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Mondal, Supriya
- Magnetic Susceptibility as a Proxy for Pollution in Triveni-Bandel Area, Hooghly District, West Bengal, India
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PDF Views:73
Authors
Supriya Mondal
1,
Saurodeep Chatterjee
1,
Rimjhim Maity
1,
Debesh Gain
1,
Ayanangshu Das
1,
Saikat Sinha
1
Affiliations
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
Source
Current Science, Vol 112, No 11 (2017), Pagination: 2306-2311Abstract
This study aims at tracing the distribution and concentration of contaminants in fly ash along roads and highways with appreciable traffic by using magnetic proxies. Magnetic susceptibility is used for pollution mapping in the field. The distribution of susceptibility values represents polluted areas strongly influenced by traffic frequency, roadside topography, meteorological conditions (e.g. wind direction) and other factors. A magnetic phase was found to be responsible for the enhancement of magnetic signal in roadside ash. Magnetic methods provide effective tools for delineation of industrial pollution such as fly ash. In the area studied, magnetic susceptibility proved to be an excellent proxy for analysis of intensity of pollution yielding interesting results.Keywords
Bandel, Fly Ash, Magnetic Proxies, Magnetic Susceptibility, Pollution.References
- Morris, W. A., Versteeg, J. K., Marvin, C. H., McCarry, B. E. and Rukavina, N. A., Preliminary comparisons between magneticsusceptibility and polycyclic aromatic hydrocarbon contentin sediments from Hamilton harbour, western Lake Ontario. Sci. Total Environ., 1994, 152, 153–160.
- LfU-Landesanstalt für Umweltschutz., Schwebstaubbelastungin BadenWuerttemberg. LfUBericht, Karlsruhe, 1998, 117.
- Hoffmann, V., Hanzlik, M., Wildner, M., Horn, P. and Fehr, K. Th., Cigarette-lighters: a significant source of anthropogenic magnetic and REE bearing aerosol particles – a potential health risk? Geol. Karpath., 1998, 49/3, 235–236.
- Hoffmann, V., Knab, M. and Appel, E., Magnetic susceptibility mapping of roadside pollution. J. Geochem. Explor., 1999, 66, 313–326.
- Leven, C., Hoffmann, V., Knab, M., Appel, E., Schaefer, R. and Beck, R., PGE (platinum group elements) contamination of roadside soils: magnetic parameters as a proxy? Geol. Karpath., 1998, 49/3, 238.
- Versteeg, J. K., Morris, W. A. and Rukavina, N. A., The utility of magnetic properties as a proxy for mapping contamination in Hamilton Harbour sediment. J. Great Lakes Res., 1995, 21, 71–83.
- Versteeg, J. K., Morris, W. A. and Rukavina, N. A., Distribution of contaminated sediment in Hamilton Harbour as mapped by magnetic susceptibility. Geosci. Can., 1996, 22/4, 145–151.
- Dekkers, M. J. and Pietersen, H. S., Magnetic properties of low-Ca fly-ash: a rapid tool for Fe-assessment and a survey for potentially hazardous elements. Mater. Res. Soc. Symp. Proc., 1992, 245, 37–47.
- Knab, M., Hoffmann, V., Appel, E., Jordanova, N. and Beck, R., Magnetic mapping of roadside pollution and correlationwith heavy metals. Geol. Karpath., 1998, 49/3, 237.
- Nature of Flow Patterns of Rajahmundry Lava, Gowripatnam Area, West Godavari, India:Insights from AMS Studies
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Authors
Affiliations
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
Source
Current Science, Vol 113, No 09 (2017), Pagination: 1719-1728Abstract
Anisotropy of magnetic susceptibility (AMS) data for a single basaltic lava flow, herein named the Gowripatnam lava flow from the Rajahmundry Traps, are evaluated for determining precisely the mechanism of lava flow. At Rajahmundry, lava flows are found on both banks of the Godavari River and sandwich intertrappean sedimentary layers in between. The ones on the west bank of the river are studied here. This study has an implication as the mechanism of lava flow or nature of lava flow patterns of Rajamundry Trap basalt is still a debatable issue. AMS directions is a powerful tool for investigating the source and direction of lava. Its application to single lava flow from Rajahmundry indicates maximum direction of susceptibility axes in almost all possible directions, indicating radial flowage from radial vent source(s). Two AMS directions (towards north-west – 14%, and north – 7%), however, have the maximum number of petals. This indicates that at least there were palaeo-flowage patterns towards these directions. Incidentally the Godavari lineament strikes NW–SE and the flow dip is due south. However, the two dominant magnetic lineation directions are due north. Hence, the possibility of the earlier suggested river piracy model for lava flow can be ruled out. The fissure eruption near Rajahmundry is pointed out as the then prevailing lava flow mechanism. This is further supported by an overall random distribution of maximum susceptibility axes apart from two dominant flow directions.Keywords
Anisotropy of Magnetic Susceptibility, Long Distance Lava Flowage, Rajahmundry Traps, Fe–Ti Oxides.References
- Pascoe, E. H., A Manual of the Geology of India and Burma, Calcutta, Govt of India Press, 1964, p. 2130.
- Knight, K. B., Renne, P. G., Halkett, A. and White, N., 40Ar/39Ar dating of the Rajahmundry Traps, eastern India and their relationship to the Deccan Taps. Earth Planet. Sci. Lett., 2003, 208, 85–99.
- Bakshi, A. K., The Deccan trap Palaeogene–Cretaceous boundary connection; new 40Ar/39Ar ages and critical assessment of existing argon data pertinent to this hypothesis. J. Asian Earth Sci., 2014, 84, 9–23.
- Keller, G., Adatte, T., Gardin, S., Bartolini, A. and Bajpai, S., Main Deccan volcanism phase ends near the K–T boundary: evidence from the Krishna–Godavari basin, SE India. Earth Planet. Sci. Lett., 2008, 268, 293–311.
- Self, S., Thordarson, T., Widdowson, M. and Jay, A., Volatile fluxes during flood basalt eruptions and potential effects on the global environment: a Deccan perspective. Earth Planet. Sci. Lett., 2006, 248, 518–532.
- Krishnan, M. S., Geology of India and Burma, Higginbothams, Madras, 1960, p. 604.
- Baksi, A. K., Byerly, G. R., Chan, L. H. and Ferar, E., Intracanyan flows in the Deccan province India? Case history of the Rrajahmundry Traps. Geology, 1994, 22, 605–608.
- Self, S., Jay, A. E., Widdowson, M. and Keszthelyi, Correlation of the Deccan and Rajahmundry Trap lavas: are these the longest lava flows on Earth? J. Volcanol. Geotherm. Res., 2008, 172, 3–19.
- Jay, A. E. and Widdowson, M., Stratigraphy, structure and volcanology of southeast Deccan continental flood basalt province: implication for eruptive extent and volumes. J. Geol. Soc. London, 2008, 165, 177–188.
- Reddy, P. R., Venkateswarulu, N., Prasad, A. S. S. S. R. S. and Koteswar Rao, P., Basement structure below the coastal belt of Krishna–Godavari basin: correlation between seismic structure and well information. Gondwana Res., 2002, 5, 513–518.
- Misra, K. S., Arterial system of Lava tubes and channels within Deccan volcanics of western India. J. Geol. Soc. India, 2002, 59, 115–124.
- Misra, K. S., Distribution pattern, age and duration and mode of eruption of Deccan and associated volcanics, Gondwana Geol. Spec. Mag., 2005, 8, 53–60.
- Kale, V. S. and Rajaguru, S. N., Morphology and denudation chronology of the coastal and upland river basins of western Deccan trappean landscape (India): a collation. Zeit. Geomorphal. NF, 1988, 32, 311–327.
- Lakshminarayana, G., Manikyamba, C., Khanna, T. C., Kanakdande, P. P. and Raju, K., New observations on Rajahmundry Traps of the Krishna–Godavari Basin. Geol. Soc. India, 2010, 75, 807–819.
- Baksi, A. K., Search for a deep mantle component in mafic lavas using a Nb–Y–Zr plot. Can. J. Earth Sci., 2001, 38, 813–824.
- Caffon-Tapia, E., Walker, G. P. L. and Herrero-Bervera, E., The internal structure of lava flows – insights from AMS measurements I: near–vent a’a, J. Volcanol. Geoth. Res., 1996, 70, 21–26.
- Caffon-Tapia, E., Anisotropy of magnetic susceptibility of lava flows and dykes: a historical account. Geol. Soc., London, Special Publ., 2004, 238, 205–225.
- Lakshminarayana, G., Evolution in basin-fill style during the mesozoic gondwana continental break-up in the Godavari Triple junction, SE India. J. Gondwana Res., 2002, 5, 227–244.
- Lakshminarayana, G., Proterozoic intracratonic rift development at right angle to the eastern ghat mobile belt an example for collision induced rifting in SE India. Curr. Sci., 1997, 73, 444–450.
- Lakshminarayana, G., Stratigraphy and structural framework of the gondwana sediments in the Pranhita-Godavari Valley, Andhra Pradesh. In Proceedings of the IX International Gondwana Symposium, 1996, vol. 1, pp. 311–330.
- Lakshminarayana, G., Gondwana sedimentation in the Chintalapudi sub-basin, Godavari valley, Andhra Pradesh. J. Geol. Soc. India, 1995, 64, 375–389.
- Lakshminarayana, G., Fluvial to estuarine transitional depositional setting in the Cenozoic Rajahmundry formation, K–G basin, India. Indian Miner., 1995, 49, 163–176.
- Veevers, J. J. and Ttewari, R. C., Gondawana master basin of peninsular India between Tethys and the interior of the Gondwana land province of Pangea. Memoir Geol. Soc. Am., 1995, 87, 1–62.
- Nagata, T., Rock Magnetism, Maruzen, Tokyo, 1961, 2nd edn, p. 350.
- Balsley, J. R. and Buddington, A. F., Magntic susceptibility anisotropy and fabric of some Adirondack granites and orthogenesis. Am. J. Sci., 1960, 258A, 6–20.
- Stacey, F. D., Joplin, G. and Lindsay, J., Magnetic anisotropy and fabric of some foliated rocks from S.E. Australia. Geophys. Pura Appl., 1960, 47, 30–40.
- Hrouda, F., Magnetic anisotropy of rocks and its application in geology and geophysics. Geophys. Surveys, 1982, 5, 37–82.
- Jelinek, V., Characterization of the magnetic fabric of rocks. Tectonophysics, 1973, 79, 7–63.
- Tarling, D. and Hrouda, F., Magnetic Anisotropy of Rocks, Springer, 1993, pp. 14–27.
- Buddington, A. F. and Lindsley, D. H., Iron–titanium oxide minerals and synthetic equivalents. J. Petrol., 1964, 5, 310–357.
- Haggerty, S. E., Opaque mineral oxides in terrestrial igneous rocks. In Oxide minerals. Mineral. Soc. Am., Short Course Notes, 1976, 3, hg101–hg300.
- Duraiswami, R., Gadpallu, P., Shaikh, T. N. and Cardin, N., Pahoehoe–a0a transitions in the lava flow fields of the western Deccan Traps, India-implications for emplacement dynamics, flood basalt architecture and volcanic stratigraphy. J. Asian Earth Sci., 2014, 84, 146–166.
- Adirondack granites and orthogenesis. Am. J. Sci., 258A, 1960, 6–20.
- Akimoto, T., Kinoshita, H. and Furuta, T., Electron probe micro-analysis study on process of low temperature oxidation of titanomagnetite. Earth Planet. Sci. Lett., 1984, 71, 263–278.
- Banerjee, P. K., Ghose, N. C., Ravikumar, V. and Chacko S., Petrography, geomagnetism, and rare-earth element abundances of the Rajahmundry lavas, eastern India. J. Southeast Asian Earth Sci., 1996, 13, 139–143.
- Flinn, D., On folding during three-dimensional progressive deformation. Geol. Soc. London Q. J., 1962, 18, 385–433.
- Johnson, H. P. and Melson, W. G., Electron microprobe analyses of some titanomagnetite grains form Hole 395A. Initial Rep. Deep-Sea Drilling Project, 1978, 45, 575–579.
- Krishnan, M. S., Limestone and ochre near kovvur and Rajahmundry, Madras Presidency. Geol. Surv. India Record, 1950, 81, 297–314.
- Prevot, M., Remond, G. and Caye, R., Etude de la transformation d’une titanomagnetite en titanomaghemite dans une roche volcanique. Bull. Soc. Fr. Miner. Cristallogr., 1968, 91, 65.
- Sen, B. and Sabale, A. B., Flow-types and lava emplacement history of Rajahmundry Traps, west of River Godavari, Andhra Pradesh. J. Geol. Soc. India, 2011, 78, 457–467.
- Subbarao, K. V., Walsh, J. N., Dayal A. M., Zachariah, J. and Gopalan, K., Enriched mantle at east Coast Rajahmundry, of India (abstract). In Proceedings of the Conference on Isotopes in the Solar System, PRL, Ahmedabad, India, 1997, p. 123.
- Magneto-Mineralogical Characterization and Manifestations of Magnetic Fabrics from the Gneissic Rocks and Associated Intrusive Bodies in and around Bankura and Purulia Districts, West Bengal, India
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Authors
Affiliations
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
1 Department of Geological Sciences, Jadavpur University, Kolkata 700 032, IN
Source
Current Science, Vol 114, No 09 (2018), Pagination: 1894-1902Abstract
The present study aims to unravel the mineralogical, chemical and anisotropy of magnetic susceptibility (AMS) from gneissic rocks and associated pegmatitic bodies from Bankura–Purulia region, West Bengal (India). Petrographic studies were done to detect the textural relationship of minerals that contribute susceptibility with that of the silicates. The study of polished thin-sections under reflected light microscope showed the presence of titano-magnetite and magnetite as dominant magnetic minerals. More than one generation of magnetic minerals were found which are linked to different conditions of temperature and tectonics that prevailed during their oxidation. AMS studies depicted the overall nature of magnetic fabrics (and other related parameters like mean susceptibility, magnetic foliation, magnetic lineation, corrected degree of anisotropy, shape parameter) in the region. The susceptibility ellipsoids were dominantly oblate in the region as evident from the Pj–Tj plots. The absence of linear relationship between mean susceptibility and degrees of anisotropy proves that the fabrics are independent of bulk ferromagnetic susceptibility and controlled by deformational features. The equal area plots of the principal susceptibility axes and representation of maximum susceptibility axes in the rose diagram revealed parity between the field and magnetic fabrics thus pointing to a tectonic control of fabrics. Moreover, the pegmatitic bodies based on AMS parameters are found to have emplace syn-tectonic to basement deformation which impinged a linear feature (both in mesoscopic fabric and magnetic fabric) to the otherwise undeformed intrusive bodies.Keywords
Atomic Absorption Spectrophotometry, Anisotropy of Magnetic Susceptibility, Fe–Ti-Oxide, Gneiss, Pegmatites.References
- Watson, J. V., Vertical movements in Proterozoic structural provinces. Philos. Trans. R. Soc. London A, 1976, 280.
- Baidya, T. K., Archean metallogeny and crustal evolution in the East Indian shield. Earth Sci. (Special Issue: Archean Metallogeny and Crustal Evolution), 2015, 4/4-1, 1–14.
- Ghose, N. C., Geology, tectonics and evolution of the Chhotanagpur granite-gneiss complex, Eastern India. In Recent Researches in Geology, Hindustan Pub. (Delhi), 1983, vol. 10, pp. 211–247.
- Mandal, A., Ray, A., Debnath, M. and Paul, S. P., Petrology, geo-chemistry of hornblende gabbro and associated dolerite dyke of Paharpur, Puruliya, West Bengal: Implication for petrogenetic process and tectonic setting. J. Earth Syst. Sci., 2012, 121(3), 793–812.
- Baidya, T. K., Chakravarty, P. S., Drubetskoy, E. and Khiltova, V. J., New geochronological data on some granitic phases of the Chhotanagpur granite gneiss complex in the northwestern Purulia district, West Bengal. Indian J. Earth Sci., 1987, 14(2), 136–141.
- Baidya, T. K., Maity, N. and Biswas, P., Tectonic phases and crustal evolution in a part of the Eastern Chhotanagpur Gneissic Complex. J. Geol. Soc. India, 1987, 34(3), 318–324.
- Sengupta, D. K. and Sarkar, S. N., Structure of the granitic rock and associated metamorphites of the area around Muri-Silli-Jhalida, Ranchi and Purulia Districts, India. In 22nd International Geological Congress, 1964, vol. 4, pp. 374–389.
- Ghosh, N. C., Geology, tectonic evolution of the Chhotanagpur granite gneiss complex, eastern India. Recent Res. Geol., 1983, 10, 211–247.
- Mazumder, S. K., Crustal evolution of Chhotanagpur gneissic complex and the Mica Belt of Bihar. In Precambrian of the Eastern Indian Shield. Geological Society of India Memoir, 1988, vol. 8, pp. 49–83.
- Sarkar, A. N., Tectonic evolution of the Chhotanagpur plateau and Gondwana basins in eastern India: An interpretation based on supra-subduction geological processes. In Precambrian of the Eastern Indian Shield. Geological Society of India Memoir, 1988, vol. 8, pp. 127–146.
- Tarling, D. and Hrouda, F., Magnetic Anisotropy of Rocks, Springer, 1993, pp. 14–27.
- Sen, K., Sharma, R. and Arora, B. R., Influence of magnetic fabric anisotropy on seismic wave velocity in paramagnetic granites from NW Himalaya: Results from preliminary investigations. J. Geol. Soc. India, 2010, 76/4, 322–330.
- Jayangondaperuma, R., Dubey, A. K. and Sen, K., Structural and magnetic fabric studies of recess structures in the western Himalaya: Implications for 1905 Kangra earthquake. J. Geol. Soc. India, 2010, 75/1, 225–238.
- Nagata, T., Rock magnetism. In Maruzen, 1961, 2nd edn, p. 350.
- Blasley, J. R. and Buddington, A. F., Magnetic susceptibility anisotropy and fabric of some Adirondack granites and orthogenesis. Am. J. Sci., 1960, 258/A, 6–20.
- Stacey, F. D., Joplin, G. and Lindsay, J., Magnetic anisotropy and fabric of some foliated rocks from S.E. Australia. Geophys. Pura Appl., 1960, 47, 30–40.
- Hrouda, F., Chlupacova, M. and Relj, L., The mimetic fabric of magnetite in some foliated granitoids, as indicated by magnetic anisotropy. Earth Planet. Sci. Lett., 1971, 11, 4–38.
- Hrouda, F., Janak, F., Rejl, L. and Weiss, J., The use of magnetic susceptibility anisotropy for estimating the ferromagnetic mineral fabrics of metamorphic rocks. Geol. Rundsh., 1971, 60, 42–1124.
- Jelenik, V., Characterization of the magnetic fabric of rocks. Tectonophysics, 1973, 79, 7–63.
- Hrouda, F., Magnetic anisotropy of rocks and its application in Geology and Geophysics. Geophys. Surveys, 1982, 5, 37–82.
- Flinn, D., On folding during three-dimensional progressive deformation. Q. J. Geol. Soc. London, 1962, 118, 385–433.
- Haggerty, S. E., Opaque mineral oxides in terrestrial igneous rocks. In Oxide Minerals (ed. Rumble, D.), Mineral. Soc. Am., Short Course Notes, 3, Hg101–Hg300.
- Chatterjee, S., Gain, D. and Mondal, S., Magneto-mineralogy characterization and analysis of magnetic fabrics of the high-grade rocks from Chilka Lake area, Eastern Ghats belt, India. Earth Sci. India, 2016, 9/1, 29–47.
- Johnson, H. P. and Hall, J. M., A detailed rock magnetic and opaque mineralogy study of the basalts from Nazca Plate. Geo-phys. J. R. Astr. Soc., 1978, 52, 45–64.
- Prevot, M., Remond, G. and Caye, R., Etude de la transformation d’unetitano magnetite-en-titanomaghemite-dansunerochevolcanique. Bull. Soc. Fr. Min. Cristallogr., 1968, 91, 65.
- Akimoto, T., Kinoshita, H. and Furuta, T., Electron probe micro-analysis study on process of Low temperature oxidation of titano-magnetite. Earth Planet. Sci. Lett., 1984, 71, 263–278.
- Ferre, E. C., Martin-Hernandez, F., Teyssier, C. and Jackson, M., Paramagnetic and ferromagnetic anisotropy of magnetic susceptibility in migmatites: measurements in high and low fields and kinematic implications. Geophys. J. Int., 2004, 157, 1119–1129.
- Rathore, J. S., Magnetic susceptibility anisotropy in the Cambrian slate belt of North Wales and correlation with strain. Tectonophysics, 1979, 53, 83–97.
- Goldstein, A. G., Magnetic susceptibility anisotropy of mylonites from the Lake Char Mylonite Zone, SE New England. Tectono-physics, 1980, 66, 197–211.
- Mondal, S., Piper, J. D. A., Hunt, L., Bandopadhyay, G. and BasuMallick, S., Palaeomagnetic and rock magnetic study of charnockites from Tamil Nadu, India, and the ‘Ur’protocontinent in Early Palaeoproterozoic times. J. Asian Earth Sci., 2009, 34, 493–506.
- Hrouda, F. and Janak, F., The changes in shape of the magnetic susceptibility ellipsoid during progressive metamorphism and deformation. Tectonophysics, 1976, 4, 135–148.
- Zhang, J. and Piper, J. D. A., Magnetic fabric and post-orogenic uplift and cooling magentisations in a Precambrian granulite terrain: The Datong-Huai’an region of the North China Shield. Tectonophysics, 1994, 234, 227–246.
- Imprints of vehicular pollution in roadside dust from Kolkata, India: insights from magnetic susceptibility, geo-statistical and SEM studies
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Authors
Affiliations
1 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India, IN
2 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India; Department of Geology, Rajiv Gandhi University, Rono Hills, Papum Pare 791 112, India, IN
3 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India, IN
4 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India; Geology Department, Asutosh College, S.P. Mukherjee Road, Kolkata 700 026, India, IN
1 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India, IN
2 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India; Department of Geology, Rajiv Gandhi University, Rono Hills, Papum Pare 791 112, India, IN
3 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India, IN
4 Department of Geological Sciences, Jadavpur University, 188 Raja S.C. Mullick Road, Kolkata 700 032, India; Geology Department, Asutosh College, S.P. Mukherjee Road, Kolkata 700 026, India, IN
Source
Current Science, Vol 124, No 1 (2023), Pagination: 56-62Abstract
The present study aimed to determine the magnetic susceptibility of roadside dust collected from different parts of Kolkata city, West Bengal, India. The average value of susceptibility was 4.96 ´ 10–6 m3/kg, the highest being 19.6 ´ 10–6 m3/kg and the lowest being 1.2 ´ 10–6 m3/kg. The frequency-dependent susceptibility value (average = 2.19) indicated the dominance of stable-single domain grains with a low concentration of superparamagnetic grains at a few locations. SEM analysis showed morphological diversity of road dust – irregular, aggregate, angular and cloudy. Energy dispersive X-ray spectroscopy analysis of the dust particles revealed that Ca-rich, Na-rich and Fe-rich particles were abundant. Compositions were variable with the morphology. The mapping of magnetic susceptibility indicated that the susceptibility values were higher in areas with heavy vehicular traffic and other polluting sources. However, some areas with high pollution had open spaces, indicating the dispersion of magnetic pollutants. The study indicated the degradation of the environment due to anthropogenic activitiesReferences
- Goddu, S. R., Appel, E., Jordanova, D. and Wehland, R., Magnetic properties of road dust from Visakhapatnam (India) – relationship to industrial pollution and road traffic. Phys. Chem. Earth, 2004, 29(13,14), 985–995.
- Hoffmann, V., Knab, M. and Appel, E., Magnetic susceptibility mapping of roadside pollution. J. Geochem. Explor., 1999, 66, 313– 326.
- Gautam, P., Blaha, U. and Appel, E., Magnetic susceptibility of dust-loaded leaves as a proxy of traffic-related heavy metal pollution in Kathmandu city, Nepal. Atmos. Environ., 2005, 39, 2201–2211.
- Petrovsky, E. and Ellwood, B. B., Magnetic monitoring of pollution of air, land and waters. In Quaternary Climates, Environments and Magnetism (eds Maher, B. A. and Thompson, R.), Cambridge Uni-versity Press, Cambridge, UK, 1999, pp. 279–322.
- Gautam, P., Blaha, U. and Appel, E., Integration of magnetic properties and heavy metal chemistry to quantify environmental pollution in urban soils, Kathmandu, Nepal. Himalayan J. Sci., 2004, 2(4), 140– 141.
- Petrovsky, E., Kapicka, A., Jordanova, N., Knab, M. and Hoff-mann, V., Low-field magnetic susceptibility: a proxy method of esti-mating increased pollution of different environmental systems. Environ. Geol., 2000, 39(3–4), 312–318.
- Boyko, T., Scholger, R. and Stanjek, H., Topsoil magnetic suscep-tibility mapping as a tool for pollution monitoring: repeatability of in situ measurements. J. Appl. Geophys., 2004, 55, 249–259.
- Kapicka, A., Petrovsky, E., Ustjak, S. and Machackova, K., Proxy mapping of fly-ash pollution of soils around a coal-burning power plant: a case study in the Czech Republic. J. Geochem. Explor., 1999, 66, 291–297.
- Hunt, A., The application of mineral magnetic methods to atmospheric aerosol discrimination. Phys. Earth Planet. Inter., 1986, 42, 10–21.
- Evans, M. E. and Heller, F., Environmental Magnetism: Principles and Applications of Enviromagnetics. 86, International Geophysics Series, Academic Press, Florida, 2003.
- Brilhante, O., Daly, L. and Trabuc, P., Application of magnetism to detect pollution caused by heavy metals in the environment. CR Acad. Sci. Paris, 1989, 309(II), 2005–2012.
- Foster, D. L., Charlesworth, S. M., Dearing, J. A., Keen, D. H. and Dalgleish, H. Y., Lake sediment: a surrogate measure of sediment associated heavy metal transport in fluvial systems? In Sediment and Stream Water Quality in a Changing Environment: Trends and Explanation, edn 203, IAHS Press, Wallingford, 1991, pp. 321–328.
- Charlesworth, S. M. and Lees, J. A., The application of some min-eral magnetic measurements and heavy metal analysis for characteris-ing fine sediments in an urban catchment, Coventry, UK. J. Appl. Geophys., 2001, 48, 113–125.
- Dunlop, D. and Özdemir, Ö., Rock Magnetism – Fundamentals and Frontiers, Cambridge University Press, Cambridge, UK, 1997.
- Georgeaud, V. M., Rochette, P., Ambrosi, J. P., Vandamme, D. and Williamson, D., Relationship between heavy metals and magnetic properties in a large polluted catchment: the etangdeBerre (south of France). Phys. Chem. Earth, 1997, 22, 211–214.
- Thompson, R. and Oldfield, F., Environmental Magnetism, Allen and Unwin, London, UK, 1986.
- Fassdinder, J. W. E., Stanjeck, H. and Vali, H., Occurrence of magnetic bacteria in soil. Nature, 1990, 343, 161–163.
- Morris, W. A., Versteeg, J. K., Bryant, D. W., Legzdins, A. E., McCarry, B. E. and Marvin, C. H., Preliminary comparisons bet-ween mutageneity and magnetic susceptibility of respirable air-borne particulate. Atmos. Environ., 1995, 29, 3441–3450.
- Versteeg, J. K., Morris, W. A. and Rukavina, N. A., Distribution of contaminated sediment in Hamilton harbour as mapped by magnetic susceptibility. Geosci. Can., 1995, 22(4), 68–100.
- Mondal, S., Chatterjee, S., Maity, R., Gain, D., Das, A. and Sinha, S., Magnetic susceptibility as a proxy for pollution in Triveni– Bandel area, Hooghly district, West Bengal, India. Curr. Sci., 2016, 112(11), 2306–2311.
- Dhar, S. B., Influence of the River Ganga on the urban process in Kolkata Metropolitan Area. IOSR-JHSS, 2014, 19(9), 60–67.
- Das, D. and Chattopadhyay, B. C., Characterization of soil over Kolkata municipal area. In Indian Geotechnical Conference, Guntur, 2009.
- Lal, D. S., Climatology, Sharda Pustak Bhawan, Allahabad, 2003.
- KMDA, Annual Report, Kolkata Metropolitan Development Authority, 2011.
- CPCB, Central Pollution Control Board, Ministry of Environment and Forests, Government of India, 2008–2009, p. 40.
- Bhaumik, S., Oxygen supplies for Indian Police, BBC, 2007.
- Utsunomiya, S. and Ewing, R. C., Application of high-angle annular dark field scanning transmission electron microscopy, scanning trans-mission electron microscopy energy dispersive X-ray spectrometry, and energy-filtered transmission electron microscopy to the charac-terization of nanoparticles in the environment. Environ. Sci. Tech-nol., 2003, 37, 786–791.
- Maity, R., Venkateshwarlu, M., Mondal, S., Kapawar, M. R., Gain, D. and Paul, P., Magnetic and microscopic characterization of an-thropogenically produced magnetic particles: a proxy for environ-mental pollution. Int. J. Environ. Sci. Technol., 2020; https:// doi.org/10.1007/s13762-020-02902-x.
- Muxworthy, A. R., Effect of grain interactions on the frequency dependency of magnetic susceptibility. Geophys. J. Int., 2001, 144, 441–447.
- Kim, W., Dosh, S. J. and Yui, Y., Anthropogenic contribution of magnetic particulates in urban roadside dust. Atmos. Environ., 2009, 43, 3137–3144.
- Bucko, M. S., Magiera, T., Johanson, B., Petrovsky, E. and Pesonen, L. J., Identification of magnetic particulates in road dust accumulated on roadside snow using magnetic, geochemical and micro-morpho-logical analyses. Environ. Pollut., 2011, 159, 1266–1276.
- Zhang, C. X., Qiao, Q. Q., Piper, J. D. A. and Huang, B. C., Assess-ment 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.
- Zhu, Z., Li, Z., Bi, X., Han, Z. and Yu, G., Response of magnetic properties to heavy metal pollution in dust from three industrial cities in China. J. Hazard. Mater., 2013, 246–247, 189–198.
- Shenggao, L., Xi, Y. and Chen, Y., Magnetic properties, micro-structure and mineralogical phases of technogenic magnetic particles (TMPs) in urban soils: their source identification and environmen-tal implications. Sci. Total Environ., 2016, 543, 239–247.