Li X L.Effect of external byohae of arbuscular mycorrhizal plant on water-stable aggregates in sandy soil[J].Journal of Soil and Water Conservation,2001,15(4):99-102.
[28] 廖芳芳,郑嵩,葛皓.煤矸石山生态修复方法综述[J].环保科技,2012,18(1):21-25. Liao F F,Zheng S,Ge H.Methods of ecological restoration of coal gangue hill[J].Environmental Protection and Technology,2012,18(1):21-25.
[29] 毕银丽,陈铸,曹楠,等.丛枝菌根对矿区塌陷地环境修复的生态效应[J].中国科技论文在线,2010,5(11):850-854. Bi Y L,Chen Z,Cao N,et al.Ecological effects of arbuscular mycorrhizal fungi on environmental phytoremediation in mining subsided land[J].Sciencepaper Online,2010,5(11):850-854.
[30] 宋晓.采煤沉陷地土地影响及复垦模式初探[J].科技传播,2012(20):135-137,143. Song X.Research on land effect and reclamation pattern of coal mining subsidence[J].Public Communication of Science & Technology,2012(20):135-137,143.
[31] 张合兵,桑振平,李晨.焦作煤矿区开采沉陷地生物复垦技术与试验研究[J].安徽农业科学,2008,36(29):12891-12893. Zhang H B,Sang Z P,Li C.Study on organism reclamation technique of the mining subsidence land in Jiaozuo coal mining area[J].Journal of Anhui Agriculture Science, 2008,36(29):12891-12893.
[32] 杜善周,毕银丽,王义,等.丛枝菌根对神东煤矿区塌陷地的修复作用与生态效应[J].科技导报,2010,28(7):41-44. Du S Z,Bi Y L,Wang Y,et al.The reclamation and ecological effects of arbuscular mycorrhiza on subsided land in Shendong coal mine areas[J].Science & Technology Review,2010,28(7):41-44.
[33] 岳辉,毕银丽,Zhakypbek Y,等.接种菌根对神东矿区采煤沉陷地的生态修复效应[J].科技导报,2012,30(36):56-60. Yue H,Bi Y L,Zhakypbek Y,et al.Ecological reclamation effect of arbuscualr mycorrhizal inoculum on subsided land in the area of Shendong coal mine[J].Science & Technology Review,2012,30(36):56-60.
[34] 杨琳琳,季秀玲,吴潇,等.微生物在成矿及矿区环境修复中的应用研究现状[J].生命科学,2011,23(3):306-310. Yang L L,Ji X L,Wu X,et al.Research status of microbial technology on biomineralization and microbial bioremediation[J].Chinese Bulletin of Life Sciences,2011,23(3):306-310.
[35] Loser C,Zehnsdorf A,Hoffmann P,et al.Remediation of heavy metal polluted sediment by suspension and solid bed leaching:Estimate of metal removal efficiency[J].Chemosphere,2007,66(9):1699-1705.
[36] Yuan H P,Zhang J H,Lu Z M,et al.Studies on biosorption equilibrium and kinetics of Cd2+ by Streptomyces sp.K33and HL-12[J].Journal of Hazardous Materials,2009,164(2/3):423-431.
[37] Papassiopi N,Kontoyianni A,Vaxevanidou K.Assessment of chromium biostabilization in contaminated soils using standard leaching and sequential extraction techniques[J].Science of Total Environment,2009,407(2):925-936.
[38] Charm I S,Kim B H.Effect of sulfate reduction activity on biological treatment of hexavalent chromium[Cr(Ⅵ)]contaminated electroplating waste water under sulfate-rich condition[J].Chemosphere,2007,68(2):218-226.
[39] 孙嘉龙,肖唐付,周连碧,等.微生物与重金属的相互作用机理研究进展[J].地球与环境,2007,35(4):367-374. Sun J L,Xiao T F,Zhou L B,et al.Studies on the mechanisms of interaction between microboes and heavy metals[J].Earth and Environment,2007,35(4):367-374.
[40] Sari A,Tuzen M.Kinetic and equilibrium studies of biosorption of Pb(II) and Cd(II) from aqueous solution by macrofungus(Amanita rubescens)biomass[J].Journal of Hazardous Materials,2009,164(2/3):1004-1011.
[41] Sari A,Tuzen M.Biosorption of As(III)and As(V)from aqueous solution by macrofungus(Inonotus hispidus)biomass:Equilibrium and kinetic studies[J].Journal of Hazardous Materials,2009,164(2/3):1372-1378.
[42] Vazquez S,Agha R,Granado A,et al.Use of white Lupin plant for phytostahilization of Cd and As polluted acid soil[J].Water Air and Soil Pollution,2006,177:349-365.
[43] Conesa M H,Faz A,Arnaldos R.Initial studies for the phytostahilization of a mine tailing from the Cartagena-La Union Mining District(SE Spain)[J].Chemosphere,2006,66(1):38-44.
[44] 高玉倩,张俊英,李富平,等.生物修复矿区铅锌污染研究[J].现代矿业,2012(4):65-67. Gao Y Q,Zhang J Y,Li F P,et al.Research on pollution of lead and zinc in coal mining reclaimed with microboes[J].Modern Mining,2012(4):65-67.
[45] 李自刚,彭爱娟,屈凌波.微生物修复菌剂对复垦金尾矿土壤微生物群落的影响[J].湖南农业科学,2009(5):46-49. Li Z G,Peng A J,Qu L B.Effects of microbial remediation inocula on microbial community in gold-tailings soil with secondary tillage[J].Hunan Agricultural Sciences,2009(5):46-49.
[46] 郭友红.微生物对煤矿区适生植物污染修复的作用[J].北方园艺,2012(17):65-67. Guo Y H.Effect of microorganisms on pollution restoration of suitable plants in coal mine[J].Northern Horticulture,2012(17):65-67.
[47] 刘晓娜,赵中秋.螯合剂、菌根联合植物修复重金属污染土壤研究进展[J].环境科学与技术,2011,34(12):127-133. Liu X N,Zhao Z Q.Chelate,Mycorrhiza and plants joint remediation of heavy metal contaminated soil[J].Environmental Science & Technology,2011,34(12):127-133.
[48] 董明,王冬梅,王晓英.菌根菌在植物修复重金属污染土壤中的作用[J].华北农学报,2010,25(s1):250-253. Dong M,Wang D M,Wang X Y.The role of mycorrhizal fungi of plant repair heavy metal contaminated soil[J].Acta Agriculturae Boreali-Sinica,2010,25(s1):250-253.
[49] 任红艳,潘剑君,张佳宝.高光谱遥感技术的铅污染监测应用研究[J].遥感信息,2005(3):34-38. Ren H Y,Pan J J,Zhang J B.Hyper-spectral application to monitoring plumbum pollution of vegetation[J].Remote Sensing Information,2005(3):34-38.
[1] 邓刚,唐志光,李朝奎,陈浩,彭焕华,王晓茹. 基于MODIS时序数据的湖南省水稻种植面积提取及时空变化分析[J]. 国土资源遥感, 2020, 32(2): 177-185.
[2] 夏既胜,马梦莹,符钟壬. 基于GF-2遥感影像的机械性破损面提取方法[J]. 国土资源遥感, 2020, 32(2): 26-32.
[3] 樊宪磊,阎宏波,瞿瑛. 基于HJ-1A/B CCD地表反照率估算方法比较与验证[J]. 国土资源遥感, 2019, 31(3): 123-131.
[4] 马超,杨飞,王学成. 基于中尺度光谱和时序物候特征提取南方丘陵山区茶园[J]. 国土资源遥感, 2019, 31(1): 141-148.
[5] 国贤玉,李坤,王志勇,李宏宇,杨知. 基于SVM+SFS策略的多时相紧致极化SAR水稻精细分类[J]. 国土资源遥感, 2018, 30(4): 20-27.
[6] 赵菲菲, 包妮沙, 吴立新, 孙瑞. 国产HJ-1B卫星数据的地表温度及湿度反演方法——以呼伦贝尔草原伊敏露天煤矿区为例[J]. 国土资源遥感, 2017, 29(3): 1-9.
[7] 王玉, 付梅臣, 王力, 王长耀. 基于多源高分卫星影像的果棉套种信息提取[J]. 国土资源遥感, 2017, 29(2): 152-159.
[8] 陶婷, 阮仁宗, 岁秀珍, 王玉强, 林鹏. 基于HyMap数据的浮水植被信息提取[J]. 国土资源遥感, 2017, 29(2): 187-192.
[9] 苏腾飞, 张圣微, 李洪玉. 基于纹理特征与区域生长的高分辨率遥感影像分割算法[J]. 国土资源遥感, 2017, 29(2): 72-81.
[10] 胡华龙, 薛武, 秦志远. 基于小波纹理和基元合并的高分影像居民地提取[J]. 国土资源遥感, 2017, 29(1): 21-28.
[11] 王瑾杰, 丁建丽, 张成, 陈文倩. 基于GF-1卫星影像的改进SWI水体提取方法[J]. 国土资源遥感, 2017, 29(1): 29-35.
[12] 项盛文, 文贡坚, 高峰. 知识驱动下的飞机目标变化检测方法[J]. 国土资源遥感, 2016, 28(4): 77-82.
[13] 孙宇翼, 赵军利, 王苗苗, 刘勇. 基于J48决策树的面向对象方法的土地覆被信息提取[J]. 国土资源遥感, 2016, 28(4): 156-163.
[14] 鹿丰玲, 巩在武. 基于随机森林算法构建云-云阴影-水体掩模[J]. 国土资源遥感, 2016, 28(3): 73-79.
[15] 刘威, 赵文杰, 李成, 李婷, 谭海峰, 马扬铭. 基于中心对称局部相似数量模型的均值漂移目标跟踪[J]. 国土资源遥感, 2016, 28(3): 37-45.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
京ICP备05055290号-2
版权所有 © 2015 《自然资源遥感》编辑部
地址:北京学院路31号中国国土资源航空物探遥感中心 邮编:100083
电话:010-62060291/62060292 E-mail:zrzyyg@163.com
本系统由北京玛格泰克科技发展有限公司设计开发