Abstract
Thirty-six sediment samples from twelve soil profiles have been collected from Karewa deposits of south Kashmir with an objective for evaluating weathering of the source area, palaeoclimate and environmental contamination. Chemical Index of Alteration (CIA), Plagioclase Index of Alteration (PIA) and Chemical Index of Weathering (CIW) values of the sediments averaged at 53.99, 68.6 and 72.53 indicating low to moderate degree of weathering. Higher values are observed in the samples collected at top surface. The samples taken at 15 cm depth and 60 cm depth showed almost similar but lesser values than top soil samples. A–CN–K and A–CNK–FM diagrams showed an almost similar contents for Al2O3, CaO, Na2O, K2O and MgO as those of upper crust, reflecting very poor to moderate weathering history. The ratio plots of SiO2 vs Al2O3 + K2O + Na2O and CIA (molar) vs Al2O3 indicate semi-arid climatic conditions with a mean annual precipitation of 846 mm per year and mean annual paleo-temperature of 10.91 °C. Metal concentration in sediment samples ranged from 331.1 to 571 ppm (Ba), 146 to 292 ppm (Zr), 82 to 587 ppm (Sr), 70 to 130 ppm (Cr), 58.9 to 120 ppm (Rb), 37.6 to 112 ppm (V) and 43 to 112 ppm (Zn). The enrichment ratio of 6 for As, 3 for Cr and 2 for Ni, Sb and Tb indicate the enrichment of these metals in the sediment samples. The QoC plot of As, Ni, Co and Cr illustrated an anthropogenic source and Ba, Rb, Sr, Nb, and Ta were mainly derived from geogenic sources with no evidence of anthropogenic contamination.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adriano DC (2001) Trace elements in terrestrial environments: biogeochemistry, bioavailability, and risks of metals. Springer Verlag, New York
Ahmad I, Chandra R (2013) Geochemistry of loess-paleosol sediments of Kashmir Valley, India: provenance and weathering. J Asian Earth Sci 66:73–89
Ahmad AHM, Noufal KN, Masroor AH, Khan T (2014) Petrography and geochemistry of jumara dome sediments, Kachchh Basin: implications for provenance, tectonic setting and weathering intensity. Chi J Geochem 33(1):9–23
Asaah VA, Abimboal AF, Suh CE (2006) Heavy metal concentration and distribution in surface soils of the bassa industrial zone 1, Douala, Cameroon. Arab Jour Sci Eng 31(2):147
Benhaddya ML, Hadjel M (2013) Spatial distribution and contamination assessment of heavy metals in surface soils of hassiMessaoud. Algeria Environ Ear Sci 71(3):1473–1486
Bhat NA (2017) Geochemistry of surface water and stream sediments in Karewa basin of South Kashmir, India: implications on human health, agriculture and environmental studies. PhD Thesis; Banarus Hindu University
Bhat AA, Bhat NA (2014) Geochemical mapping of Kashmir Nappe and Karewa group of rocks covering parts of Anantnag, Baramulla and Srinagar districts, J&K in toposheet nos. 43K/13 and 43K/14. Geological Survey of India, Unpublished report FS 2013-14
Bhat NA, Nath S, Guha DB, Singh BP, Bhat AA (2018) Geochemistry of stream sediments of Karewa Basin of South Kashmir, India: their environmental and agricultural implications. Ind J Geosci (Under review)
Bhat NA, Singh BP, Bhat AA, Nath S, Guha DB (2019) Application of geochemical mapping in unraveling paleoweathering and provenance of Karewa sediments of South Kashmir, NW Himalayas, India. J Geol Soc Ind 93(1):68–74. https://doi.org/10.1007/s12594-019-1124-x
Bhatt DK (1975) On the Quaternary geology of the Kashmir Valley with special reference to stratigraphy and sedimentation. Geol Sur Ind Misc Pub 24:188–204
Bhatt DK (1976) Straigraphical status of Karewa Group of Kashmir, India. Him Geol 6:197–208
Bhatt DK (1989) Lithostratigraphy of Karewa group, Kashmir Valley, India and a critical review of its fossil record. In: Memoir of the Geological Survey of India, vol 122. Geological Survey of India, Calcutta
Bickle MJ, Chapman HJ, Bunbury J, Harris NBW, Fairchild IJ, Ahmad T, Pomiès C (2005) Relative contributions of silicate and carbonate rocks to riverine Sr fluxes in the headwaters of the Ganges. Geochim Cosmochim Acta 69:2221–2240
Blum JD, Gazis CA, Jacobson AD, Chamberlain CP (1998) Carbonate versus silicate weathering in the Raikhot catchment within the high Himalayan crystalline series. Geol 26:411–414
Boyle RW, Jonasson IR (1973) The geochemistry of As and its use as an indicator element in geochemical prospecting. J Geochem Explor 2:251–296
Chandra R, Ahmad I, Quarshi A (2016) Pedological and geochemical characterization of loess-paleosol sediments of Karewa basin: implications for paleoclimatic reconstruction of Kashmir valley. J Geol Soc India 4:38–54
Fedo CM, Nesbitt HW, Young GM (1995) Unravelling the effects of potassium metasomatism in sedimentary rocks and paleosols, with implications for paleoweathering conditions and provenance. Geology 23(10):921–924
Fedo CM, Young GM, Nesbitt HW, Hanchar JM (1997) Potassic and sodic metasomatism in the Southern province of the Canadian shield: evidence from the paleoproterozoic serpent formation, huroniansupergroup. Canad Precam Res 84:17–36
Feng R, Kerrich R (1990) Geochemistry of fine grained clastic sediments in the Archean Abitibi greenstones belt, Canada: implications for provenance and tectonic setting. Geochim Cosmochim Acta 54:1061–1081
Garrels RM, Mackenzie FT (1971) Evolution of sedimentary rocks. Norton, New York
Gas’kova OL, Strakhovenko VD, Ovdina EA (2017) Composition of brines and mineral zoning of the bottom sediments of soda lakes in the Kulunda steppe (West Siberia). Russ Geo Geophy 58(10):1199–1210
George RM, Martin. GD, Nair. SM, Thomas SP Jacob S (2016) Geochemical assessment of trace metal pollution in sediments of the Cochin backwaters, Envir Foren, 17:2, 156–171, https://doi.org/10.1080/15275922.2016.1163623
Goldberg K, Humayun M (2010) The applicability of the chemical index of alteration as a paleoclimatic indicator: an example from the Permian of the Paraná Basin, Brazil. Palaeo Palaeo Palaeo 293:175–183
Gromet LP, Dymek RF, Haskin LA, Korotev RL (1984) The ‘North American shale composite’: its compilation, major and trace element characteristics. Geochim Cosmochim Acta 48:2469–2482
Grunsky EC, Drew LJ, Sutphin DM (2009) Process recognition in multi-element soil and stream-sediment geochemical data. Appl Geochem 24:1602–1616
Harnois L (1988) The C.I.W. index: a new chemical index of weathering. Sed Geol 55:319–322
Jeelani G, Shah AQ (2006) Geochemical characteristics of water and sediment from the Dal Lake, Kashmir Himalaya: constraints on weathering and anthropogenic activity. Environ Geol 50(1):12–23
Jin ZD, Li FC, Cao JJ, Wang SM, Yu JM (2006) Geochemistry of Daihai Lake sediments, inner Mongolia, North China: implications for provenance, sedimentary sorting, and catchment weathering. Geomor 80:147–163
Marbut CF (1935) Atlas of American agriculture. III. Soils of the United States. Government Printing Office, Washington
Maynard JB (1992) Chemistry of modern soils as a guide to interpreting Precambrian paleosols. J Geol 100:279–289
Maynard JB, Valloni R, Yu HS (1982) Composition of modern deep-sea sands from arc-related basin. In: Leggett JK (ed) Trench forearc geology: sedimentation and tectonics on modern and ancient active plate margins, vol 10. Geological Society, London, Special Publications, pp 551–561
McLennan SM (1989) Rare earth elements in sedimentary rocks: influence of provenance and sedimentary processes. Rev Miner 21:170–199
McLennan SM, Hemming S, McDaniel DK, Hanson GN (1993) Geochemical approaches to sedimentation, provenance and tectonics. Geol Soc Amer Spec Pap 284:21–40
Mir RA, Jeelani G (2015) Textural characteristics of sediments and weathering in the Jhelum River basin located in Kashmir Valley, western Himalaya. J Geol Soc India 86:445–458
Mir IA, Mir RA, 2015, Interim report on geochemical mapping of Srinagar, Pampur and Ganderbal areas of Srinagar and Ganderbal districts, Jammu and Kashmir in toposheet no. 43 J/11 and part of 43 J/12. Geological Survey of India, Unpublished report FS 2014-15
Mukherjee PK, Pal T, Chattopadhyay S (2010) Role of geomorphic elements on distribution of arsenic in groundwater—a case study in parts of Murshidabad and Nadia districts, West Bengal. Ind Jour Geosci 64(1–4):77–86
Nath BN, Bau M, Ramalingeswara RB, Rao CM (1997) Trace and rare earth elemental variation in Arabian Sea sediments through a transect across the oxygen minimum zone. Geochim Cosmochim Act 61(12):2375–2388
Nesbitt HW, Young GM (1982) Early Proterozoic climates and plate motions inferred from major element chemistry of lutites. Nat 299:715–717
Nesbitt HW, Markovics G, Price RC (1980) Chemical processes affecting alkalis and alkali earths during continental weathering. Geochim Cosmochim Acta 44:1659–1666
Nesbitt HW, Young GM, McLennan SM, Keays RR (1996) Effect of chemical weathering and sorting on the petrogenesis of siliciclastic sediments, with implications for provenance studies. J Geol 104:525–542
Niskavaara H, Reimann C, Chekushin V, Kashulina G (1997) Seasonal variability of total and easily leachable element contents in top soils (0–5 cm) from eight catchments in the European Arctic (Finland, Norway and Russia). Environ Poll 96:261–274
Nordstrom DK (2002) Worldwide occurrences of arsenic in groundwater. Science 296:2143–2145
Prasad V, Farooqui A, Sharma A, Phartiyal B, Chakraborty S, Bhandari S, Singh A (2014) Mid–late Holocene monsoonal variations from mainland Gujarat, India: a multi-proxy study for evaluating climate culture relationship. Palaeo Palaeo Palaeo 397:38–51
Puchelt H (1972) Barium. Handbook of geochemistry (Wedepohl KH et al (eds)), 56B1–56O2, Springer, Berlin
Raj R, Chamyal LS, Prasad V, Sharma A, Tripathi JK, Verma P (2015) Holocene climatic fluctuations in the Gujarat Alluvial plains based on a multiproxy study of the Pariyaj Lake archive, western India. Palaeo Palaeo Palaeo 421:60–74
Ranasinghe PN, Fernando GWAR, Dissanayake CB, Rupasinghe MS (2008) Stream sediment geochemistry of the Upper Mahaweli River Basin of Sri Lanka—geological and environmental significance. J Geochem Explor 99:1–28
Rashid SA, Ganai JA, Masoodi A, Khan FA (2015) Major and trace element geochemistry of lake sediments, India: implications for weathering and climate control Arab. J Geosci 8:5677–5684
Salminen R, Gregorauskiene V, Tarvainen T (2008) The normative mineralogy of 10 soil profiles in Fennoscandia and north-western Russia. App Geochem 23:3651–3665
Saxena A, Trivedi A, Chauhan MS, Sharma A (2015) Holocene vegetation and climate change in central Ganga plain: a study based on multiproxy records from Chaudhary-KaTal, Raebareli District, Uttar Pradesh, India. Quat Inter 371:164–174
Selinus O, Frank A (2000) Medical geology. In: Moller L (ed) Environmental medicine. Joint Industrial Safety Council, Stockholm, pp 64–82
Sheikh JA, Jeelani G, Gavali RS, Shah RA (2014) Weathering and anthropogenic influences on the water and sediment chemistry of Wular Lake, Kashmir Himalaya. Environ Ear Sci 71:2837–2846
Sheldon ND, Retallack GJ, Tanaka S (2002) Geochemical climofunctions from North American soils and application to Paleosols across the eocene-oligocene boundary in oregon. Jour Geol 110:687–696
Simex SA, Helz GR (1981) Regional geochemistry of trace elements in Checapeake Bay. Environ Geol 3(6):315–323
Singh IB (1982) Sedimentation pattern in the Karewa Basin, Kashmir Valley, India, and its geological significance. J Palaeon Soc Ind 27:71–110
Suttner LJ, Dutta PK (1986) Alluvial sandstones composition and paleoclimate, I, framework mineralogy. J Sed Pet 56:329–345
Tan J, Zhu W, Wang W, Li R, Hou S, Wang D, Yang L (2002) Selenium in soil and endemic diseases in China. Sci Tot Environ 284:227–235
Taylor SR, Mclennan SM (1985) The continental crust: its composition and evolution. Blackwell, Oxford
Verma M, Singh BP, Srivastava A, Mishra M (2012) Chemical behavior of suspended sediments in a small river draining out of the Himalaya, Tawi River, northern India: implications on provenance and weathering. Him Geol 33(1):1–14
Viers J, Dupré B, Braun JJ, Deberdt S, Angeletti B, Ngoupayou JN, Michard A (2000) Major and trace element abundances, and strontium isotopes in the Nyong basin rivers (Cameroon): constraints on chemical weathering processes and elements transport mechanisms in humid tropical environments. Chem Geol 169:211–241
Wedepohl HK (1995) The composition of the continental crust. Geochim Cosmochim Acta 59:1217–1232
Xuan PT, Pho NV, Gas’kova OL, Bortnikova SB (2013) Geochemistry of surface waters in the vicinity of open pit mines at the cay cham deposit, Thai Nguyen Province, Northern Vietnam. Geochem Inter 51(11):931–938
Acknowledgements
The work has been carried out under Geological Survey of India, Field Season Programme 2013–14. The authors gratefully acknowledge Director General, Geological Survey of India, Dy. Director General and HOD, Geological Survey of India, Northern Region and Dy. Director General, State Unit Jammu and Kashmir for providing necessary facilities for completion of the work. The authors are also thankful to the officers of Geochemical Lab. GSI, Lucknow for analysis of the samples. The authors are highly indebted to Miss Samreen Shaikh, Geologist, GSI for improving the language of the manuscript and also to the anonymous reviewers for their valuable scientific comments and suggestions.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Bhat, N.A., Singh, B.P., Nath, S. et al. Geochemical characterisation of stream sediments and soil samples from Karewa deposits of south Kashmir, NW Himalaya, India. Environ Earth Sci 78, 278 (2019). https://doi.org/10.1007/s12665-019-8212-5
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12665-019-8212-5