Geochemical studies on urban soil from two sampling depths in Tampere Central Region, Finland

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• 作者：Jaana Jarva (1)
  Rolf Tore Ottesen (2)
  Timo Tarvainen (1)
  
• 关键词：Geochemical baseline ; Soils ; Geochemical mapping ; Sampling depth ; Urban environment ; Finland
• 刊名：Environmental Earth Sciences
• 出版年：2014
• 出版时间：June 2014
• 年：2014
• 卷：71
• 期：11
• 页码：4783-4799
• 全文大小：
• 参考文献：1. Abrahams PW (2002) Soils: their implications to human health. Sci Total Environ 291:1-2 CrossRef
  2. Acosta JA, Faz Cano A, Arocena JM, Debela F, Martínez-Martínez S (2009) Distribution of metals in soil particle size fractions and its implication to risk assessment of playgrounds in Murcia city (Spain). Geoderma 149:101-09 CrossRef
  3. Ajmone-Marsan F, Biasioli M (2010) Trace elements in soils of urban areas. Water Air Soil Pollut 213:121-43 CrossRef
  4. Albanese S, Breward N (2011) Sources of anthropogenic contaminants in the urban environment. In: Johnson CC, Demetriades A, Locutura J, Ottesen RT (eds) Mapping the chemical environment of urban areas. John Wiley, Oxford, pp 116-27 CrossRef
  5. Albanese S, Cicchella D (2012) Legacy problems in urban geochemistry. Elements 8:423-28 CrossRef
  6. Andersson M, Ottesen RT, Volden T (2004) Building materials as a source of PCB pollution in Bergen. Sci Total Environ 325:139-44 CrossRef
  7. Andersson M, Ottesen RT, Haugland T (2006) Overv?kning av jordforurensning i Trondheim 1994-004 (Monitoring soil pollution in Trondheim 1994-004). NGU Rapport 2006.033 (in Norwegian)
  8. Andersson M, Ottesen RT, Langedal M (2010) Geochemistry of urban surface soils—Monitoring in Trondheim, Norway. Geoderma 156:112-18 CrossRef
  9. Backman B, Luoma S, Ruskeeniemi T, Karttunen V, Talikka M, Kaija J (2006) Natural occurrence of arsenic in the Pirkanmaa region in Finland. Geological Survey of Finland, Espoo
  10. Biasioli M, Gr?man H, Kralj T, Madrid F, Díaz-Barrientos E, Ajmone-Marsan F (2007) Potentially toxic elements contamination in urban soils: a comparison of three European cities. J Enviro Qual 36:70-9 CrossRef
  11. Bockheim JG (1974) Nature and properties of highly disturbed urban soils, Philadelphia, Pennsylvania. Paper presented before Div. S-5. Soil Science Society of America, Chicago, Illinois
  12. Carlon C (ed) (2007) Derivation methods of soil screening values in Europe. A review and evaluation of national procedures towards harmonization. European Commission, Joint Research Centre, Ispra, EUR 22805-EN. soils.jrc.ec.europa.eu/esdb_archive/eusoils_docs/other/EUR22805.pdf" class="a-plus-plus">http://eusoils.jrc.ec.europa.eu/esdb_archive/eusoils_docs/other/EUR22805.pdf. Accessed 22 August 2013
  13. Chen XD, Lu XW, Li LY, Yang G (2013) Spatial distribution and contamination assessment of heavy metals in urban topsoil from inside the Xi’an second ringroad, NW China. Environ Earth Sci 68:1979-988 CrossRef
  14. Chronopoulos J, Haidouti C, Chronopoulos-Sereli A, Massas I (1997) Variations in plant and soil lead and cadmium content in urban parks in Athens, Greece. Sci Total Environ 196:91-8 CrossRef
  15. Craul PJ (1985) A description of urban soils and their desired characteristics. J Arboricult 11:330-39
  16. De Vos W, Tarvainen T (Chief-eds), Salminen R, Reeder S, De Vivo B, Demetriades A, Pirc S, Batista MJ, Marsina K, Ottesen RT, O’Connor PJ, Bidovec M, Lima A, Siewers U, Smith B, Taylor H, Shaw R, Salpeteur I, Gregorauskiene V, Halamic J, Slaninka I, Lax K, Gravesen P, Birke M, Breward N, Ander EL, Jordan G, Duris M, Klein P, Locutura J, Bel-lan A, Pasieczna A, Lis J, Mazreku A, Gilucis A, Heitzmann P, Klaver G, Petersell V (2006) Geochemical atlas of Europe, part 2. Geological Survey of Finland, Espoo
  17. Douay F, Pruvot C, Roussel H, Ciesielski H, Fourrier H, Proix N, Waterlot C (2008) Contamination of urban soils in an area of Northern France polluted by dust emissions of two smelters. Water Air Soil Pollut 188:247-60 CrossRef
  18. El Khalil H, Schwarz C, Elhamiani O, Kubiniok J, Morel JL, Boularbah A (2008) Contribution of technic materials to the mobile fraction of metals in urban soils in Marrakech (Morocco). J Soils Sediments 8:17-2 CrossRef
  19. Fordyce F, Brown SE, Ander EL, Rawlins BG, O’Donnell KE, Lister TR, Breward N, Johnson CC (2005) GSUE: urban geochemical mapping in Great Britain. Geochem: Explor, Environ, Anal 5:325-36
  20. Government Decree on the Assessment of Soil Contamination and Remediation Needs (214/2007). http://www.finlex.fi/fi/laki/kaannokset/2007/en20070214.pdf. Accessed 26 Aug 2013
  21. Hatakka T (ed), Tarvainen T, Jarva J, Backman B, Eklund M, Huhta P, K?rkk?inen N, Luoma S (2010) Pirkanmaan maaper?n geokemialliset taustapitoisuudet. English summary: Geochemical baselines in Pirkanmaa area. Geological Survey of Finland, Report of Investigation 182
  22. ISO 11466:1995. Soil quality—extraction of trace elements soluble in aqua regia
  23. ISO 19258:2005. Soil quality. Guidance on the determination background values
  24. ISO/IEC 17025:2005. General requirements for the competence of testing and calibration laboratories
  25. IUSS Working Group WRB (2007) World reference base for soil resources 2006. First update 2007. World soil resources reports 103. FAO, Rome. http://www.fao.org/fileadmin/templates/nr/images/resources/pdf_documents/wrb2007_red.pdf. Accessed 21 Aug 2013
  26. Jartun M, Ottesen RT, Volden T (2002a) Jordforurensning i Troms? (Soil pollution in Troms?). NGU-report, 2002.041 (in Norwegian)
  27. Jartun M, Ottesen RT, Volden T, Jensen H, Andersson M, Alexander J (2002b) Forebyggende arbeid—Jordforurensning i sm? barns utelekemilj? i Troms?. (Preventive work—Soil pollution in small children’s playgrounds in Troms?). NGU-report, 2002.053 (in Norwegian)
  28. Jarva J, Tarvainen T (2008) Tampereen seudun taajamien taustapitoisuudet: Esiselvitys (Geochemical baselines in urban areas of Tampere Central Region: Preliminary survey) Geological Survey of Finland, Archive Report S41/2008/36 (in Finnish)
  29. Jarva J, Tarvainen T, Reinikainen J, Eklund M (2010) TAPIR—Finnish national geochemical baseline database. Sci Total Environ 408:4385-395 CrossRef
  30. Johnson CC, Demetriades A (2011) Urban geochemical mapping: a review of case studies in this volume. In: Johnson CC, Demetriades A, Locutura J, Ottesen RT (eds) Mapping the chemical environment of urban areas. John Wiley, Oxford, pp 7-7 CrossRef
  31. K?hk?nen Y (2005) Svecofennian supracrustal rocks. In: Lehtinen M, Nurmi P, R?m? T (eds) Precambrian bedrock of Finland—Key to the evolution of the Fennoscandian shield. Elsevier, Amsterdam, pp 343-06 CrossRef
  32. Kampstra P (2008) Beanplot: a boxplot alternative for visual comparison of distributions. J Stat Softw 28:1-
  33. Koljonen T (ed) (1992) The geochemical atlas of Finland. Part 2: Till. Geological Survey of Finland, Espoo
  34. Massas I, Ehaliotis C, Kalivas D, Panagopoulou G (2010) Concentrations and availability indicators of soil heavy metals; the case of children’s playgrounds in the city of Athens (Greece). Water Air Soil Pollut 212:51-3 CrossRef
  35. Mielke HW, Anderson JC, Berry KJ, Mielke PW Jr, Chaney R (1983) Lead concentrations in inner city soils as a factor in the child lead problem. Am J Public Health 73:1366-369 CrossRef
  36. Mielke HW, Alexander J, Langedal M, Ottesen RT (2011) Children, soil and health: how do polluted soils influence children’s health. In: Johnson CC, Demetriades A, Locutura J, Ottesen RT (eds) Mapping the chemical environment of urban areas. John Wiley, Oxford, pp 134-50 CrossRef
  37. Ministry of the Environment (2007) Maaper?n pilaantuneisuuden ja puhdistustarpeen arviointi. English Abstract: Assessment of soil contamination and the remediation need. Environmental administration guidelines 2, Helsinki
  38. M?ller A, Müller HW, Abdullah A, Abdelgawad G, Utermann J (2005) Urban soil pollution in Damascus, Syria: concentrations and patterns of heavy metals in the soils of the Damascus Ghouta. Geoderma 124:63-1 CrossRef
  39. Morton-Bermea O, Hernández-àlvarez E, González-Hernández G, Romero F, Lozano R, Beramendi-Orosco LE (2009) Assessment of heavy metal pollution in urban topsoils from the metropolitan area of Mexico City. J Geochem Explor 101:218-24 CrossRef
  40. Ottesen RT, Langedal M (2001) Urban geochemistry in Trondheim, Norway. Norges geologiske unders?kelse, Bulletin 438:63-9
  41. Ottesen RT, Volden T (1999) Jordforurensning i Bergen (Soil pollution in the city of Bergen). Trondheim: NGUreport 99.022 (in Norwegian)
  42. Ottesen RT, Almklov PG, Tijhuis L (1995) Innhold av tungmetaller og organiske milj?gifter i overflatejord fra Trondheim (Levels of metals and organic compounds in surface soil from Trondheim). Trondheim municipality report TM 95/06 (in Norwegian)
  43. Ottesen RT, Langedal M, Cramer J, Elvebakk H, Finne TE, Haugland T, J?ger ?, Longva O, Storsand M, Volden T (2000) Forurenset grunn og sedimenter I Trondheim: Dataraport (Polluted soil and sediments in Trondheim municipality: Data report). Trondheim, NGUreport 2000.115 (in Norwegian)
  44. Ottesen RT, Alexander J, Langedal M, Haugland T, H?ygaard E (2008a) Soil pollution in day-care centers and playgrounds in Norway: national action plan for mapping and remediation. Environ Geochem Health 30:623-37 CrossRef
  45. Ottesen RT, Haugland T, Andersson M (2008b) Veileder for unders?kelse av jordforurensning i eksisterende barnehager og lekeplasser (Guidelines for soil pollution investigations in existing day-care centres and playgrounds). Norwegian Pollution Control Authority, Oslo, TA-2260/2007 (in Norwegian)
  46. Ottesen RT, Alexander J, Mikarlsen G, Langedal M (2011) Clean soil at child-care centres and public playgrounds—An important part of Norway’s chemical policy. In: Johnson CC, Demetriades A, Locutura J, Ottesen RT (eds) Mapping the chemical environment of urban areas. John Wiley, Oxford, pp 497-20 CrossRef
  47. Peltola P, ?str?m M (2003) Urban geochemistry: a multimedia and multielement survey of a small town in Northern Europe. Environ Geochem Health 25:397-19 CrossRef
  48. Reimann C, Filzmoser P, Garrett R, Dutter R (2008) Statistical data analysis explained: Applied environmental statistics with R. John Wiley, Oxford CrossRef
  49. Reinikainen J (2007) Maaper?n kynnys- ja ohjearvojen m??ritysperusteet. English Abstract: Derivation basis of threshold and guideline values for soil. The Finnish Environment 23. Finnish Environment Institute, Helsinki
  50. Reinikainen J (2008) Experiences on risk-based assessment of soil contamination and remediation needs. In: 2nd Joint Nordic meeting on remediation of contamination sites, Short Papers. Helsinki, Finland
  51. Salla A (1999) Maaper?n haitta-aineiden taustapitoisuudet Helsingiss?. (Background levels of harmful substances in the soils of Helsinki). Environment centre of city of Helsinki, Publications 15/1999 (in Finnish)
  52. Salminen R (ed) (1995) Alueellinen geokemiallinen kartoitus Suomessa 1982-994. English summary: regional geochemical mapping in Finland in 1982-994. Geological Survey of Finland, Report of Investigation 130
  53. Salonen V-P, Korkka-Niemi K (2007) Influence of parent sediments on the concentration of heavy metals in urban and suburban soils in Turku, Finland. Appl Goechem 22:906-18 CrossRef
  54. Shi W, Wang J (2013) Comparison of different methods for assessing heavy metal contamination in street dust of Xianyang City, NW China. Environ Earth Sci 68:2409-415 CrossRef
  55. Tarvainen T (ed.), Eklund M, Haavisto-Hyv?rinen M, Hatakka T, Jarva J, Karttunen V, Kuusisto E, Ojalainen J, Ter?svuori E (2006) Alkuaineiden taustapitoisuudet p??kaupunkiseudun kehyskuntien maaper?ss?. English Summary: Geochemical baselines around the Helsinki metropolitan area. Geological Survey of Finland, Report of Investigation 163
  56. Tarvainen T, Jarva J (2009).Ymp?rist?geokemialliset platinaryhm?n metallitutkimukset Espoon ja Helsingin alueella v. 1998-009 (Environmental geochemical studies on PGE-group metals in Espoo and Helsinki, 1998-009). Geological Survey of Finland, Archive Report S41/2009/41 (in Finnish)
  57. Tarvainen T, Jarva J (2011) Using geochemical baselines in the assessment of soil contamination in Finland. In: Johnson CC, Demetriades A, Locutura J, Ottesen RT (eds) Mapping the chemical environment of urban areas. John Wiley, Oxford, pp 223-31 CrossRef
  58. Tarvainen T, Jarva J, Kahelin H (2009) Geochemical baselines in relation to analytical methods in the It?-Uusimaa and Pirkanmaa regions, Finland. Geochem: Explor, Environ, Anal 9:81-2
  59. Tarvainen T, Luoma S, Hatakka T (2013) Tampereen taajama-alueiden maaper?n taustapitoisuudet. (Geochemical baselines in urban areas of the city of Tampere). Geological Survey of Finland, Archive Report 128/2013 (in Finnish)
  60. Thornton I (1993) Environmental geochemistry and health in the 1990s: a global perspective. Appl Geochem 8:203-10 CrossRef
  61. Tijhuis L, Brattali B, S?ther OM (2002) A geochemical survey of topsoil in the city of Oslo, Norway. Environ Geochem Health 24:67-4 CrossRef
  62. Varrica D, Dongarrá G, Sabatino G, Monna F (2003) Inorganic geochemistry of roadway dust from the metropolitan area of Palermo, Italy. Environ Geol 40:222-30
  63. Wichmann H, Anquandah GAK, Schmidt C, Zachmann D, Bahadir MA (2007) Increase of platinum group element concentrations in soils and airborne dust in an urban area in Germany. Sci Total Environ 388:121-27 CrossRef
  64. Wong CSC, Li X, Thornton I (2006) Urban environmental geochemistry of trace metals. Environ Pollut 142:1-6 CrossRef
  
• 作者单位：Jaana Jarva (1)
  Rolf Tore Ottesen (2)
  Timo Tarvainen (1)
  
  1. Geological Survey of Finland, Betonimiehenkuja 4, 02150, Espoo, Finland
  2. Geological Survey of Norway, P.O. Box 6315, 7491, Trondheim, Norway
  
• ISSN：1866-6299

文摘

Preliminary geochemical mapping was carried out within urban areas in Tampere Central Region, Finland, to gain a better understanding of element concentrations in urban soil and to provide information on baselines in soil within urban centres for soil contamination assessment purposes. The soil samples were taken from central city parks, day-care centres and school yards, and residential areas. Various sampling depths have generally been used in urban geochemical surveys. The aim of this study was to compare the results from two commonly used sample types taken from the same sites in urban soil: single samples of minerogenic topsoil from the 0-5?cm layer and composite samples of minerogenic topsoil from a depth of 0-?cm. The concentrations of most of the studied trace elements showed a significant correlation between samples from 0 to 2 and 0 to 25?cm, but element concentrations differed between the two studied sample depths. For most of the studied elements, the median concentrations were higher in the 0-5?cm samples, but anomalous concentrations were more often found in the 0-?cm samples. Some elements had elevated concentrations when compared with the Finnish guideline values for soil contamination assessment. This study did not conclusively establish whether a sampling depth of 0- or 0-5?cm should be recommended for similar studies in the future. Selection of the sampling depth in geochemical studies greatly depends on the aim of the project. In order to determine the upper limits of geochemical baseline variation, the deeper sampling depth appears to be more feasible. However, for the preliminary health risk assessment of areas with sensitive land uses, e.g. children’s playgrounds, samples from 0-?cm depth are considered informative. Such samples may also be used to indicate local sources of dusting creating site-specific hotspots of potentially harmful elements in urban topsoil.