崔红标1,
刘笑生1,
周静2,
胡照斌1,
胡友彪1,
高良敏1
1.安徽理工大学地球与环境学院,淮南 232001
2.中国科学院南京土壤研究所,南京 210008
基金项目: 国家自然科学基金资助项目(41601340)
安徽省高等学校自然科学研究项目(KJ2016A191)
Effects of simulated acid rain on release of Cu, Cd, Pb and phosphorus in contaminated soil immobilized by potassium dihydrogen phosphate
LI Ruyan1,,CUI Hongbiao1,
LIU Xiaosheng1,
ZHOU Jing2,
HU Zhaobin1,
HU Youbiao1,
GAO Liangmin1
1.School of Earth and Environment, Anhui University of Science and Technology, Huainan 232001, China
2.Institute of Soil Science, Chinese Academy of Sciences, Nanjing 210008, China
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摘要:以磷酸二氢钾(PDP)钝化后的重金属污染土壤为研究对象,通过室内土柱淋溶实验,考察在pH为3.5、4.5和5.6的模拟酸雨作用下土壤Cu、Cd、Pb和P的释放特征。结果表明:PDP处理较对照处理显著增加了淋出液中pH、电导率(EC)和总有机碳(TOC)含量,但不同pH模拟酸雨对对照和PDP处理淋出液pH、EC和TOC含量影响较小。对照处理中,正磷酸盐含量维持在较低水平(0.02~0.13 mg·L-1);PDP处理下,正磷酸盐含量在1~3 L和4~12 L分别是《地表水环境质量标准》(GB 3838-2002)五类水标准(总磷含量0.4 mg·L-1)的55.1~819倍和9.46~46.6倍,对地表水表现出较大的富营养化风险。PDP处理较对照处理显著降低了淋溶初期淋出液中的Cu、Cd和Pb含量,但是随模拟酸雨pH降低,对照和PDP处理的土壤淋出液中Cu、Pb含量均未表现出显著差异。因此,PDP处理能够显著钝化污染土壤中的Cu、Cd和Pb,但需关注酸雨淋溶下过量磷释放对地表水富营养化的潜在风险。
关键词: 酸雨/
磷酸二氢钾/
铜/
镉/
铅/
磷
Abstract:The potential release of copper (Cu), cadmium (Cd), lead (Pb) and phosphorus (P) from a potassium dihydrogen phosphate (PDP) treated soil were investigated by a laboratory column leaching experiment under simulated acid rain (SAR) with pH of 3.5, 4.5 and 5.6. The results showed that the leachate pH, electrical conductivity (EC) and total organic carbon (TOC) were significantly increased compared with the control, but they were not markedly differed with increasing SAR pH. The concentrations of orthophosphate in the control was kept a low level (0.02 to 0.13 mg·L-1). But they in PDP treated columns were 55.1 to 819 times and 9.46 to 46.6 times higher than the class Ⅴ limit (total phosphorus content 0.4 mg·L-1) of the Chinese National Quality Standards for Surface Waters (GB 3838-2002) in 1 to 3 L and 4 to 12 L, respectively, which posed a great eutrophication risk to surface water. Compared with the control treatment, the contents of Cu, Cd and Pb were noticeably decreased in PDP treated columns, but there was no significant difference among different pH values of SAR. Therefore, PDP treatment can effectively immobilize Cu, Cd, Pb in soil, but more concern should be pose on the potential risk of eutrophication induced by high leaching of P.
Key words:acid rain/
potassium dihydrogen phosphate/
copper/
cadmium/
lead/
phosphorus.
[1] | 曹心德,魏晓欣,代革联,等.土壤重金属复合污染及其化学钝化修复技术研究进展[J].环境工程学报,2011,5(7):1441-1453 |
[2] | KUMPIENE J, LAGERKVIST A, MAURICE C.Stabilization of As, Cr, Cu, Pb and Zn in soil using amendments:A review[J].Waste Management,2008,28(1):215-225 |
[3] | HAMON R E, MCLAUGHLIN M J, COZENS G.Mechanisms of attenuation of metal availability in in-situ remediation treatments[J].Environmental Science & Technology,2002,36(18):3991-3996 |
[4] | 李泽,王华,徐华勤,等.模拟酸雨对水稻土磷素动态变化的影响[J].农业现代化研究,2015,36(3):477-481 |
[5] | BROWN S, CHANEY R, HALLFRISCH J,et al.In situ soil treatments to reduce the phyto-and bioavailability of lead, zinc, and cadmium[J].Journal of Environmental Quality,2004,33(2):522-531 |
[6] | CAO X, WAHBI A, MA L,et al.Immobilization of Zn, Cu, and Pb in contaminated soils using phosphate rock and phosphoric acid[J].Journal of Hazardous Materials,2009,164(2/3):555-564 |
[7] | BASTA N T, GRADWOHL R, SNETHEN K L,et al.Chemical immobilization of lead, zinc, and cadmium in smelter-contaminated soils using biosolids and rock phosphate[J].Journal of Environmental Quality,2001,30(4):1222-1230 |
[8] | MCGOWEN S L, BASTA N T, BROWN G O.Use of diammonium phosphate to reduce heavy metal solubility and transport in smelter-contaminated soil[J].Journal of Environmental Quality,2001,30(2):493-500 |
[9] | CAO R X, MA L Q, CHEN M,et al.Phosphate-induced metal immobilization in a contaminated site[J].Environmental Pollution,2003,122(1):19-28 |
[10] | 崔红标,范玉超,周静,等.改良剂对土壤铜镉有效性和微生物群落结构的影响[J].中国环境科学,2016,36(1):197-205 |
[11] | CUI H, ZHOU J, ZHAO Q,et al.Fractions of Cu, Cd, and enzyme activities in a contaminated soil as affected by applications of micro-and nanohydroxyapatite[J].Journal of Soils & Sediments,2013,13(4):742-752 |
[12] | QIAN G, WEI C, LIM T T,et al.In-situ stabilization of Pb, Zn, Cu, Cd and Ni in the multi-contaminated sediments with ferrihydrite and apatite composite additives[J].Journal of Hazardous Materials,2009,170(2/3):1093-1100 |
[13] | 吕玉娟,彭新华,高磊,等.红壤丘陵岗地区坡地产流产沙特征及影响因素研究[J].水土保持学报,2014,28(6):19-23 |
[14] | 鲁如坤.土壤农业化学分析法[M].北京:中国农业科技出版社,1999 |
[15] | 马凯强,崔红标,范玉超,等.模拟酸雨对羟基磷灰石稳定化污染土壤磷镉释放的影响[J].农业环境科学学报,2016,35(1):67-74 |
[16] | OLSEN S R, COLE C V, WATNABE F S,et al.Estimation of Available Phosphorus in Soils by Extraction with Sodium Bicarbonate[M].Washington, DC:United States Government Printing Office,1954 |
[17] | 国家环境保护总局.水和废水监测分析方法[M].4版.北京:中国环境科学出版社,2002 |
[18] | 廖柏寒,李长生.土壤对酸沉降缓冲机制探讨[J].环境科学,1989,10(1):30-34 |
[19] | LIAO B, GUO Z, PROBST A, et al.Soil heavy metal contamination and acid deposition: Experimental approach on two forest soils in Hunan, Southern China[J].Geoderma,2005,127(1/2):91-103 |
[20] | 刘俐,周友亚,宋存义,等.模拟酸雨淋溶下红壤中盐基离子释放及缓冲机制研究[J].环境科学研究,2008,21(2):49-55 |
[21] | MUSTAFA S, NAEEM A, REHANA N,et al.Phosphate/sulphate exchange studies on amberlite IRA-400[J].Environmental Technology,2004,25(10):1115-1122 |
[22] | 王秀丽,梁成华,马子惠,等.施用磷酸盐和沸石对土壤镉形态转化的影响[J].环境科学,2015,36(4):1437-1444 |
[23] | 刘昭兵,纪雄辉,彭华,等.磷肥对土壤中镉的植物有效性影响及其机理[J].应用生态学报,2012,23(6):1585-1590 |
[24] | ZHANG M, ZHANG H.Co-transport of dissolved organic matter and heavy metals in soils induced by excessive phosphorus applications[J].Journal of Environmental Science,2010,22(4):598-606 |
[25] | 董颖博,林海,刘泉利,等.模拟酸雨条件下锡尾矿中重金属As、Zn、Pb的释放规律[J].中国有色金属学报,2015,25(10):2921-2928 |
[26] | 张丽华,朱志良,郑承松,等.模拟酸雨对三明地区受重金属污染土壤的淋滤过程研究[J].农业环境科学学报,2008,27(1):151-155 |
[27] | 刘洪杰.酸性淋洗对土壤有机质和粘粒含量的影响[J].环境科学,1991,12(2):42-44 |
[28] | LING D J, ZHANG J E, OUYANG Y,et al.Role of simulated acid rain on cations, phosphorus, and organic matter dynamics in latosol[J].Archives of Environmental Contamination & Toxicology,2007,52(1):16-21 |
[29] | LIU R, ZHAO D.Reducing leachability and bioaccessibility of lead in soils using a new class of stabilized iron phosphate nanoparticles[J].Water Research,2007,41(12):2491-2502 |
[30] | 陈世宝,朱永官,马义兵.不同磷处理对污染土壤中有效态铅及磷迁移的影响[J].环境科学学报,2006,26(7):1140-1144 |
[31] | CAO X, Ma L Q, RHUE D R, et al.Mechanisms of lead, copper, and zinc retention by phosphate rock[J].Environmental Pollution,2004,131:435-444 |
[32] | 朱佳文,邹冬生,向言词,等.钝化剂对铅锌尾矿砂中重金属的固化作用[J].农业环境科学学报,2012,31(5):920-925 |
[33] | JIN Z, LIU T, YANG Y,et al.Leaching of cadmium, chromium, copper, lead, and zinc from two slag dumps with different environmental exposure periods under dynamic acidic condition[J].Ecotoxicology & Environmental Safety,2014,104(2):43-50 |
[34] | BOLAN N S, ADRIANO D C, DURAISAMY P,et al.Immobilization and phytoavailability of cadmium in variable charge soils.I.Effect of phosphate addition[J].Plant Soil,2003,250(1):83-94 |
[35] | 宋波,曾炜铨,陆素芬,等.含磷材料在铅污染土壤修复中的应用[J].环境工程学报,2015,9(12):5649-5658 |
[36] | DEBELA F, AROCENA J M, THRING R W,et al.Organic acids inhibit the formation of pyromorphite and Zn-phosphate in phosphorous amended Pb-and Zn-contaminated soil[J].Journal of Environmental Management,2013,116:156-162 |
[37] | 郭亮,李忠武,黄斌,等.不同施磷量(KH2PO4)作用对Cu、Zn在红壤中的迁移转化[J].环境科学,2014,35(9):3546-3552 |
[38] | 黄蔼霞,许超,吴启堂,等.赤泥对重金属污染红壤修复效果及其评价[J].水土保持学报,2012,26(1):267-272 |
[39] | 廖柏寒,曾敏,郭朝晖,等.模拟酸雨下自然红壤与污染红壤中Cd,Cu,Zn的释放特征[J].环境化学,2009,28(3):343-349 |
[40] | TANG X, YANG J.Long-term stability and risk assessment of lead in mill waste treated by soluble phosphate[J].Science of the Total Environment,2012,438:299-303 |
[41] | YANG J, TANG X.Leaching characteristics of phosphate-stabilized lead in contaminated urban soil and mill waste[J].Environmental Monitoring and Restoration,2009,6:127-134 |
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刊出日期:2018-01-14
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模拟酸雨对磷酸二氢钾钝化污染土壤Cu、Cd、Pb和P释放的影响
李如艳1,,崔红标1,
刘笑生1,
周静2,
胡照斌1,
胡友彪1,
高良敏1
1.安徽理工大学地球与环境学院,淮南 232001
2.中国科学院南京土壤研究所,南京 210008
基金项目: 国家自然科学基金资助项目(41601340) 安徽省高等学校自然科学研究项目(KJ2016A191)
关键词: 酸雨/
磷酸二氢钾/
铜/
镉/
铅/
磷
摘要:以磷酸二氢钾(PDP)钝化后的重金属污染土壤为研究对象,通过室内土柱淋溶实验,考察在pH为3.5、4.5和5.6的模拟酸雨作用下土壤Cu、Cd、Pb和P的释放特征。结果表明:PDP处理较对照处理显著增加了淋出液中pH、电导率(EC)和总有机碳(TOC)含量,但不同pH模拟酸雨对对照和PDP处理淋出液pH、EC和TOC含量影响较小。对照处理中,正磷酸盐含量维持在较低水平(0.02~0.13 mg·L-1);PDP处理下,正磷酸盐含量在1~3 L和4~12 L分别是《地表水环境质量标准》(GB 3838-2002)五类水标准(总磷含量0.4 mg·L-1)的55.1~819倍和9.46~46.6倍,对地表水表现出较大的富营养化风险。PDP处理较对照处理显著降低了淋溶初期淋出液中的Cu、Cd和Pb含量,但是随模拟酸雨pH降低,对照和PDP处理的土壤淋出液中Cu、Pb含量均未表现出显著差异。因此,PDP处理能够显著钝化污染土壤中的Cu、Cd和Pb,但需关注酸雨淋溶下过量磷释放对地表水富营养化的潜在风险。
English Abstract
Effects of simulated acid rain on release of Cu, Cd, Pb and phosphorus in contaminated soil immobilized by potassium dihydrogen phosphate
LI Ruyan1,,CUI Hongbiao1,
LIU Xiaosheng1,
ZHOU Jing2,
HU Zhaobin1,
HU Youbiao1,
GAO Liangmin1
1.School of Earth and Environment, Anhui University of Science and Technology, Huainan 232001, China
2.Institute of Soil Science, Chinese Academy of Sciences, Nanjing 210008, China
Keywords: acid rain/
potassium dihydrogen phosphate/
copper/
cadmium/
lead/
phosphorus
Abstract:The potential release of copper (Cu), cadmium (Cd), lead (Pb) and phosphorus (P) from a potassium dihydrogen phosphate (PDP) treated soil were investigated by a laboratory column leaching experiment under simulated acid rain (SAR) with pH of 3.5, 4.5 and 5.6. The results showed that the leachate pH, electrical conductivity (EC) and total organic carbon (TOC) were significantly increased compared with the control, but they were not markedly differed with increasing SAR pH. The concentrations of orthophosphate in the control was kept a low level (0.02 to 0.13 mg·L-1). But they in PDP treated columns were 55.1 to 819 times and 9.46 to 46.6 times higher than the class Ⅴ limit (total phosphorus content 0.4 mg·L-1) of the Chinese National Quality Standards for Surface Waters (GB 3838-2002) in 1 to 3 L and 4 to 12 L, respectively, which posed a great eutrophication risk to surface water. Compared with the control treatment, the contents of Cu, Cd and Pb were noticeably decreased in PDP treated columns, but there was no significant difference among different pH values of SAR. Therefore, PDP treatment can effectively immobilize Cu, Cd, Pb in soil, but more concern should be pose on the potential risk of eutrophication induced by high leaching of P.