Source identification for potentially toxic metals using Pb isotopes and elemental ratios of road-deposited sediments, stream sediment, and soil from watershed in Busan, South Korea

Volume 4, Issue 3, June 2020     |     PP. 76-98      |     PDF (1203 K)    |     Pub. Date: November 25, 2020
DOI:    196 Downloads     5998 Views  

Author(s)

Hyeryeong JEONG, Environmental Research Center, Korea Institute of Ocean Science and Technology (KIOST), Busan, 49111, Republic of Korea; Department of Ocean Science (Oceanography), KIOST School, University of Science and Technology (UST), Daejeon, 34113, Republic of Korea
Jin Young CHOI, Environmental Research Center, Korea Institute of Ocean Science and Technology (KIOST), Busan, 49111, Republic of Korea
Kongtae RA, Environmental Research Center, Korea Institute of Ocean Science and Technology (KIOST), Busan, 49111, Republic of Korea; Department of Ocean Science (Oceanography), KIOST School, University of Science and Technology (UST), Daejeon, 34113, Republic of Korea

Abstract
Study on potentially toxic elements (PTEs; Cr, Ni, Cu, Zn, As, Cd, Sb, Pb and Hg) combined with Pb isotopes was conducted to evaluate the pollution status and to identify the sources of PTEs pollution in road-deposited sediments (RDS), soils and stream sediments in small watershed of Busan, Korea. Our results indicate that RDS was moderately to extremely polluted in Cu, Zn, Cd, Sb and Pb and highly polluted in sampling site with high traffic activity. According to the Igeo results, the Sb pollution caused by automobile brake pads was higher than that of other elements. Cd and Sb in RDS pose a serous ecological risk. The pollution degree of PTEs was in the order: RDS>stream sediment>soil. Pb isotopes of RDS of this study was clearly distinguished from the industrial region. In urban areas, traffic activities were found to have a larger contribution to PTEs pollution in RDS. 206Pb/207Pb ratio showed the lowest value in RDS and increased in the order of stream sediments and soils. In particular, the results of biplot between Pb isotope and Zu/Cu ratio showed that it was possible to distinguish between industrial and traffic activities. Our results indicate that RDS is one of the main sources of PTEs pollution in stream sediments. Therefore, efficient management, such as RDS cleaning, is very important to reduce PTEs contamination that migrates to the stream environment as a non-point source.

Keywords
potentially toxic elements, road-deposited sediments, soils, stream sediments, pollution

Cite this paper
Hyeryeong JEONG, Jin Young CHOI, Kongtae RA, Source identification for potentially toxic metals using Pb isotopes and elemental ratios of road-deposited sediments, stream sediment, and soil from watershed in Busan, South Korea , SCIREA Journal of Geosciences. Volume 4, Issue 3, June 2020 | PP. 76-98.

References

[ 1 ] Abbasi S, Keshavarzi B, Moore F, Mahmoudi MR (2018) Fractionation, source identification and risk assessment of potentially toxic elements in street dust of the most important center for petrochemical products, Asaluyeh County, Iran. Environ Earth Sci 77: 673
[ 2 ] Abu-Allaban M, Gillies J A, Gertler AW, Clayton R, Proffitt D (2003) Tailpipe, resuspended road dust, and brake-wear emission factors from on-road vehicles. Atmos Environ37: 5283-5293
[ 3 ] Adamiec E, Jarosz-Krzeminska E, Wiezala R (2016) Heavy metals from non-exhaust vehicle emissions in urban and motorway road dusts. Environ Monit Assess 188: 369.
[ 4 ] Ahmad HR, Mehmood K, Sardar MF, Maqsood MA, Rehman MZU, Zhu C, Li H (2019) Integrated risk assessment of potentially toxic elements and particle pollution in urban road dust of megacity of Pakistan. Hum Ecol Risk Assess 16: 1810-1831
[ 5 ] Amato F, Pandolfi M, Viana M, Querol X, Alastuey A, Moreno T (2009) Spatial and chemical patterns of PM10 in road dust deposited in urban environment. Atmos Environ 43: 1650-1659
[ 6 ] Amato F, Viana M, Richard A, Furger M, Prévôt ASH, Nava S, Lucarelli F, Bukowiecki N, Alastuey A, Reche C, Moreno T, Pandolfi M, Pey J, Querol X (2011) Size and time-resolved roadside enrichment of atmospheric particulate pollutants. Atmos Chem Phys 11: 2917-2931
[ 7 ] Baensch-Baltruschat B, Kocher B, Stock F, Reifferscheid G (2020) Tyre and road wear particles (TRWP) - a review of generation, properties, emissions, human health risk, ecotoxicity, and fate in the environment. Sci Total Environ 733: 137823
[ 8 ] Bhattacharya T, Chakraborty S, Tuteja D, Patel M (2013) Zinc and Chromium load in road dust, suspended particulate matter and foliar dust deposits of Anand city, Gujarat. Open J Metal 3: 42-50
[ 9 ] Bourotte CLM, Sugauara LE, De Marchi MRR, Souto-Oliveira CE (2019) Trace metal and PAHs in topsoils of the university campus in the megacity of Sao Paulo, Brazil. An Acad Bras Ciênc 91(3): e20180334
[ 10 ] Canadian Council of Ministers of the Environment (CCME) (2007) Soil quality guidelines for the protection of environmental and human health. CCME, ISBN 1-896997-34-1
[ 11 ] Cai K, Li C (2019) Street dust heavy metal pollution source apportionment and sustainable management in a typical city-Shijiazhung, China. Int J Environ Res Public Health 16(14): 2625
[ 12 ] Chen J, Wang W, Liu H, Ren L (2012) Determination of road dust loadings and chemical characteristics using resuspension. Environ Monit Assess 184: 1693-1709
[ 13 ] Cheng H, Li M, Zhao C, Li K, Peng M, Qin A, Cheng X (2014) Overview of trace metals in the urban soil of 31 metropolises in China. J Geochem Explor 139: 31-52
[ 14 ] Choi JY, Jeong H, Choi KY, Hong GH, Yang DB, Kim K, Ra K (2020) Source identification and implications of heavy metals in urban roads for the coastal pollution in a beach town, Busan Korea. Mar Pollut Bull 161: 111724
[ 15 ] Du Y, Gao B, Zhou H, Ju X, Hao H, Yin S (2013) Health risk assessment of heavy metals in road dusts in urban parks of Beijing, China. Procedia Environ Sci 18: 299-309
[ 16 ] Duong TT, Lee BY (2011) Determining contamination level of heavy metals in road dust from busy traffic areas with different characteristics. J Environ Manage 92: 554-562
[ 17 ] Duzgoren-Aydin NS (2007) Sources and characteristics of lead pollution in the urban environment of Guangzhou. Sci Total Environ 385: 182-195
[ 18 ] Faiz Y, Tufail M, Javed MT, Chaudhry MM, Siddique N (2009) Road dust pollution of Cd, Cu, Ni, Pb and Zn along Islamabad Expressway, Pakistan. Microchem J 91: 186-192
[ 19 ] Gmochowska W, Pietranik A, Tyszka R, Ettler V, Mihaljevič M, Długosz M, Walenczak K (2019) Sources of pollution and distribution of Pb, Cd, and Hg in Wroclaw soils: Insight from chemical and Pb isotope composition. Geochem 79: 434-445
[ 20 ] Grigoratos T, Martini G (2015) Brake wear particle emissions: a review, Environ Sci Pollut Res 22: 2491–2504
[ 21 ] Hakanson L (1980) An ecological risk index for aquatic pollution control. A sedimentological approach. Water Res 14: 975-1001
[ 22 ] Huang L, Rad S, Xu L, Gui L, Song X, Li Y, Wu Z, Chen Z (2020) Heavy metals distribution, sources and ecological risk assessment in Huixian wetland, South China. Water 12: 431
[ 23 ] Hwang HM, Fiala MJ, Park D, Wade TL (2016) Review of pollutants in urban road dust and stormwater runoff: part 1. Heavy metals released from vehicles. Int J Urban Sci 20: 334-360
[ 24 ] Ignatavičius G, Valskys V, Bulskaya I, Paliulis D, Zigmontienė A, Satkūnas J (2017) Heavy metal contamination in surface runoff sediments of the urban area of Vilnius, Lithuania. Estonian J Earth 66(1): 13-20
[ 25 ] Iijima A, Sato K, Yano K, Tago H, Kato M, Kimura H, Furuta N (2007) Particle size and composition distribution analysis of automotive brake abrasion dusts for the evaluation of antimony sources of airborne particulate matter. Atmos Environ 41: 4908-4919
[ 26 ] Jeong H, Ra K, Kim KT, Kim ES, Lee SY, Choi MS (2018) Tracing the pollution source using Pb isotopes in sediments of the coastal region surrounding the national industrial complex, Korea. J Coast Res SI85: 21-25
[ 27 ] Jeong H, Lee J, Choi JY, Kim KT, Kim ES, Sun C, Park JK, Ra K (2019) Study on dissolved and particulate heavy metals in stream water and stormwater runoff from Suyeong watershed in Busan special management area, Korea. J Korean Soc Mar Environ Energy 22(4): 203-214 (In Korean).
[ 28 ] Jeong H, Choi JY, Lee J, Lim J, Ra K (2020a) Heavy metal pollution by road-deposited sediments and its contribution to total suspended solids in rainfall runoff from intensive industrial areas. Environ Pollut 265: 115028
[ 29 ] Jeong H, Choi JY, Lim J, Shim WJ, Kim YO, Ra K (2020b) Characterization of the contribution of road deposited sediments to the contamination of the close marine environment with trace metals: Case of the port city of Busan (South Korea). Mar Pollut Bull 161: 111717
[ 30 ] Jeong H, Choi JY, Lee J, Ra K (2020c) Investigations of Pb and Cu isotopes to trace contamination sources from the artificial Shihwa Lake in Korea. J Coast Res SI95: 1122-1127
[ 31 ] Jose J, Srimuruganandam B (2020) Investigation of road dust characteristics and its associated health risks from urban environment. Environ Geochem Health 42: 2819-2840
[ 32 ] Kelepertzis E, Argyraki A, Chrastny V, Botsou F, Skordas K, Komarek M, Fouskas A (2020) Metal(loid) and isotopic tracing of Pb in soils, road and house dusts from the industrial area of Volos (central Greece). Sci Total Environ 725: 138300
[ 33 ] Khan K, Lu Y, Khan H, Istiaq M, Khan S, Waqas M, Wei L, Wang T (2013) Heavy metals in agricultural soils and crops and their health risks in Swat District, northern Pakistan. Food Chem Toxicol 58: 449-458
[ 34 ] Khalid N, Hussain M, Young HS (2018) Effects of road proximity on heavy metal concentrations in soils and common roadside plants in Southern California. Environ Sci Technol 25: 35257-35265
[ 35 ] Lanzerstorfer C (2020) Toward more intercomparable road dust studies. Crit Rev Env Sci Tec 1737472.
[ 36 ] Lin J, Wang D, Song B, Chen Z, Zhang X, Tang Y (2019) Source apportionment of Pb in a rice-soil system using field monitoring and isotope composition analysis. J Geochem Explor 204: 83-89
[ 37 ] Loganathan P, Vigneswaran S, Kandasamy J (2013) Road-deposited sediment pollutants: a critical review of their characteristics, source apportionment, and management. Crit Rev Env Sci Tec 43(13): 1315-1348
[ 38 ] Logiewa A, Miazgowicz A, Krennhuber K, Lanzerstorfer C (2020) Variation in the concentration of metals in road dust size fractions between 2 µm and 2mm: results from three metallurgical centres in Poland. Arc Environ Contam Toxicol 78: 46-59
[ 39 ] Lu X, Wanga L, Lei K, Huang J, Zhai Y (2009) Contamination assessment of copper, lead, zinc, manganese and nickel in street dust of Baoji, NW China. J Hazard Mater 161: 1058–1062
[ 40 ] Lu X, Wu X, Wang Y, Chen H, Gao P, Fu Y (2014) Risk assessment of toxic metals in street dust from a medium-sized industrial city of China. Ecotoxicol Environ Saf 106: 154-163
[ 41 ] Marshall S, Pettigrove V, Carew M, Hoffmann A (2010) Isolating the impact of sediment toxicity in urban streams. Environ Pollut 158: 1716–1725
[ 42 ] Muller G (1969) Index of geoaccumulation in sediments of the Rhine River. Geoj 2: 108-118
[ 43 ] Nazarpour A, Watts MJ, Madhani A, Elahi S (2019) Sources, spatial distribution and pollution assessment of Pb, Zn, Cu, and Pb, isotopes in urban soils of Ahvaz City, a semi-arid metropolis in Southwest Iran. Sci Rep 9: 5349
[ 44 ] Nemerow NL (1991) Stream, lake, estuary, and ocean pollution. New York, Unites State.
[ 45 ] Pio C, Mirante F, Oliveira C, Matos M, Caseiro A, Oliveria C, Querol X, Alves C, Martins N, Cerqueira M, Camoes F, Silva H, Plana F (2013) Size-segregated chemical composition of aerosol emissions in an urban road tunnel in Portugal. Atmos Environ 71: 15-25
[ 46 ] Ram SS, Kumar RV, Chaudhuri P, Chanda SC, Sudarshand M, Chakraborty A (2014) Physiochemical characterization of street dust and re-suspended dust on plant canopies: An approach for finger printing the urban environment. Ecol Indic 36: 334-338
[ 47 ] Rudnick RI, Gao S (2003) Composition of the continental crust. Treatise Geochem 3: 1-64
[ 48 ] Sinha A, Ischia G, Menapace C, Giaanella S (2020) Experimental characterization protocols for wear products from disc brake materials. Atm 11: 1102
[ 49 ] Suryawanshi PV, Rajaram BS, Bhanarkar AD, Chalapati Rao CV (2016) Determining heavy metal contamination of road dust in Delhi, India. Atmósfera 29(3): 221-234
[ 50 ] Świelik R, Strzelecka M, Trojanowska M (2013) Evaluation of traffic-related heavy metals emissions using noise barrier road dust analysis. Pol J Environ Stud 22(2): 561-567
[ 51 ] Thorpe A, Harrison RM (2008) Sources and properties of non-exhaust particulate matter from road traffic: a review. Sci Total Environ 400: 270-282
[ 52 ] Varrica D, Dongarra G, Sabatino G, Monna F (2003) Inorganic geochemistry of roadway dust from the metropolitan area of Palermo, Italy. Environ Geol 44: 222–230
[ 53 ] Wang N, Wang A, Kong L, He M (2018) Calculation and application of Sb toxicity coefficient for potential ecological risk assessment. Sci Total Environ 610-611: 167-174
[ 54 ] Wijaya AR, Ouchi AK, Tanaka K, Shinjo R, Ohde S (2012) Metal contents and Pb isotopes in road-side dust and sediment of Japan. J Geochem Explor 118: 68-76
[ 55 ] Yu R, Hu G, Yang Q, He H, Lin C (2016a) Identification of Pb sources using Pb isotopic compositions in the core sediments from Western Xiamen Bay, China. Mar Pollut Bull 113: 247-252
[ 56 ] Yu Y, Li Y, Li B, Shen Z, Stenstrom MK (2016b) Metal enrichment and lead isotope analysis for source apportionment in the urban dust and rural surface soil. Environ Pollut 216: 764-772
[ 57 ] Yuen JQ, Olin PH, Lim HS, Benner SG, Sutherland RA, Ziegler AD (2012) Accumulation of potentially toxic elements in road deposited sediments in residential and light industrial neighbourhoods of Singapore. J Environ Manage 101: 151-163
[ 58 ] Zhang H, Wang Z, Zhang Y, Ding M, Li L (2015) Identification of traffic-related metals and effects of different environments on their enrichment in soils along the Qinghai-Tibet highway. Sci Total Environ 521-522: 160-172