AMENDMENT MATERIALS ENHANCED <i>LAGERSTROEMIA INDICA L</i>. REMEDIATION TECHNOLOGY FOR Cu-POLLUTED SOIL

LIANG Jing; ZHANG Qing-qing; ZHANG Chang-bo

doi:10.13205/j.hjgc.202106023

Volume 39 Issue 6

Jan. 2022

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2021 > 39(6): 154-159

LIANG Jing, ZHANG Qing-qing, ZHANG Chang-bo. AMENDMENT MATERIALS ENHANCED LAGERSTROEMIA INDICA L. REMEDIATION TECHNOLOGY FOR Cu-POLLUTED SOIL[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(6): 154-159. doi: 10.13205/j.hjgc.202106023

Citation:

LIANG Jing, ZHANG Qing-qing, ZHANG Chang-bo. AMENDMENT MATERIALS ENHANCED LAGERSTROEMIA INDICA L. REMEDIATION TECHNOLOGY FOR Cu-POLLUTED SOIL[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(6): 154-159. doi: 10.13205/j.hjgc.202106023

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AMENDMENT MATERIALS ENHANCED LAGERSTROEMIA INDICA L. REMEDIATION TECHNOLOGY FOR Cu-POLLUTED SOIL

doi: 10.13205/j.hjgc.202106023

1. Shanghai Academy of Landscape Architecture Science and Planning, Shanghai 200232, China;
2. Shanghai Engineering Research Center of Landscaping on Challenging Urban Sites, Shanghai 200232, China;
3. Shanghai Research Institute of Chemical Industry, Shanghai 200062, China

Received Date: 2020-03-11
Available Online: 2022-01-18

Abstract

Abstract

Lagerstroemia indica L., a woody plant was selected as the studied subject, and the strengthening effect of types and additive amount of amendment materials on the phytoremediation of Cu-contaminated soil were conducted with the incubation experiments. The results showed that there was a more significant enhancement effect for EDTA and EDDS than organic amendment materials, and the enhancement effect was the highest at the additive amounts of 5 mmol/L EDTA or 3 mmol/L EDDS. However, the enhancement effect was found on almost all the organic amendment materials on the lower Cu-polluted soils, and more significant at the organic amendment materials/soil volume ratio of 30%. Moreover, the strengthening effect of different amendment materials on the phytoremediation of the higher Cu-polluted soil was only found at organic amendment materials/soil volume ratio of 50% for the greenery waste, agricultural organic waste and peat.
- Lagerstroemia indica L.,
- Cu-contaminated soils,
- Cu absorption rate,
- Cu removal rate,
- leaves

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References(26)

References

[1]	FERGUSON C C,MARSH J A.Assessing human health risks from ingestion of contaminated soil[J].Land Contamination and Reclaim,1993,1:177-185.
[2]	李玉双,胡晓钧,孙铁珩,等.污染土壤淋洗修复技术研究进展[J].生态学杂志,2011,30(3):596-602.
[3]	MAO X H,JIANG R,XIAO W,et al.Use of surfactants for the remediation of contaminated soils:a review[J].Journal of Hazardous Materials,2015,285:419-435.
[4]	何军良,祝亚平,朱密,等.土壤中重金属污染的植物修复强化技术概览[J].安全与环境工程,2019,26(1):62-67 ,80.
[5]	USMAN A R A,MOHAMED H M.Effect of microbial inoculation and EDTA on the uptake and translocation of heavy metal by corn and sunflower[J].Chemosphere,2009,76(7):893-899.
[6]	ARSENOV D,ZUPUNSKI M,BORISEV M,et al.Exogenously applied citric acid enhances antioxidant defense and phytoextraction of cadmium by willows (Salix Spp.)[J].Water,Air,& Soil Pollution,2017,228(6):1-12.
[7]	JI P H,TANG X W,JIANG Y J,et al.Potential of gibberellic Acid₃ (GA₃) for enhancing the phytoremediation efficiency of Solanum nigrum L[J].Bulletin of Environmental Contamination and Toxicology,2015,95(6):810-814.
[8]	LÓPEZ M L,PERALTA-VIDEA J R,BENITEZ T,et al.Enhancement of lead uptake by alfalfa (Medicago sativa) using EDTA and a plant growth promoter[J].Chemosphere,2005,61(4):595-598.
[9]	BURGES A,EPELDE L,BLANCO F,et al.Ecosystem services and plant physiological status during endophyte-assisted phytoremediation of metal contaminated soil[J].Science of the Total Environment,2017,584/585:329-338.
[10]	刘维涛,张银龙,陈喆敏,等.矿区绿化树木对镉和锌的吸收与分布[J].应用生态学报,2008,19(4):752-756.
[11]	NGUYEN T X T,AMYOT M,LABRECQUE M.Differential effects of plant root systems on nickel,copper and silver bioavailability in contaminated soil[J].Chemosphere,2017,168:131-138.
[12]	张冬梅,罗玉兰,有祥亮,等.城市重金属污染场地次富集树种标准划定研究[J].中国城市林业,2018,16(6):49-52.
[13]	商侃侃,张国威,蒋云.54种木本植物对土壤Cu、Pb、Zn的提取能力[J].生态学杂志,2019,38(12):3723-3730.
[14]	樊佳奇,牛来春,庞磊.云南地区不同园林植物对土壤重金属的吸收富集特征[J].江苏农业科学,2016,44(7):467-472.
[15]	梁晶,马光军,郝冠军,等.绿化植物废弃物对土壤中Cu Zn Pb和Cd形态的影响[J].农业环境科学学报,2010,29(3):492-499.
[16]	梁晶.12种草坪植物对土壤铜毒性的响应[J].环境科学与技术,2019,42(增刊2):26-31.
[17]	庞鸿宾.森林土壤分析方法[M].北京:中国标准出版社,1988.
[18]	白薇扬,赵清华,谭怀琴.非生物螯合剂EDTA与生物螯合剂EDDS联合施用提高植物提取土壤重金属效应的研究[J].重庆理工大学学报(自然科学),2013,27(8):47-53.
[19]	王静雯,伍钧,郑钦月,等.EDTA对鱼腥草修复铅锌矿区重金属复合污染土壤的影响[J].水土保持学报,2013,27(6):62-66.
[20]	王显海,刘云国,曾光明,等.EDTA溶液修复重金属污染土壤的效果及金属的形态变化特征[J].环境科学,2006,27(5):1008-1012.
[21]	罗璐瑕,胡忻.生物可降解螯合剂[S,S]-乙二胺二琥珀酸和乳酸乙酯提取土壤中重金属的研究[J].环境污染与防治,2007,29(9):661-663.
[22]	吴雅倩,白利勇,黄明丽,等.EDTA及其结构异构体在环境中的应用综述[J].环境工程,2019,37(8):159-163 ,147.
[23]	WANG X,WANG Y,QAISAR M.The effect of EDDS additionon the phytoextraction efficiency from Pb contaminated soil by Sedum alfredii Hance[J].Journal of Hazardous Materials,2009,168(1):530-535.
[24]	陈世俭.有机物质添加量对污染土壤铜形态及活性的影响[J].土壤与环境,1999,8(1):22-25.
[25]	刘益贵,彭克俭,沈振国.湖南湘西铅锌矿区植物对重金属的积累[J].生态环境,2008,17(3):1042-1048.
[26]	PADMAVATHIAMMA P K,LI L Y.Phytoremediation technology:hyper-accumulation metals in plants[J].Water,Air and Soil Pollution,2007,184:105-126.