承德市滦河流域土壤重金属地球化学基线厘定及其累积特征
|
摘要
选择承德市滦河流域为研究区,系统采集了351个表层土壤样品(0~20cm),测定了Cu、Ni、Cd、Cr、Pb、Zn、Hg、V、Ti、Mn、As和Co共12种重金属的含量,运用基于参比元素的标准化方法和累积频率曲线法确定了12种重金属元素的地球化学基线值,结合主成分分析法与地统计方法统计结果,分析了重金属的空间结构和分布特征,利用地累积指数法对不同土壤类型和土地利用方式表层土壤重金属累积程度进行了分类评价.结果表明,滦河流域表层土壤V、Ti、Cd、Pb、Mn和Co元素地球化学基线值高于河北省背景值,As、Zn、Cr、Cu、Ni和Hg元素地球化学基线值低于河北省背景值.表层土壤重金属总体累积程度由强至弱为:Cd> Pb> Cu> Ti> Mn> Zn> Cr> Ni> Co> V> Hg> As,80%以上的土壤样品中Pb、Ti、V、As和Co元素属无累积-中度累积水平,70%以上土壤样品中Hg、Mn、Ni、Cu、As、Cd和Cr元素属无累积-中度累积水平.土壤重金属总体累积程度在棕壤、褐土和潮土中依次增大;在工矿用地、灌木林地中较高,林地、草地中相对最低.农用地表层土壤中Pb、Cd元素累积程度相对较高,分别有27. 69%和25. 38%的样品属中等以上累积水平.滦河流域表层土壤Ti、V、Co、Ni和Cr元素同源性较高,与原生高地质背景相关; Cd、Pb、Zn,Mn、Cu和As元素污染累积受成土母岩和人为因素共同作用影响,Hg元素累积则主要来源于人为活动.
A total of 351 surface soil samples( 0-20 cm) were collected from the Luanhe River Basin in Chengde City( a typical area of concentrated mineral resources) and analyzed for 12 heavy metals( Cu,Ni,Cd,Cr,Pb,Zn,Hg,V,Ti,Mn,As,and Co). The geochemical baseline values of the heavy metals were determined using the reference element method and the cumulative frequency curve method. Furthermore,the spatial structure and distribution characteristics of the heavy metals were assessed based on PCA and geostatistical analysis. The accumulation of heavy metal pollution in different types of soil and in association with different land use patterns was also evaluated using a geological accumulative index. The results showed that the geochemical baseline values of V,Ti,Cd,Pb,Mn,and Co in the surface soils of the Luanhe River Basin were higher than their background values for Hebei Province. In contrast,the geochemical baseline values of As,Zn,Cr,Cu,Ni,and Hg were lower than their background values. The average accumulation index of the surface soils followed the order of Cd > Pb > Cu > Ti > Mn > Zn > Cr > Ni > Co > V > Hg > As. More than80% of the soil samples were categorized as having no accumulation or moderate accumulation of Pb,Ti,V,As,and Co,while over70% of the soil samples were categorized as having no accumulation or moderate accumulation of Hg,Mn,Ni,Cu,As,Cd,and Cr.With respect to different soil types,the average accumulation index of heavy metals followed the order of fluvo-aquic soil > cinnamon soil > brown soil. With respect to land use types,the accumulation index of heavy metals followed the order of industrial and mining land > shrub forest land > agricultural land > woodland and grassland. The accumulation of Pb and Cd in the surface soils of agricultural land was relatively high in comparison to the other elements,with 27. 69% and 25. 38% of the samples being above the moderate accumulation level,respectively. The iron group elements Ti,V,Co,Ni,and Cr are likely to derive from naturally high geological background sources,while the spatial patterns of Cd,Pb,Zn,Mn,Cu,and As were associated with the combination of parent material and anthropogenic inputs. The accumulation of Hg was mainly influenced by human activities.
A total of 351 surface soil samples( 0-20 cm) were collected from the Luanhe River Basin in Chengde City( a typical area of concentrated mineral resources) and analyzed for 12 heavy metals( Cu,Ni,Cd,Cr,Pb,Zn,Hg,V,Ti,Mn,As,and Co). The geochemical baseline values of the heavy metals were determined using the reference element method and the cumulative frequency curve method. Furthermore,the spatial structure and distribution characteristics of the heavy metals were assessed based on PCA and geostatistical analysis. The accumulation of heavy metal pollution in different types of soil and in association with different land use patterns was also evaluated using a geological accumulative index. The results showed that the geochemical baseline values of V,Ti,Cd,Pb,Mn,and Co in the surface soils of the Luanhe River Basin were higher than their background values for Hebei Province. In contrast,the geochemical baseline values of As,Zn,Cr,Cu,Ni,and Hg were lower than their background values. The average accumulation index of the surface soils followed the order of Cd > Pb > Cu > Ti > Mn > Zn > Cr > Ni > Co > V > Hg > As. More than80% of the soil samples were categorized as having no accumulation or moderate accumulation of Pb,Ti,V,As,and Co,while over70% of the soil samples were categorized as having no accumulation or moderate accumulation of Hg,Mn,Ni,Cu,As,Cd,and Cr.With respect to different soil types,the average accumulation index of heavy metals followed the order of fluvo-aquic soil > cinnamon soil > brown soil. With respect to land use types,the accumulation index of heavy metals followed the order of industrial and mining land > shrub forest land > agricultural land > woodland and grassland. The accumulation of Pb and Cd in the surface soils of agricultural land was relatively high in comparison to the other elements,with 27. 69% and 25. 38% of the samples being above the moderate accumulation level,respectively. The iron group elements Ti,V,Co,Ni,and Cr are likely to derive from naturally high geological background sources,while the spatial patterns of Cd,Pb,Zn,Mn,Cu,and As were associated with the combination of parent material and anthropogenic inputs. The accumulation of Hg was mainly influenced by human activities.
引文
[1]周启星,滕涌,展思辉,等.土壤环境基准/标准研究需要解决的基础性问题[J].农业环境科学学报,2014,33(1):1-14.Zhou Q X,Teng Y,Zhan S H,et al.Fundamental problems to be solved in research on soil-environmental criteria/standards[J].Journal of Agro-Environment Science,2014,33(1):1-14.
[2]Chen S B,Wang M,Li S S,et al.Overview on current criteria for heavy metals and its hint for the revision of soil environmental quality standards in China[J].Journal of Integrative Agriculture,2019,17(4):765-774.
[3]聂静茹,马友华,徐露露,等.我国《土壤环境质量标准》中重金属污染相关问题探讨[J].农业资源与环境学报,2013,30(6):44-49.Nie J R,Ma Y H,Xu L L,et al.Discussion about heavy metal pollution in soil environmental quality standard in China[J].Journal of Agricultural Resources and Environment,2013,30(6):44-49.
[4]李敏,李琴,赵丽娜,等.我国土壤环境保护标准体系优化研究与建议[J].环境科学研究,2016,29(12):1799-1810.Li M,Li Q,Zhao L N,et al.Optimizing the soil environmental protection standard system and suggestions[J].Research of Environmental Sciences,2016,29(12):1799-1810.
[5]伍福琳,陈丽,易廷辉,等.重庆市农地重金属基线值的厘定及其积累特征分析[J].环境科学,2018,39(11):5116-5126.Wu F L,Chen L,Yi T H,et al.Determination of heavy metal baseline values and analysis of its accumulation characteristics in agricultural land in Chongqing[J].Environmental Science,2018,39(11):5116-5126.
[6]卢新哲,谷安庆,张言午,等.基于环境地球化学基线的农用地重金属累积特征及其潜在生态危害风险研究[J].土壤学报,2019,56(2):408-419.Lu X Z,Gu A Q,Zhang Y W,et al.Sources and risk assessment of heavy metal in agricultural soils based on the environmental geochemical baselines[J].Acta Pedologica Sinica,2019,56(2):408-419.
[7]赵元艺,曾辉,徐友宁,等.金属矿集区地球化学环境累积效应的理论与工作方法[J].地质通报,2014,33(8):1106-1113.Zhao Y Y,Zeng H,Xu Y N,et al.Theory and work methods for the cumulative effects of environmental geochemistry in the metallic deposit cluster[J].Geological Bulletin of China,2014,33(8):1106-1113.
[8]Faust J C,Scheiber T,Fabian K,et al.Geochemical characterisation of northern Norwegian fjord surface sediments:a baseline for further paleo-environmental investigations[J].Continental Shelf Research,2017,148:104-115.
[9]李艳,张薇薇,程永毅,等.重庆紫色母岩及土壤As、Hg环境地球化学基线研究[J].土壤学报,2017,54(4):917-926.Li Y,Zhang W W,Cheng Y Y,et al.Environmental geochemical baseline of As and Hg in purple soil and its parent rock in Chongqing[J].Acta Pedologica Sinica,2017,54(4):917-926.
[10]朱晓东,韦朝阳,杨芬.包头-白云鄂博地区重金属基线值的厘定及其在重金属污染分级评价中的应用[J].自然资源学报,2016,31(2):310-320.Zhu X D,Wei C Y,Yang F.Determination of heavy metal baseline in Baotou and Bayan Obo and its application in the assessment of heavy metal contamination[J].Journal of Natural Resources,2016,31(2):310-320.
[11]高杨,许东升,李琦.宿州市表层土壤重金属元素环境地球化学基线研究[J].地球与环境,2018,46(5):444-450.Gao Y,Xu D S,Li Q.A study on environmental geochemical baselines of heavy metals in the surficial soil of Suzhou[J].Earth and Environment,2018,46(5):444-450.
[12]Salminen R,Gregorauskiene V.Considerations regarding the definition of a geochemical baseline of elements in the surficial materials in areas differing in basic geology[J].Applied Geochemistry,2000,15(5):647-653.
[13]Sultan K,Shazili N A.Distribution and geochemical baselines of major,minor and trace elements in tropical topsoils of the Terengganu River basin,Malaysia[J].Journal of Geochemical Exploration,2009,103(2-3):57-68.
[14]王学求,周建,徐善法,等.全国地球化学基准网建立与土壤地球化学基准值特征[J].中国地质,2016,43(5):1469-1480.Wang X Q,Zhou J,Xu S F,et al.China soil geochemical baselines networks:data characteristics[J].Geology in China,2016,43(5):1469-1480.
[15]Salminen R,Tarvainen T.The problem of defining geochemical baselines.a case study of selected elements and geological materials in Finland[J].Journal of Geochemical Exploration,1997,60(1):91-98.
[16]王济,王世杰,欧阳自远.贵阳市表层土壤中镉的环境地球化学基线研究[J].环境科学,2007,28(6):1344-1348.Wang J,Wang S J,Ouyang Z Y.Geogenic distribution and baseline concentrations of cadmium in surficial soil of Guiyang,China[J].Environmental Science,2007,28(6):1344-1348.
[17]赵新儒,特拉津·那斯尔,程永毅,等.伊犁河流域土壤重金属环境地球化学基线研究及污染评价[J].环境科学,2014,35(6):2392-2400.Zhao X R,Nasier T,Cheng Y Y,et al.Environmental geochemical baseline of heavy metals in soils of the Ili River Basin and pollution evaluation[J].Environmental Science,2014,35(6):2392-2400.
[18]李超,杜哲,陈亚恒,等.环京津地区土地生态服务价值时空分异特征[J].土壤通报,2015,46(1):42-47.Li C,Du Z,Chen Y H,et al.Spatio-temporal differentiation of land ecosystem service value in the surrounding regions of Beijing and Tianjin[J].Chinese Journal of Soil Science,2015,46(1):42-47.
[19]Yu C J,Li H Q,Jia X P,et al.Improving resource utilization efficiency in China's mineral resource-based cities:a case study of Chengde,Hebei province[J].Resources,Conservation and Recycling,2015,94:1-10.
[20]Liu J Q,Yin P,Chen B,et al.Distribution and contamination assessment of heavy metals in surface sediments of the Luanhe River Estuary,northwest of the Bohai Sea[J].Marine Pollution Bulletin,2016,109(1):633-639.
[21]滕彦国,矫旭东,左锐,等.攀枝花矿区表层土壤中钒的环境地球化学研究[J].吉林大学学报(地球科学版),2007,37(2):278-283.Teng Y G,Jiao X D,Zuo R,et al.Environmental geochemistry of vanadium in topsoil in Panzhihua Mining Area[J].Journal of Jilin University(Earth Science Edition),2007,37(2):278-283.
[22]中华人民共和国生态环境部.生态环境损害鉴定评估技术指南土壤与地下水[R].北京:中华人民共和国生态环境部,2018.11-22.Ministry of Ecology and Environment of the People's Republic of China.Technical guidelines for identification and assessment of eco-environmental damage soil and groundwater[R].Beijing:Ministry of Ecology and Environment of the People's Republic of China,2018.11-22.
[23]滕彦国,倪师军,庹先国,等.应用标准化方法评价攀枝花地区表层土壤的重金属污染[J].土壤学报,2003,40(3):374-379.Teng Y G,Ni S J,Tuo X G,et al.Application of a normalization procedure in assessing heavy metal pollution in topsoil,Panzhihua Region[J].Acta Pedologica Sinica,2003,40(3):374-379.
[24]Guillén M T,Delgado J,Albanese S,et al.Environmental geochemical mapping of Huelva municipality soils(SW Spain)as a tool to determine background and baseline values[J].Journal of Geochemical Exploration,2011,109(1-3):59-69.
[25]Islam M S,Hossain M B,Matin A,et al.Assessment of heavy metal pollution,distribution and source apportionment in the sediment from Feni River estuary,Bangladesh[J].Chemosphere,2018,202:25-32.
[26]范凯,韦朝阳,杨晓松.长沙市乔口镇土壤重金属地球化学基线值的厘定及应用[J].环境科学学报,2014,34(12):3076-3083.Fan K,Wei C Y,Yang X S.Geochemical baseline of heavy metals in the soils of Qiaokou town,Changsha city and its application[J].Acta Scientiae Circumstantiae,2014,34(12):3076-3083.
[27]章海波,骆永明.区域尺度土壤环境地球化学基线估算方法及其应用研究[J].环境科学,2010,31(7):1607-1613.Zhang H B,Luo Y M.Researches on the estimate methods and applications of soil environmental geochemical baseline at a regional scale[J].Environmental Science,2010,31(7):1607-1613.
[28]Bauer I,Bor J.Lithogene,geogene und anthropogene schwermetallgehalte von l9b9den an den beispielen von Cu,Zn,Ni,Pb,Hg und Cd[J].Mainzer Geowiss Mitt,1995,24:47-70.
[29]Müller G.Index of geoaccumulation in sediments of the Rhine River[J].Geo Journal,1969,2(3):108-118.
[30]中国环境监测总站.中国土壤元素背景值[M].北京:中国环境科学出版社,1990.
[31]杨伟光,王美娥,陈卫平.新疆干旱区某矿冶场对周围土壤重金属累积的影响[J].环境科学,2019,40(1):445-452.Yang W G,Wang M E,Chen W P.Effect of a mining and smelting plant on the accumulation of heavy metals in soils in arid areas in Xinjiang[J].Environmental Science,2019,40(1):445-452.
[32]Cao X L,Diao M H,Zhang B G,et al.Spatial distribution of vanadium and microbial community responses in surface soil of Panzhihua mining and smelting area,China[J].Chemosphere,2017,183:9-17.
[33]郑睛之,王楚栋,王诗涵,等.典型小城市土壤重金属空间异质性及其风险评价:以临安市为例[J].环境科学,2018,39(6):2875-2883.Zheng J Z,Wang C D,Wang S H,et al.Spatial variation of soil heavy metals in Lin'an city and its potential risk evaluation[J].Environmental Science,2018,39(6):2875-2883.
[2]Chen S B,Wang M,Li S S,et al.Overview on current criteria for heavy metals and its hint for the revision of soil environmental quality standards in China[J].Journal of Integrative Agriculture,2019,17(4):765-774.
[3]聂静茹,马友华,徐露露,等.我国《土壤环境质量标准》中重金属污染相关问题探讨[J].农业资源与环境学报,2013,30(6):44-49.Nie J R,Ma Y H,Xu L L,et al.Discussion about heavy metal pollution in soil environmental quality standard in China[J].Journal of Agricultural Resources and Environment,2013,30(6):44-49.
[4]李敏,李琴,赵丽娜,等.我国土壤环境保护标准体系优化研究与建议[J].环境科学研究,2016,29(12):1799-1810.Li M,Li Q,Zhao L N,et al.Optimizing the soil environmental protection standard system and suggestions[J].Research of Environmental Sciences,2016,29(12):1799-1810.
[5]伍福琳,陈丽,易廷辉,等.重庆市农地重金属基线值的厘定及其积累特征分析[J].环境科学,2018,39(11):5116-5126.Wu F L,Chen L,Yi T H,et al.Determination of heavy metal baseline values and analysis of its accumulation characteristics in agricultural land in Chongqing[J].Environmental Science,2018,39(11):5116-5126.
[6]卢新哲,谷安庆,张言午,等.基于环境地球化学基线的农用地重金属累积特征及其潜在生态危害风险研究[J].土壤学报,2019,56(2):408-419.Lu X Z,Gu A Q,Zhang Y W,et al.Sources and risk assessment of heavy metal in agricultural soils based on the environmental geochemical baselines[J].Acta Pedologica Sinica,2019,56(2):408-419.
[7]赵元艺,曾辉,徐友宁,等.金属矿集区地球化学环境累积效应的理论与工作方法[J].地质通报,2014,33(8):1106-1113.Zhao Y Y,Zeng H,Xu Y N,et al.Theory and work methods for the cumulative effects of environmental geochemistry in the metallic deposit cluster[J].Geological Bulletin of China,2014,33(8):1106-1113.
[8]Faust J C,Scheiber T,Fabian K,et al.Geochemical characterisation of northern Norwegian fjord surface sediments:a baseline for further paleo-environmental investigations[J].Continental Shelf Research,2017,148:104-115.
[9]李艳,张薇薇,程永毅,等.重庆紫色母岩及土壤As、Hg环境地球化学基线研究[J].土壤学报,2017,54(4):917-926.Li Y,Zhang W W,Cheng Y Y,et al.Environmental geochemical baseline of As and Hg in purple soil and its parent rock in Chongqing[J].Acta Pedologica Sinica,2017,54(4):917-926.
[10]朱晓东,韦朝阳,杨芬.包头-白云鄂博地区重金属基线值的厘定及其在重金属污染分级评价中的应用[J].自然资源学报,2016,31(2):310-320.Zhu X D,Wei C Y,Yang F.Determination of heavy metal baseline in Baotou and Bayan Obo and its application in the assessment of heavy metal contamination[J].Journal of Natural Resources,2016,31(2):310-320.
[11]高杨,许东升,李琦.宿州市表层土壤重金属元素环境地球化学基线研究[J].地球与环境,2018,46(5):444-450.Gao Y,Xu D S,Li Q.A study on environmental geochemical baselines of heavy metals in the surficial soil of Suzhou[J].Earth and Environment,2018,46(5):444-450.
[12]Salminen R,Gregorauskiene V.Considerations regarding the definition of a geochemical baseline of elements in the surficial materials in areas differing in basic geology[J].Applied Geochemistry,2000,15(5):647-653.
[13]Sultan K,Shazili N A.Distribution and geochemical baselines of major,minor and trace elements in tropical topsoils of the Terengganu River basin,Malaysia[J].Journal of Geochemical Exploration,2009,103(2-3):57-68.
[14]王学求,周建,徐善法,等.全国地球化学基准网建立与土壤地球化学基准值特征[J].中国地质,2016,43(5):1469-1480.Wang X Q,Zhou J,Xu S F,et al.China soil geochemical baselines networks:data characteristics[J].Geology in China,2016,43(5):1469-1480.
[15]Salminen R,Tarvainen T.The problem of defining geochemical baselines.a case study of selected elements and geological materials in Finland[J].Journal of Geochemical Exploration,1997,60(1):91-98.
[16]王济,王世杰,欧阳自远.贵阳市表层土壤中镉的环境地球化学基线研究[J].环境科学,2007,28(6):1344-1348.Wang J,Wang S J,Ouyang Z Y.Geogenic distribution and baseline concentrations of cadmium in surficial soil of Guiyang,China[J].Environmental Science,2007,28(6):1344-1348.
[17]赵新儒,特拉津·那斯尔,程永毅,等.伊犁河流域土壤重金属环境地球化学基线研究及污染评价[J].环境科学,2014,35(6):2392-2400.Zhao X R,Nasier T,Cheng Y Y,et al.Environmental geochemical baseline of heavy metals in soils of the Ili River Basin and pollution evaluation[J].Environmental Science,2014,35(6):2392-2400.
[18]李超,杜哲,陈亚恒,等.环京津地区土地生态服务价值时空分异特征[J].土壤通报,2015,46(1):42-47.Li C,Du Z,Chen Y H,et al.Spatio-temporal differentiation of land ecosystem service value in the surrounding regions of Beijing and Tianjin[J].Chinese Journal of Soil Science,2015,46(1):42-47.
[19]Yu C J,Li H Q,Jia X P,et al.Improving resource utilization efficiency in China's mineral resource-based cities:a case study of Chengde,Hebei province[J].Resources,Conservation and Recycling,2015,94:1-10.
[20]Liu J Q,Yin P,Chen B,et al.Distribution and contamination assessment of heavy metals in surface sediments of the Luanhe River Estuary,northwest of the Bohai Sea[J].Marine Pollution Bulletin,2016,109(1):633-639.
[21]滕彦国,矫旭东,左锐,等.攀枝花矿区表层土壤中钒的环境地球化学研究[J].吉林大学学报(地球科学版),2007,37(2):278-283.Teng Y G,Jiao X D,Zuo R,et al.Environmental geochemistry of vanadium in topsoil in Panzhihua Mining Area[J].Journal of Jilin University(Earth Science Edition),2007,37(2):278-283.
[22]中华人民共和国生态环境部.生态环境损害鉴定评估技术指南土壤与地下水[R].北京:中华人民共和国生态环境部,2018.11-22.Ministry of Ecology and Environment of the People's Republic of China.Technical guidelines for identification and assessment of eco-environmental damage soil and groundwater[R].Beijing:Ministry of Ecology and Environment of the People's Republic of China,2018.11-22.
[23]滕彦国,倪师军,庹先国,等.应用标准化方法评价攀枝花地区表层土壤的重金属污染[J].土壤学报,2003,40(3):374-379.Teng Y G,Ni S J,Tuo X G,et al.Application of a normalization procedure in assessing heavy metal pollution in topsoil,Panzhihua Region[J].Acta Pedologica Sinica,2003,40(3):374-379.
[24]Guillén M T,Delgado J,Albanese S,et al.Environmental geochemical mapping of Huelva municipality soils(SW Spain)as a tool to determine background and baseline values[J].Journal of Geochemical Exploration,2011,109(1-3):59-69.
[25]Islam M S,Hossain M B,Matin A,et al.Assessment of heavy metal pollution,distribution and source apportionment in the sediment from Feni River estuary,Bangladesh[J].Chemosphere,2018,202:25-32.
[26]范凯,韦朝阳,杨晓松.长沙市乔口镇土壤重金属地球化学基线值的厘定及应用[J].环境科学学报,2014,34(12):3076-3083.Fan K,Wei C Y,Yang X S.Geochemical baseline of heavy metals in the soils of Qiaokou town,Changsha city and its application[J].Acta Scientiae Circumstantiae,2014,34(12):3076-3083.
[27]章海波,骆永明.区域尺度土壤环境地球化学基线估算方法及其应用研究[J].环境科学,2010,31(7):1607-1613.Zhang H B,Luo Y M.Researches on the estimate methods and applications of soil environmental geochemical baseline at a regional scale[J].Environmental Science,2010,31(7):1607-1613.
[28]Bauer I,Bor J.Lithogene,geogene und anthropogene schwermetallgehalte von l9b9den an den beispielen von Cu,Zn,Ni,Pb,Hg und Cd[J].Mainzer Geowiss Mitt,1995,24:47-70.
[29]Müller G.Index of geoaccumulation in sediments of the Rhine River[J].Geo Journal,1969,2(3):108-118.
[30]中国环境监测总站.中国土壤元素背景值[M].北京:中国环境科学出版社,1990.
[31]杨伟光,王美娥,陈卫平.新疆干旱区某矿冶场对周围土壤重金属累积的影响[J].环境科学,2019,40(1):445-452.Yang W G,Wang M E,Chen W P.Effect of a mining and smelting plant on the accumulation of heavy metals in soils in arid areas in Xinjiang[J].Environmental Science,2019,40(1):445-452.
[32]Cao X L,Diao M H,Zhang B G,et al.Spatial distribution of vanadium and microbial community responses in surface soil of Panzhihua mining and smelting area,China[J].Chemosphere,2017,183:9-17.
[33]郑睛之,王楚栋,王诗涵,等.典型小城市土壤重金属空间异质性及其风险评价:以临安市为例[J].环境科学,2018,39(6):2875-2883.Zheng J Z,Wang C D,Wang S H,et al.Spatial variation of soil heavy metals in Lin'an city and its potential risk evaluation[J].Environmental Science,2018,39(6):2875-2883.