[1]郑志林,罗有发,周佳佳,等.铅锌废渣堆场4种先锋修复植物根际微域磷素赋存形态特征[J].水土保持研究,2019,26(03):269-278.
 ZHENG Zhilin,LUO Youfa,ZHOU Jiajia,et al.The Fraction Characteristics of Phosphorus in the Rhizosphere of Four Pioneer Restoration Plants in Lead-Zinc Waste Slag Yards[J].Research of Soil and Water Conservation,2019,26(03):269-278.
点击复制

铅锌废渣堆场4种先锋修复植物根际微域磷素赋存形态特征

参考文献/References:

[1] Hedo J, Lucas-Borja M E, Wic C, et al. Soil microbiological properties and enzymatic activities of long-term post-fire recovery in dry and semiarid Aleppo pine(Pinus halepensis M.)forest stands[J]. Solid Earth,2015,6(1):243-252.
[2] 吴攀,刘丛强,杨元根,等.土法炼锌废渣堆中的重金属及其释放规律[J].中国环境科学,2002,22(2):109-113.
[3] Yang S X, Li J T, Yang B, et al. Effectiveness of amendments on re-acidification and heavy metal immobilization in an extremely acidic mine soil[J]. Journal of Environmental Monitoring,2011,13(7):1876-1883.
[4] Bradshaw A. Restoration of mined lands-using natural processes[J]. Ecological Engineering,1997,8(4):255-269.
[5] Wong M H. Ecological restoration of mine degraded soils, with emphasis on metal contaminated soils[J]. Chemosphere,2003,50(6):775-780.
[6] Mendez M O, Maier R M. Phytoremediation of mine tailings in temperate and arid environments[J]. Reviews in Environmental Science and Bio/Technology,2008,7(1):47-59.
[7] Goloran J B, Chen C, Phillips I R, et al. Shifts in leaf N:P stoichiometry during rehabilitation in highly alkaline bauxite processing residue sand[J]. Scientific Reports,2015,5:14811.
[8] Jones B E H, Haynes R J, Phillips I R. Cation and anion leaching and growth of Acacia saligna in bauxite residue sand amended with residue mud, poultry manure and phosphogypsum[J]. Environmental Science and Pollution Research,2012,19(3):835-846.
[9] Luo Y F, Wu Y G, Wang H, et al. Bacterial community structure and diversity responses to the direct revegetation of an artisanal zinc smelting slag after 5 years[J]. Environmental Science and Pollution Research,2018,25(15):14773-14788.
[10] 安宗胜,詹婧,孙庆业.自然植物群落形成过程中铜尾矿废弃地氮素组分的变化[J].生态学报,2010,30(21):5958-5966.
[11] 任冠举,孙庆业,安树青,等.不同植物群落下酸化尾矿养分状况及土壤酶活性[J].生态学杂志,2006,25(4):379-382.
[12] Yang S X, Cao J B, Li F M, et al. Field evaluation of the effectiveness of three industrial by-products as organic amendments for phytostabilization of a Pb/Zn mine tailings[J]. Environmental Science:Processes & Impacts,2016,18(1):95-103.
[13] Lei D M, Duan C Q. Restoration potential of pioneer plants growing on lead-zinc mine tailings in Lanping, southwest China[J]. Journal of Environmental Sciences,2008,20(10):1202-1209.
[14] Pardo T, Bernal M P, Clemente R. Phytostabilisation of severely contaminated mine tailings using halophytes and field addition of organic and inorganic amendments[J]. Chemosphere,2017,178:556-564.
[15] Courtney R, Mullen G, Harrington T. An evaluation of revegetation success on bauxite residue[J]. Restoration Ecology,2009,17(3):350-358.
[16] Santini T C, Fey M V. Spontaneous vegetation encroachment upon bauxite residue(red mud)as an indicator and facilitator of in situ remediation processes[J]. Environmental Science & Technology,2013,47(21):12089-12096.
[17] Xue S G, Zhu F, Kong X F, et al. A review of the characterization and revegetation of bauxite residues(Red mud)[J]. Environmental Science and Pollution Research,2016,23(2):1120-1132.
[18] Sperow M. Carbon sequestration potential in reclaimed mine sites in seven east-central states[J]. Journal of Environmental Quality,2006,35(4):1428-1438.
[19] Celi L, Cerli C, Turner B L, et al. Biogeochemical cycling of soil phosphorus during natural revegetation of Pinus sylvestris on disused sand quarries in Northwestern Russia[J]. Plant and Soil,2013,367(1/2):121-134.
[20] Anderson C R, Condron L M, Clough T J, et al. Biochar induced soil microbial community change:implications for biogeochemical cycling of carbon, nitrogen and phosphorus[J]. Pedobiologia,2011,54(5/6):309-320.
[21] Goloran J B, Chen C R, Phillips I R, et al. Plant phosphorus availability index in rehabilitated bauxite-processing residue sand[J]. Plant and Soil, 2014,374(1/2):565-578.
[22] Goloran J B, Phillips I R, Chen C R. Forms of nitrogen alter plant phosphorus uptake and pathways in rehabilitated highly alkaline bauxite processing residue sand[J]. Land Degradation & Development,2017,28(2):628-637.
[23] Chrysochoou M, Dermatas D, Grubb D G. Phosphate application to firing range soils for Pb immobilization:the unclear role of phosphate[J]. Journal of Hazardous Materials, 2007,144(1/2):1-14.
[24] Ruby M V, Davis A, Nicholson A. In situ formation of lead phosphates in soils as a method to immobilize lead[J]. Environmental Science & Technology,1994,28(4):646-654.
[25] 陈世宝,李娜,王萌,等.利用磷进行铅污染土壤原位修复中需考虑的几个问题[J].中国生态农业学报,2010,18(1):203-209.
[26] 柯莉萍,张艳,李冬立.威宁县严重干旱气候条件分析[J].现代农业科技,2011(13):286-288.
[27] 宋振涛,管少斌,牛禹,等.黔西北铅锌成矿带成矿地质条件与找矿标志[J].矿产与地质,2017,31(3):460-471.
[28] 鲍士旦.土壤农化分析[M].北京:中国农业出版社,2000.
[29] 朱广伟,秦伯强,高光,等.灼烧对沉积物烧失量及铁,磷测定的影响[J].分析试验室,2004,23(9):72-76.
[30] 刘晶晶,李敏,曲博,等.湿地挺水植物根系土壤中的磷形态变化与分析[J].中国环境科学,2013,33(11):2040-2046.
[31] 黄昌勇.土壤学[M].北京:中国农业出版社,2000.
[32] Dinkelaker B, Römheld V, Marschner H. Citric acid excretion and precipitation of calcium citrate in the rhizosphere of white lupin(Lupinus albus L.)[J]. Plant Cell & Environment,1989,12(3):285-292.
[33] Cerli C, Celi L, Johansson M, et al. Soil organic matter changes in a spruce chronosequence on swedish former agricultural soil[J]. Soil Science,2006,171(11):837-849.
[34] 林启美,赵小蓉,孙焱鑫,等.4种不同生态系统的土壤解磷细菌数量及种群分布[J].土壤与环境,2000,9(1):34-37.
[35] 章家恩,刘文高.微生物资源的开发利用与农业可持续发展[J].土壤与环境,2001,10(2):154-157.
[36] Ding Y Z, Song Z G, Feng R W, et al. Interaction of organic acids and pH on multi-heavy metal extraction from alkaline and acid mine soils[J]. International Journal of Environmental Science and Technology,2014,11(1):33-42.
[37] Mendez M O, Glenn E P, Maier R M. Phytostabilization potential of quailbush for mine tailings[J]. Journal of Environmental Quality,2007,36(1):245-253.
[38] 童倩倩,何腾兵,高雪,等.贵州省耕地土壤的养分状况[J].贵州农业科学,2011,39(2):82-84.
[39] 麻占威,吴永贵,付天岭,等.不同植物凋落物对土法冶炼铅锌废渣的改良效果[J].贵州农业科学,2014,42(6):188-192.
[40] 陆景陵.植物营养学(上)[M].北京:中国农业大学出版社,2002.
[41] 黄彬彬.不同母岩和林龄杉木人工林土壤磷素形态特征研究[D].福州:福建农林大学,2017.
[42] 张福锁.环境胁迫与植物根际营养[M].北京:中国农业出版社,1997.
[43] 李金辉,卢鑫,周志宇,等.不同种植年限紫穗槐根际非根际土壤磷组分含量特征[J].草业学报,2014,23(6):61-68.
[44] Venterink H O, Davidsson T E, Kiehl K, et al. Impact of drying and re-wetting on N, P and K dynamics in a wetland soil[J]. Plant and Soil,2002,243(1):119-130.
[45] 贵州省土镶普查办公室.贵州省土壤[M].贵阳:贵州科技出版社,1994.
[46] Hinsinger P. Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes:a review[J]. Plant and Soil,2001,237(2):173-195.
[47] Bekele T, Cino B J, Ehlert P A I, et al. An evaluation of plant-borne factors promoting the solubilization of alkaline rock phosphates[J]. Plant & Soil,1983,75(3):361-378.
[48] Hinsinger P, Elsass F, Jaillard B, et al. Root-induced irreversible transformation of a trioctahedral mica in the rhizosphere of rape[J]. European Journal of Soil Science,1993,44(3):535-545.
[49] Hinsinger P, Gilkes R J. Root-induced dissolution of phosphate rock in the rhizosphere of lupins grown in alkaline soil[J]. Soil Research,1995,33(3):477-489.
[50] 姚拓.高寒地区燕麦根际联合固氮菌研究Ⅱ固氮菌的溶磷性和分泌植物生长素特性测定[J].草业学报,2004,13(3):85-90.
[51] 申建波,张福锁.根分泌物的生态效应[J].中国农业科技导报,1999,1(4):21-27.
[52] 沈宏,杨存义,范小威,等.大豆根系分泌物和根细胞壁对难溶性磷的活化[J].生态环境,2004,13(4):633-635.
[53] Ae N, Otani T. The role of cell wall components from groundnut roots in solubilizing sparingly soluble phosphorus in low fertility soils[J]. Plant and Soil,1997,196(2):265-270.
[54] Shen H, Wang X C, Shi W M. Isolation and identification of specific root exudates in elephant grass(Pennis lium L.)in response to phosphorus deficiency[J]. Journal of Plant Nutrition,2001,24(7):1117-1130.
[55] 刘志红,宋之光,雷怀彦,等.土荆芥生长土壤的环境地球化学特征[J].时珍国医国药,2010,21(1):252-254.
[56] 刘艺杉,刘自学,李晓光,等.北京地区3种冷季型禾本科草坪草生物量及养分吸收动态的研究[J].草业科学,2008,25(4):88-94.
[57] Zoysa A K N, Loganathan P, Hedley M J. A technique for studying rhizosphere processes in tree crops:soil phosphorus depletion around camellia(Camellia japonica L.)roots[J]. Plant and Soil,1997,190(2):253-265.
[58] 刘文静,张平究,董国政,等.不同退耕年限下菜子湖湿地土壤磷素组分特征变化[J].生态学报,2014,34(10):2654-2662.
[59] Hamad M E, Rimmer D L, Syers J K. Effect of iron oxide on phosphate sorption by calcite and calcareous soils[J]. Journal of Soil Science, 1992,43(2):273-281.
[60] Takagi S, Kamei S, Yu M H. Efficiency of iron extraction from soil by mugineic acid family phytosiderophores[J]. Journal of Plant Nutrition, 1988,11(6/11):643-651.
[61] 章爱群,贺立源,赵会娥,等.有机酸对土壤无机态磷转化和速效磷的影响[J].生态学报,2009,29(8):4061-4069.

相似文献/References:

[1]丁真真.中国农田土壤重金属污染与其植物修复研究[J].水土保持研究,2007,14(03):19.
 DING Zhen-zhen.Farmland Soil Heavy Metal Pollution in Our Country and Plant Repair Research[J].Research of Soil and Water Conservation,2007,14(03):19.
[2]曾小梅,刘鹏,张晓斌.水生观赏植物对城市污水的修复研究[J].水土保持研究,2015,22(05):349.
 ZENG Xiaomei,LIU Peng,ZHANG Xiaobin.Phytoremediation of Urban Wastewater by Ornamental Hydrophytes[J].Research of Soil and Water Conservation,2015,22(03):349.
[3]王波,李凯荣,崔碧霄,等.刺槐苗木抗氧化保护系统对石油污染的响应[J].水土保持研究,2014,21(02):251.
 WANG Bo,LI Kai-rong,CUI Bi-xiao,et al.Reponse of Anti-oxidation Protective System of Robinia pseudoacacia Seedlings to Petroleum Contamination[J].Research of Soil and Water Conservation,2014,21(03):251.

备注/Memo

收稿日期:2018-07-13;改回日期:2018-08-10。
基金项目:贵州省国内生态学一流学科建设项目(GNYL (2017)007号);国家自然科学基金(41663009);国家自然科学基金—贵州省联合资助项目(U1612442-3);贵州省教育厅自然科学研究项目(黔教合KY字(2016)011);贵州省教育厅研究生教育创新计划项目(黔教研合GZZ字(2016)07)
作者简介:郑志林(1992-),男,江西峡江人,硕士研究生,主要从事生物地球化学与污染生态修复研究。E-mail:zlzheng92@163.com
通讯作者:吴永贵(1972-),男,贵州纳雍人,博士,教授,博士生导师,主要从事污染生态效应,污染生态控制及环境生态修复方面的教学研究工作。E-mail:ygwu72@126.com

更新日期/Last Update: 1900-01-01