Abstract
This study is a systematic analysis of the magnetic characteristics and heavy metal elements in soil samples collected from Lanzhou City, China. The 117 surface soil samples were measured to study the feasibility and effectiveness of environmental magnetism for evaluating heavy metal pollution in urban soils. Results of the study indicate that low-coercivity magnetite dominates the magnetic properties in the samples. The high values of the soil magnetic mineral concentration parameters and low values of magnetic particle size parameters are distributed throughout the northern area of Xigu District, the industrial zones of the eastern section of Chengguan District and the districts of the narrow sections connecting Chengguan District and the other three districts; these parameters are fundamentally consistent with the distribution of the high values of the Pollution Load Index and Nemerow Pollution Index. Semi-quantitative studies which use the environmental magnetic method to monitor pollution of heavy metals (such as As, Cr, Cu, Ni, Pb, Zn, and Fe) have shown that when χlf⩽35×10−8 m3 kg−1, it is unpolluted; when 35 ⩽ χlf<150×10−8 m3 kg−1, it is moderately polluted to unpolluted; when 150 ⩽ χlf<365×10−8 m3 kg−1, it is moderately polluted; when 365 ⩽ χlf<750×10−8 m3 kg−1, χfd%<2.7 and χARM/SIRM<0.2×10−3 m A−1, it is moderately to highly polluted; when χlf⩾750×10−8 m3 kg−1, χfd%<2.7 and χARM/SIRM<0.2×10−3 m A−1, it is highly polluted. The region of moderately to highly polluted distribution is caused by industry and vehicles, showing that the change of pollution in Lanzhou City bears the trend of “vehicle emission + industrial”.
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Kapička A, Petrovský E, Ustjak S, et al. Proxy mapping of fly-ash pollution of soils around a coal-burning power plant: A case study in Czech Republic. J Geochem Explor, 1999, 66: 291–297
Flanders P J. Identifying fly ash at a distance from fossil fuel power stations. Environ Sci Technol, 1999, 33: 528–532
Ďurža O. Heavy metals contamination and magnetic susceptibility in soil around metallurgical plant. Phys Chem Earth, 1999, 24: 541–543
Jeleńska M, Hasso-Agopsowicz A, Kopcewicz B, et al. Magnetic properties of the profiles of polluted and non-polluted soils. A case study from Ukraine. Geophys J Int, 2004, 159: 104–116
Hay K L, Dearing J A, Baban S M J, et al. A preliminary attempt to identify atmospherically derived pollution particles in English topsoils from magnetic susceptibility measurements. Phys Chem Earth, 1997, 22: 207–210
Blundell A, Dearing J A, Boyle J F, et al. Controlling factors for the spatial variability of soil magnetic susceptibility across England and Wales. Earth-Sci Rev, 2009, 95: 158–188
Blundell A, Hannam J A, Dearing J A, et al. Detecting atmospheric pollution in surface soils using magnetic measurements: A reappraisal using an England and Wales database. Environ Pollut, 2009, 157: 2878–2890
Canbay M, Aydin A, Kurtulus C. Magnetic susceptibility and heavy-metal contamination in topsoils along the Izmit Gulf coastal area and IZAYTAS (Turkey). J Appl Geophys, 2010, 70: 46–57
Karimi R, Ayoubi S, Jalalian A, et al. Relationships between magnetic susceptibility and heavy metals in urban topsoils in the arid region of Isfahan, central Iran. J Appl Geophys, 2011, 74: 1–7
Hanesch M, Scholger R. Mapping of heavy metal loadings in soils by means of magnetic susceptibility measurements. Environ Geol, 2002, 42: 857–870
Petrovský E, Kapička A, Jordanova N, et al. Magnetic properties of alluvial soils contaminated with lead, zinc and cadmium. J Appl Geophys, 2001, 48: 127–136
Zhang C X, Qiao Q Q, John D A, et al. Assessment of heavy metal pollution from a Fe-smelting plant in urban river sediments using environmental magnetic and geochemical methods. Environ Pollut, 2011, 159: 3057–3070
Desenfant F, Petrovský E, Rochette P. Magnetic signature of industrial pollution of stream sediments and correlation with heavy metals: Case study from South France. Water Air Soil Pollut, 2004, 152: 297–312
Jordanova D, Veneva L, Hoffmann V, et al. Magnetic susceptibility screening of anthropogenic impact on the Danube River Sediments in Northwestern Bulgaria—Preliminary results. Studia Geophys Geod, 2003, 47: 403–418
Evans M E, Heller F. Environmental Magnetism-Principles and Applications of Environmagnetics. New York: Acdemic Press, 2003. 1–299
Lauf R J, Harris L A, Rawlston S S. Pyrite framboids as the source of magnetic spheres in fly ash. Environ Sci Technol, 1982, 16: 218–220
Boyko T, Scholger R, Stanjek H, et al. Topsoil magnetic susceptibility mapping as a tool for pollution monitoring: Repeatability of in situ measurements. J Appl Geophys, 2004, 55: 249–259
Oldfield F, Hunt A, Jones M D H, et al. Magnetic differentiation of atmospheric dusts. Nature, 1985, 317: 516–518
Xia D S, Chen F H, Bloemendal J, et al. Magnetic properties of urban dustfall in Lanzhou, China, and itsenvironmental implications. Atmos Environ, 2008, 42: 2198–2207
Xia D S, Yang L P, Ma J Y, et al. Magnetic property of Lanzhou dustfall and its implication in urban pollution. Sci China Ser D-Earth Sci, 2007, 37: 1073–1081
Muxworthy A R, Schmidbauer E, Petersen N. Magnetic properties and Mössbauer spectra of urban atmospheric particulate matter: A case study from Munich, Germany. Geophys J Int, 2002, 150: 558–570
Goddu S R, Appel E, Jordanova D, et al. Magnetic properties of road dust from Visakhapatnam (India)—relationship to industrial pollution and road traffic. Phys Chem Earth, 2004, 29: 985–995
Wang G, Xia D S, Liu X M, et al. Spatial and temporal variation in magnetic propertiesof street dust in Lanzhou City, China. Chin Sci Bull, 2008, 53: 1913–1923
Wang G, Oldfield F, Xia D S, et al. Magnetic properties and correlation with heavy metals in urban street dust: A case study from the city of Lanzhou, China. Atmos Environ, 2012, 46: 289–298
Bućko M S, Magiera T, Johanson B, et al. Identification of magnetic particulates in road dust accumulated on roadside snow using magnetic, geochemical and micro-morphological analyses. Environ Pollut, 2011, 159: 1266–1276
Hu S Y, Duan X M, Shen M J, et al. Magnetic response to atmospheric heavy metal pollution recorded by dust-loaded leaves in Shougang industrial area, western Beijing. Chin Sci Bull, 2008, 53: 1555–1564
Maher B A, Moore C, Matzka J. Spatial variation in vehicle-derived metal pollution identified by magnetic and elemental analysis of roadside tree leaves. Atmos Environ, 2008, 42: 364–373
Zhang C X, Huang B C, Li Z Y, et al. Magnetic properties of high-road-side pine tree leaves in Beijing and their environmental significanc. Chin Sci Bull, 2006, 51: 1459–1468
Mclntosh G, Gómez-Paccard M, Osete M L. The magnetic properties of particles deposited on Platanus X Hispanica leaves in Madrid, Spain, and their temporal and spatial variations. Sci Total Environ, 2007, 382: 135–146
Zhang C X, Huang B C, John D A, et al. Biomonitoring of atmospheric particulate matter using magnetic properties of Salix matsudana tree ring cores. Sci Total Environ, 2008, 393: 177–190
Wang B, Xia D S, Yu Y, et al. Magnetic properties of urban dustfall and its environmental implications (in Chinese). J Lanzhou Univ, 2010, 46: 11–17
Wang B, Xia D S, Yu Y, et al. Use of environmental magnetism to monitor pollution in the river sediment of an urban area (in Chinese). Acta Sci Circumst, 2011, 31: 1979–1991
Jia J, Xia D S, Wei H T, et al. Magnetic properties of typical paleosol and loess stratum of western Loess Plateau and its signification to paleoclimate (in Chinese). J Lanzhou Univ, 2010, 46: 26–40
Thompson R, Oldfield F. Environmental Magnetism. London: Allen & Unwin, 1986. 1–34
Deng C L, Zhu R X, Jackson M J, et al. Variability of the temperature-dependent susceptibility of the Holocene eolian deposits in the Chinese Loess Plateau: A pedogenesis indicator. Phys Chem Earth, 2001, 26: 873–878
Liu Q S, Deng C L, Yu Y, et al. Temperature dependence of magnetic susceptibility in an argon environment: Implications for pedogenesis of Chinese loess/palaeosols. Geophys J Int, 2005, 161: 102–112
Xia D S, Ma J Y, Wang G, et al. Environmental magnetism concepts and their applications to environmental studies in arid regions, Northwest China (in Chinese). Front Earth Sci, 2006, 13: 168–179
Dearing J A, Dann R J L, Hay K L, et al. Frequency-dependent susceptibility measurements of environmental materials. Geophys J Int, 1996, 124: 228–240
China Environmental Monitoring Center. Chinese Soil Element Background Values (in Chinese). Beijing: China Environmental Science Press, 1990. 329–483
Tomlinson D L, Wilson J G, Harris C R, et al. Problems in the assessment of heavy metal levels in estuaries and the formation of a pollution index. Helgoland Mar Res, 1980, 33: 566–575
Angulo E. The Tomlinson pollution load index applied to heavy metal “Mussel-Watch” data: A useful index to assess coastal pollution. Sci Total Environ, 1996, 187: 19–56
Nemerow N L. Scientific stream pollution analysis. Script Book Co Washington D C, 1974. 1–358
Wang L, Liu D S, Lü H Y. Magnetic susceptibility properties of polluted soils. Chin Sci Bull, 2000, 45: 1723–1726
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Wang, B., Xia, D., Yu, Y. et al. Magnetic records of heavy metal pollution in urban topsoil in Lanzhou, China. Chin. Sci. Bull. 58, 384–395 (2013). https://doi.org/10.1007/s11434-012-5404-8
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DOI: https://doi.org/10.1007/s11434-012-5404-8