Abstract
Purpose
The overall objectives of this study were to examine the relationship between the concentrations of heavy metals such as Pb, Zn, Cu, and Cd in roadside soil derived from three different geological parent materials, Hawkesbury Sandstone, Wianamatta Shale, and Mittagong Formation and also to examine the influence of rainfall events on heavy metal concentrations in both the topsoil and the subsoil in all three soil types. In this paper, the focus is on lead and zinc.
Materials and methods
The results obtained from the samples taken from an initial transect were used to select the location of the study sites. Soil samples were collected using a stainless steel auger at distances of 1, 5, and 10 m from the edge of two major roads of similar traffic volumes bordering a suburban park. At each of five study sites, samples were collected at depths of 0–10 and 10–30 cm, three times pre-rainfall (after extended periods of no rain) and three times post-rainfall (after intensive rainfall periods). The modified aqua regia digestion method was applied for heavy metal concentrations measurement. To determine the temporal dynamics of trace elements in the soils, sequential extractions were applied to all the topsoil samples according to the modified three-step sequential extraction procedure.
Results and discussion
The corresponding concentrations of Pb and Zn were different for the soil derived from Hawkesbury Sandstone and Wianamatta Shale and also Mittagong Formation. The highest concentration of Pb was in the soil from Wianamatta Shale, 159.32 mg/kg and the highest concentration of Zn was in the soil from the Mittagong Formation, 254.12 mg/kg, all at a distance of 1 m from the roadside. From the sequential chemical extraction results, the rainfall substantially influenced the exchangeable fraction (F1) of Pb at a distance from the road of 1 m. A significant reduction of F1 was found for the soil derived from Mittagong Formation which also had the most significant reduction of total Zn concentration.
Conclusions
The interpretation of the results showed that there was a clear correlation between the concentration of Pb and Zn with the distance from the roadside and depth in all soil types. However, the results also showed that there are variable concentrations between the soil types. The heavy metal concentrations at the same distance for the three soil types are different. The rainfall events do influence the heavy metal concentration differently in both topsoil and subsoil of the three soil types at the same distance from the roadside.
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References
Al-Chalabi AS, Hawker D (2000) Distribution of vehicular lead in roadside soils of major roads of Brisbane, Australia. Water Air Soil Pollut 118:299–310
Ayrault S, Roy-Barman M, Le Cloarec M-F, Priadi CR, Bonté P, Göpel C (2012) Lead contamination of the Seine River, France: geochemical implications of a historical perspective. Chemosphere 87:902–910
Azeez JO, Mesele SA, Sarumi BO, Ogundele JA, Uponi AO, Hassan AO (2014) Soil metal pollution as a function of traffic density and distance from road in emerging cities: a case study of Abeokuta, southwestern Nigeria. Arc Agron Soil Sci 60:275–295
Bakirdere S, Yaman M (2008) Determination of lead, cadmium and copper in roadside soil and plants in Elazig, Turkey. Environ Monit Assess 136:401–410
Chen X, Xia X, Zhao Y, Zhang P (2010) Heavy metal concentrations in roadside soils and correlation with urban traffic in Beijing, China. J Hazard Mater 181:640–646
Cicchella D, De Vivo B, Lima A, Albanese S, McGill R, Parrish RR (2008) Heavy metal pollution and Pb isotopes in urban soils of Napoli, Italy. Geochem: Explor, Environ, Anal 8:103–112
Curran-Cournane F, Lear G, Schwendenmann L, Khin J (2015) Heavy metal soil pollution is influenced by the location of green spaces within urban settings. Soil Res 53:306–315
Davis AP, Shokouhian M, Ni S (2001) Loading estimates of lead, copper, cadmium, and zinc in urban runoff from specific sources. Chemosphere 44:997–1009
De Silva S, Ball AS, Huynh T, Reichman SM (2015) Metal accumulation in roadside soil in Melbourne, Australia: effect of road age, traffic density and vehicular speed. Environ Pollut 208:102–109
Gaudino S, Galas C, Belli M, Barbizzi S, de Zorzi P, Jaćimović R, Jeran Z, Pati A, Sansone U (2007) The role of different soil sample digestion methods on trace elements analysis: a comparison of ICP-MS and INAA measurement results. Accred Qual Assur 12:84–93
Guney M, Onay TT, Copty NK (2010) Impact of overland traffic on heavy metal levels in highway dust and soils of Istanbul, Turkey. Environ Monit Assess 164:101–110
Hazelton P, Tille P (1990) Soil Landscapes of the Wollongong-Port Hacking 1: 100 000 Sheet Map. Soil Conservation Service of NSW, Sydney
Herbert C (1983) Sydney 1: 100 000 Geological Sheet 9130. Geological Survey of New South Wales, Sydney
Imperato M, Adamo P, Naimo D, Arienzo M, Stanzione D, Violante P (2003) Spatial distribution of heavy metals in urban soils of Naples city (Italy). Environ Pollut 124:247–256
Kadıoğlu YK, Üstündağ Z, Solak AO, Karabıyıkoğlu G (2010) Sources of Environmental Pollution in Ankara (Turkey): geochemistry and Traffic Effects—PEDXRF Applications. Spectroscopy Lett 43:247–257
Karim Z, Qureshi BA, Mumtaz M, Qureshi S (2014) Heavy metal content in urban soils as an indicator of anthropogenic and natural influences on landscape of Karachi—a multivariate spatio-temporal analysis. Ecol Ind 42:20–31
Karim Z, Qureshi BA, Mumtaz M (2015) Geochemical baseline determination and pollution assessment of heavy metals in urban soils of Karachi, Pakistan. Ecol Ind 48:358–364
Kaur R, Katnoria J (2014) Heavy metals and polycyclic aromatic hydrocarbons in roadside soil samples: a review. Int J Environ Ecol Geol Geophys Eng 8:331–341
Khan S, Khan MA, Rehman S (2011) Lead and cadmium contamination of different roadside soils and plants in Peshawar City, Pakistan. Pedosphere 21:351–357
Legret M, Pagotto C (2006) Heavy metal deposition and soil pollution along two major rural highways. Environ Technol 27:247–254
Li J, Pu L, Liao Q, Zhu M, Dai X, Xu Y, Zhang L, Hua M, Jin Y (2015) How anthropogenic activities affect soil heavy metal concentration on a broad scale: a geochemistry survey in Yangtze River Delta, Eastern China. Environ Earth Sci 73:1823–1835
Liu Y, Wang Z, Zhang L, Tian F, Liu C (2015) Spatial and temporal distribution of platinum group elements (PGEs) in roadside soils from Shanghai and Urumqi, China. J Soils Sediments 15:1947–1959
Loganathan P, Vigneswaran S, Kandasamy J (2013) Road-deposited sediment pollutants: a critical review of their characteristics, source apportionment, and management. Crit Rev Environ Sci Technol 43:1315–1348
Lu A, Wang J, Qin X, Wang K, Han P, Zhang S (2012) Multivariate and geostatistical analyses of the spatial distribution and origin of heavy metals in the agricultural soils in Shunyi, Beijing, China. Science Total Environ 425:66–74
Massas I, Ehaliotis C, Gerontidis S, Sarris E (2009) Elevated heavy metal concentrations in top soils of an Aegean island town (Greece): total and available forms, origin and distribution. Environ Monit Assess 151:105–116
Owusu G, Oteng-Ababio M (2015) Moving unruly contemporary urbanism toward sustainable urban development in Ghana by 2030. Am Behav Sci 59:311–327
Pueyo M, Mateu J, Rigol A, Vidal M, López-Sánchez JF, Rauret G (2008) Use of the modified BCR three-step sequential extraction procedure for the study of trace element dynamics in contaminated soils. Environ Pollut 152:330–341
Škrbić B, Đurišić-Mladenović N (2013) Distribution of heavy elements in urban and rural surface soils: the Novi Sad city and the surrounding settlements, Serbia. Environ Monit Assess 185:457–471
Sun Y, Zhou Q, Xie X, Liu R (2010) Spatial, sources and risk assessment of heavy metal contamination of urban soils in typical regions of Shenyang, China. J Hazard Mater 174:455–462
Roads and Traffic Authority New South Wales (2005) Traffic volume data for Sydney region 2005
Vural A (2013) Assessment of heavy metal accumulation in the roadside soil and plants of Robinia pseudoacacia, in Gumushane, Northeastern Turkey. Ekoloji 22:1–10
Wei B, Yang L (2010) A review of heavy metal contaminations in urban soils, urban road dusts and agricultural soils from China. Microchem J 94:99–107
Werkenthin M, Kluge B, Wessolek G (2014) Metals in European roadside soils and soil solution–a review. Environ Pollut 189:98–110
Wichmann H, Bahadir M (2015) Increase of platinum group element concentrations in soils and airborne dust during the period of vehicular exhaust catalysts introduction. In: Platinum metals in the environment, Springer, pp 153–161
Yan X, Zhang F, Zeng C, Zhang M, Devkota LP, Yao T (2012) Relationship between heavy metal concentrations in soils and grasses of roadside farmland in Nepal. Int J Environ Res Public Health 9:3209–3226
Yang T, Liu Q, Zeng Q, Chan L (2012) Relationship between magnetic properties and heavy metals of urban soils with different soil types and environmental settings: implications for magnetic mapping. Environ Earth Sci 66:409–420
Zhuang Z, Ball J (in prep): An investigation of factors influencing contamination concentrations beside a road. J Soils Sediments
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Zhao, Z., Hazelton, P. Evaluation of accumulation and concentration of heavy metals in different urban roadside soil types in Miranda Park, Sydney. J Soils Sediments 16, 2548–2556 (2016). https://doi.org/10.1007/s11368-016-1460-z
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DOI: https://doi.org/10.1007/s11368-016-1460-z