Abstract
Urban soils in medium- and large-sized cities generally have shown elevated contents of environmentally important trace metals (e.g. lead, copper, zinc). Such high concentrations in soils of green areas, mainly recreational areas, can be a source of potentially toxic elements and pose a risk for human health. Thus the availability of these contaminants is an essential control parameter, as it indicates potential plant uptake and their transfer to humans via inhalation of suspended dust, or direct ingestion (i.e. hand to mouth pathway), or consumption of contaminated foodstuff. Young children are the most sensitive segment of the population. Addition of amendments to the soil is a feasible technique to reduce the availability of trace metals. Accordingly, four urban soils of green areas of Seville (Spain), with relatively high lead contents and moderate copper and zinc contents, were amended in the laboratory with four inorganic materials [acid zeolite (AZ), sodium zeolite (SZ), Slovakite (SL), apatite (AP)], at two rates (1%, 5% w/w) and incubated for 1 year. Significant decreases in EDTA-extractable metal contents were observed in some of the treatments after adding the amendments even before the incubation begun, mainly for SL treatments. The amendment that produced the longest lasting immobilisation effect, compared to control treatments, was AZ at the higher rate. The effects of SZ and SL tended to decrease with time, while the AP effect was almost negligible after 3 months of ageing. This study confirms the feasibility of using certain inexpensive soil amendments to at least temporarily immobilise metals in urban soils for the purpose of protecting human health, especially that of young children.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References cited
Abrahams PW. 2002 Soils: their implications to human health. Sci Total Environ 291, 1–32.
Adriano DC. 2001 Trace Elements in Terrestrial Environments: Biogeochemistry, Bioavailability and Risk of Metals. Berlin Heidelberg New York: Springer, p. 9–24
Adriano DC, Wenzel WW, Vangronsveld J, Bolan NS. 2004 Role of assisted remediation in environmental cleanup. Geoderma 122, 121–142
Álvarez-Ayuso E, García-Sánchez A. 2003 Palygorskite as a feasible amendment to stabilize heavy metal polluted soils. Environ Pollut 125, 337–344
Boisson J, Ruttens A, Mench M, Vangronsveld J. 1999 Evaluation of hydroxyapatite as a metal immobilizing soil additive for the remediation of polluted soils. Part 1. Influence of hydroxyapatite on metal exchangeability in soil, plant growth and plant metal accumulation. Environ Pollut 104, 225–233
Brown S, Christensen B, Lombi E, McLaughlin M, McGrath S, Colpaert J, Vangronsveld J. 2005 An inter-laboratory study to test the ability of amendments to reduce the availability of Cd, Pb, and Zn in situ. Environ Pollut 138, 34–45
Bullock P, Gregory PJ. 1991 Soils in the urban environment. Blackwell, Oxford
Cao X, Ma LQ, Rhue DR, Appel CS. 2004 Mechanism of lead, copper and zinc retention by phosphate rock. Environ Pollut 131, 435–444
Castaldi P, Santona L, Melis P. 2005 Heavy metal immobilization by chemical amendments in a polluted soil and influence on white lupin growth. Chemosphere 60, 365–371
Chen ZS, Lee GJ, Liu JC. 2000 The effects of chemical remediation treatments on the extractability and speciation of cadmium and lead in contaminated soils. Chemosphere 41, 235–242
Davies DJA, Thornton I, Watt J, Culbard EB, Harvey PG, Delves HT, et al. 1990 Lead intake and blood lead in two year old UK urban children. Sci Total Environ 90, 13–29
De Miguel E., Llamas JF, Chacón E, Berg T, Larssen S, Royset O, Vadset M. 1997 Origin and patterns of distribution of trace elements in street dust: unleaded petrol and urban lead. Atmos Environ 31, 2733–2740
Edwards R, Rebedea I, Lepp NW, Lovell AJ. 1999 An investigation into the mechanism by which synthetic zeolites reduce labile metal concentrations in soils. Environ Geochem Health 21, 157–173
Fang G, Wu Y, Huang S, Rau J. 2005 Review of atmospheric metallic elements in Asia during 2000–2004. Atmos Environ 39, 3003–3013
Finster ME, Gray KA, Binns HJ. 2004 Lead levels of edibles grown in contaminated residential soils: a field survey. Sci Total Environ 320, 245–257
Friesi W, Lombi E, Horak O, Wenzel WW. 2003 Immobilization of heavy metals in soils using inorganic amendments in a greenhouse study. J Plant Nutr Soil Sci 166, 191–196
Gee GW, Bauder JW. 1986 Particle-size analysis. In Klute A, ed. Methods of Soil Analysis. Part 1. Physical and Mineralogical Methods, 2nd ed. Madison, WI: American Society of Agronomy, p. 383–411
Gupta SK, Vollmer MK, Krebs R. 1996 The importance of mobile, mobilisable and pseudo total heavy metal fractions in soil for three-level risk assessment and risk management. Sci Total Environ 178, 11–20
Gworek B. 1992 Lead inactivation in soils by zeolites. Plant Soil 143, 71–74
Hettiarachchi GM, Pierzynski GM, Ransom MD. 2001 In situ stabilization of soil lead using phosphorous. J Environ Qual 30, 1214–1221
Knox AS, Kaplan DI, Adriano DC, Hinton TG, Wilson MD. 2003 Apatite and phillipsite as sequestering agents for metals and radionuclides. J Environ Qual 32, 515–525
Li X, Poon C, Liu PS. 2001 Heavy metal contamination of urban soils and street dusts in Hong Kong. Appl Geochem 16, 1361–1368
Lombi E, Zhao F, Zhang G, Sun B, Fitz W, Zhang H, McGrath SP. 2002 In situ fixation of metals in soils using bauxite residue: chemical assessment. Environ Pollut 118, 435–443
Madrid L. 1999 Metal retention and mobility as influenced by some organic residues added to soils: a case study. In Selim HM, Iskandar IK, ed. Fate and Transport of Heavy Metals in the Vadose Zone. Boca Raton, FL: Lewis, p. 201–223
Madrid L, Díaz-Barrientos E, Reinoso R., Madrid F. 2004 Metals in urban soils of Seville: seasonal changes and relations with other soil components and plant contents. Eur J Soil Sci 55, 209–217
Melamed R, Cao X, Chen M, Ma LQ. 2003 Field assessment of lead immobilization in a contaminated soil after phosphate application. Sci Total Environ 305, 117–127
Mench M, Vangronsveld J, Lepp NW, Edwards R. 1998 Physico-chemical aspects and efficiency of trace element immobilization by soil amendments. In Vangronsveld J, Cunningham SD, eds. Metal Contaminated Soils: In Situ Inactivation and Phytorestoration. Georgetown, TX: Springer, p. 151–182
Mielke HW, Gonzales CR, Smith MK, Mielke PW. 1999 The urban environment and children’s health: Soil as an integrator of lead, zinc and cadmium in New Orleans, Louisiana, USA. Environ Res 81, 117–129
Miller RR. 1996 Phytoremediation. Technology Overview Report. Pittsburgh, PA: Ground Water Remediation Technologies Analysis Center
Ministero dell’Ambiente. 1999 Valori di Concentrazione Limite Accettabili nel Suolo en el Sottosuolo Rifferitti alla Specifica Sestinazione d’Uso dei Terreni da Bonificare. Decreto Ministeriale 471. Gazz Uff Rep Ital 293
Möller 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, 63–71
Oste LA, Lexmond TM, Van Riemsdijk WH. 2002a Metal immobilization in soils using synthetic zeolites. J Environ Qual 31, 813–821
Oste LA, Temminghoff EJM, Van Riemsdijk WH. 2002b The acid-solution partitioning of soil organic matter as influenced by an increase in pH or Ca. Environ Sci Technol 36, 208–214
Page AL, Miller RH, Keeney DR. 1982 Methods of Soil Analysis. Part 2. Chemical and Microbiological Properties, 2nd edn. Madison. WI: American Society of Agronomy
Quevauviller P, Lachica M, Barahona E, Rauret G, Ure A, Gómez A, Muntau H. 1997 The Certification of the EDTA-Extractable Contents (mass fraction) of Cd an Ni in Calcareous Soil by the Extraction Procedures Given. BCR Report EUR-17555-EN. Brussels: European Commission
Raicevic S, Kaludjerovic-Radoicic T, Zouboulis AI. 2005 In situ stabilization of toxic metals in polluted soils using phosphates: theoretical prediction and experimental verification. J Hazard Mater B 117, 41–53
Ruiz-Cortés E, Reinoso R, Díaz-Barrientos E, Madrid L. 2005 Concentrations of potentially toxic metals in urban soils of Seville: relationship with different land uses. Environ Geochem Health 27, 465–474
Sociedad Pública de Gestión Ambiental. 2002 Investigación de la Contaminación del Suelo, Manual Práctico. Bilbao: IHOBE/Gobierno Vasco
Ure AM, Quevauvillier PH, Muntau HJ, Griepink B. 1993 Speciation of heavy metals in soils and sediments. An account of the improvement and harmonization of extraction techniques undertaken under the auspices of the BCR of the Commission of the European Communities. Int J Environ Anal Chem 51, 135–151
Vangronsveld J, Cunningham SD. 1998 Introduction to the concepts. In Vangronsveld J, Cunningham SD, eds. Metal Contaminated Soils: In Situ Inactivation and Phytorestoration. Georgetown, TX: Springer, p. 1–15
Acknowledgement
The authors wish to thank the Ministerio de Educación y Ciencia for the financial support of this work under project REN 2002–03309.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Madrid, F., Romero, A.S., Madrid, L. et al. Reduction of availability of trace metals in urban soils using inorganic amendments. Environ Geochem Health 28, 365–373 (2006). https://doi.org/10.1007/s10653-005-9034-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10653-005-9034-9