Abstract
Haryana plain is the drainage divide between the Ganga plain in the east and the Indus plain in the west. Being a part of the Himalayan foreland, its geomorphology, sedimentation processes, and tectonism are broadly controlled by the Himalayan tectonics. Soil and geomorphological mapping in Haryana plain bring out geomorphic features such as paleochannels, various active drainage patterns, and landforms such as old fluvial plains, floodplains, piedmonts, pediments, terminal fans, and eolian plains. Based on the degree of soil development, and Optical stimulated luminescence (OSL) ages, the soil-geomorphic units were grouped into six members (QIMS-I to VI) (Quaternary Indus Morphostratigraphic Sequence) of a morphostratigraphic sequence: QIMS-VI 9.86–5.38 Ka, QIMS-V 5.38–4.45 Ka, QIMS-IV 4.45–3.60 Ka, QIMS-III 3.60–2.91 Ka, QIMS-II < 2.91–1.52 Ka, and QIMS-I < 1.52 Ka. OSL chronology of different geomorphic features suggests six episodes of tectono-geomorphic evolution in the region since 10 Ka. Neotectonic features such as nine faults, two lineaments, and five fault-bounded tectonic blocks have been identified. Independent tilting and sagging of the blocks in response to neotectonics have resulted in modification of landforms, depositional processes, and hydro-geomorphology of the region. Major rivers like the Yamuna, the Ghaggar, and the Sutlej show different episodes of shifting of their courses. Lineament controlled few extinct channels have been recorded between 20 and 25 m depth below the surface in the ground-penetrating radar (GPR) profiles. These buried channels are aligned along the paleo-course of the Lost Saraswati River interpreted from the existing literature and hence are considered as the course of the lost river. Seven terminal fans have been formed on the downthrown blocks of the associated faults. The Markanda Terminal Fan, the first of such features described, is indeed a splay terminal fan and was formed by a splay distributary system of the Markanda River. Association of three terminal fans of different ages with the Karnal fault indicates the segment-wise development of the fault from west to east. Also, comparison with other such studies in the Ganga plain to further east suggests that the terminal fans formed by streams with distributary drainage pattern occur only in semiarid regions as in the present area and thus are indicators of semiarid climate/paleoclimate. Though the whole region is tectonically active, the region between the Rohtak fault and Hisar fault is most active at present signified by the concentration of earthquake epicenters.
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References
Aitken MJ (1985) Thermoluminescence dating. Academic Press, London 359p
Audru J-C, Bano M, Begg J, Berryman S, Niviere HB (2001) GPR investigations on active faults in urban areas: the Georisc-NZ project in Wellington, New Zealand. Earth Planet Sci 333:447–454
Bhadra BK, Gupta AK, Sharma JR (2006) Sub-surface water oozing at Kalayat village, Jind district, Haryana in December, 2005: Possible connection with Saraswati Palaeochannel. J Geol Soc India 68(6), p 946
Bhadra BK, Gupta AK, Sharma JR (2009) Saraswati Nadi in Haryana and its linkage with the Vedic Saraswati River—integrated study based on satellite images and ground based information. J Geol Soc India 73:273–288
Bhosle B, Parkash B, Awasthi AK, Pati P (2009) Use of digital elevation models and drainage patterns for locating active faults in the Upper Ganga Plain, India. Int J Remote Sens 30(3):673–691
Bhosle B, Parkash B, Awasthi AK, Singh S, Khan N, MS (2008) Role of extensional tectonics and climatic changes in geomorphological, pedological and sedimentary evolution of the Western Ganga Plain (Himalayan Foreland Basin), India. Himal Geol 29(1):1–24
Bristow CS, Jol HM (2003) Ground penetrating radar in sediments. Geol. Soc. London spec. Publ., vol. In: 211
C.G.W.B., 2004. Complete study report on perspective land use for Haryana state. Central Ground Water Board S. No. 24, ref 1223
Fisher, C. S., Stewart, R.R. and Jol, H. M., 2000. Processing ground penetrating radar data. Proceedings of eighth international conference on ground penetrating radar. University of Queensland
Frye JC, Willman HB (1962) Note 27; Morpho-stratigraphic units in Pleistocene stratigraphy. Bull Am Assoc Pet Geol 46(1):112–113
Gawthorpe RL, Leeder MR (2000) Tectono-sedimentary evolution of active extensional basins. Basin Res 12:195–218
Ghose B, Kar A, Hussain Z (1979) The lost courses of the Saraswati River in the great Indian Desert—new evidence from Landsat imagery. Geogr J, London 45(3):446–451
Gibling MR, Fielding CR and Sinha R (2011) Alluvial valleys and alluvial sequences: towards a geomorphic assessment. In: Davidson, S. K., Leleu, S. and North, C. P. (eds) From river to rock record: the preservation of fluvial sediments and their subsequent interpretation. SEPM, Special Publication, 97, pp 423–447
Golden Software Inc (2003) Surfer version 8.03—User Guide. Golden Software Inc., Colorado
Goldsworthy M, Jackson J (2000) Active normal fault evolution in Greece revealed by geomorphology and drainage patterns. J Geol Soc Lond 157:967–981
Goodbread SL Jr, Kuehl SA (2000) Enormous Ganges–Brahmaputra sediments discharge during strengthened early Holocene monsoon. Geology 28:1083–1086
Goodbread SL Jr (2003) Response of the Ganges dispersal system to climate change: a source-to-sink view since the last interstade. Sediment Geol 162(62):83–104
Gupta RP (1991) Remote sensing geology. Springer-Verlag, Berlin, Heidelberg, 1991
Gupta AK, Sharma JR, Sreenivasan G, Srivastava KS (2004) New findings on the course of river Saraswati. J Indian Soc Remote 32(1)
Gupta AK, Bhadra BK, Sharma JR (2008) Saraswati drainage system of Haryana–satellite based study. In: Vedic Saraswati and hindu civilization, Srinivasan K. (Ed), Aryan Books International, New Delhi, pp 46–64
Jackson J, Leeder M (1994) Drainage systems and the development of normal faults: an example from Pleasant Valley, Nevada. J Struct Geol 16(8):1041–1059
Jol HM and Bristow CS (2003) GPR in sediments: advice on data collection, basic processing and interpretation, a good practice guide. In: Ground penetrating radar in sediments. CS Bristow and HM Jol, Eds, Geol Soc London Spec Publ 211, 9–27
Joshi JP, Bala M, Raj J (1984) The Indus civilisation: a reconstruction on the basis of distribution maps. In: Lal BB, Gupta SP (eds) Frontiers of the Indus civilisation. Books and Books, New Delhi, pp 511–539
Kalyanraman S (1999) Saraswati River: goddess and civilization. In: Vedic Saraswati. B.P. Radhakrishna and S.S. Merh. Eds., Geol. Soc. India, Mem 42, 25–33
Kar A, Ghose B (1984) The Drishadvati river system of India—an assessment and new findings. Geogr J 15:122–229
Kar A (1995) Geomorphology of arid western India. Memoir Geol Soc India 32:168–190
Khonde N, Singh SK, Maurya DM, Rai VK, Chamyal LS, Giosan L (2017) Tracing the Vedic Saraswati River in the great Rann of Kachchh. Nat Sci Rep 7:5476
Kumar S, Parkash B, Manchanda ML, Singhvi AK (1996) Holocene landform and soil evolution of the western Ganga Plains: implications of neotectonics and climate. Zeit Geomorph NF Suppl-Bd 103:283–312
Levine EL, Ciolkosz EJ (1983) Soil development in till of various ages in northern Pennsylvania. Quat Res 19:85–99
Manchanda ML, Hilwig FW (1981) Visual interpretation of computer transformed Landsat imagery for salt affected areas of part of Haryana. Journal of the Indian Society of Photo-Interpretation and Remote Sensing, 9(2):1–11
Mohindra R, Parkash B, Prasad J (1992) Historical geomorphology and pedology of the Gandak Megafan, middle Gangetic Plains, India. Earth Surf Process Landf 17:643–662
Narula PL, Acharya SK, Benarjee J (2000) Seismotectonic atlas of India and its environs. Geological Survey of India, Kolkata, pp 26–27
Neal A (2004) Ground-penetrating radar and its use in sedimentology: principles, problems and progress. Earth Sci Rev 66:261–330
North CP, Wariswick GL (2007) Fluvial fans: myths, misconceptions, and the end of the terminal-fan model. J Sediment Res 77:693–701
Oldham CF (1893) The Saraswati and the lost river in the Indian desert. J Roy Asiatic Soc 25:49–76
Oldham RD (1886) On probable changes in the geography of the Panjab and its rivers: a historic geographical study. Jour Asiatic Soc Bengal 55:322–343
Parkash B, Kumar S (1991) The Indo-Ganga Basin. In: Tandon SK, Pant CC, Casshyap SM (eds) Sedimentary basins of India—tectonic context. Gyanodaya Prakashan, Nainital India, pp 147–170
Parkash B, Kumar S, Rao SM, Giri SC, Kumar CS, Gupta S, Srivastava P (2000) Holocene tectonic movements and stress field in the Western Ganga Plains. Curr Sci 79:438–449
Pati P, Parkash B, Awasthi AK, Acharya V, Singh S (2011a) Concealed thrusts in the Middle Ganga Plain, India—a ground penetrating radar study proves the truth against the geomorphic features supporting normal faulting. J Asia Earth Sci 40:315–325
Pati, P. Parkash, B., A.K. Awasthi, A.K., and Acharya, V., 2011b. Holocene tectono-geomorphic evolution of parts of the Upper and Middle Ganga Plains, India Geomorphol 128, 48–170
Pati P, Parkash B, Awasthi AK, Jakhmola RP (2012) Spatial and temporal distribution of inland fans/terminal fans between the Ghaghara and Kosi rivers indicate eastward shift of neotectonic activities along the Himalayan front. A study from parts of the Upper and Middle Ganga Plains, India. Earth Sc Rev 15:201–216
Prabhat P, Dinkar GK, Kumar R and Singh V (2014) Quantitative study of drainage basin morphometry of Ghaggar river system in Sirmur district of Himachal Pradesh, India. In: Geology, biodiversity & natural resources of Himalaya and their Intellectual Property Law. R. A. Singh, Ed. Pratyush Publications, Delhi, 219–233
Radhakrishna BP (1999) Holocene chronology and Indian pre-history. In Vedic Saraswati: evolutionary history of a lost river of northwestern India. B.P. Radhakrishna and S. S. Merh, Eds., Geol Soc India Mem 43, 47–51
Raghav KS (1999) Evolution of drainage basins in parts of northern and western Rajasthan that desert India. Memoir Geol Soc India 42:175–185
Raike L (1968) Kalibangan: death from natural causes. Antiquity 42(168):286–291
Ramasamy SM, Bakliwal PC, Verma RP (1991) Remote sensing and river migration in western India. Int J Remote Sens 12:2597–2609
Rao DP (1999) Role of remote sensing in understanding of palaeo drainage evolution. Memoir Geol Soc India 42:237–244
Sahai (1999) Unraveling the 'Lost' Vedic Saraswati. In: B.P. Radhakrishna and S.S. Met (eds) Vedic Saraswati. Memoir Geol Soc lndia, 42: 121–142
Sahoo PK, Kumar S, Singh RP (2000) Neotectonic study of ganga and Yamuna tear faults, NW Himalaya, using remote sensing and GIS. Int J Remote Sens 21(3):499–518
Saini HS, Mujtaba SAI (2010) Luminescence dating of the sediments from a buried channel loop in Fatehabad area, Haryana: insight into Vedic Saraswati River and its environment. Geochronometria 37:29–35
Sharma S, Joachimski M, Sharma M, Tobschall HJ, Singh IB, Sharma C, Chauhan MS, Morgenroth G (2004) Late Glacial and Holocene environmental changes in Ganga Plain, northern India. Quat Sci Rev 23(1–2):145–159
Shukla Z, Thakkar MG (2014) Paleochannel investigations and geo-hydrological significance of Saraswati river of mainland Gujarat, India: using remote sensing and GIS techniques. J Environ Res Develop 9(2):472–479
Singh G (1971) The Indus Valley culture (seen in context of post-glacial climate and ecological studies in north-west India. Archaeol Phys Anthropol Oceania, 6(2), 177–189
Singh G, Joshi RD, Singh AB (1972) Stratigraphic and radiocarbon evidence for the age and development of three salt-lake deposits in Rajasthan, India. Quat Res 2:496–505
Singh G, Joshi RD, Chopra SK, Singh AB (1974) Late Quaternary history of vegetation and climate of the Rajasthan desert, India. Philos Trans R Soc Lond 267(889):467–501
Singh G, Wasson RJ, Agarwal DP (1990) Vegetational and seasonal climatic change since the last full glacial in the Thar Desert, northwestern India. Rev Paleobot Palynol 64:351–358
Singh S, Parkash B, Arora M, Rao MS, Bhosle B (2006) Geomorphology, pedology and sedimentology of the Deoha/Ganga–Ghaghara interfluve, upper Ganga Plains (Himalayan Foreland Basin)—extensional tectonic implications. Catena 67:83–203
Singhai SK, Parkash B, Manchanda ML (1991) Geomorphological and pedological evolution of Haryana state. Bull Oil and Natural Gas Comm 28(2):37–60
Sridevi J (2004) Estimates of plate velocity and crustal deformation in the Indian subcontinent using GPS. Geodesy 86:1143–1448
Srivastava P, Parkash B, Sehgal JL, Kumar S (1994) Role of neotectonics and climate in development of the Holocene geomorphology and soils of the Ganga Plains between the Ramganga and Rapti rivers. Sediment Geol 94:129–151
Valdiya KS (2002) Saraswati, the river that disappeared. University Press, Hyderabad (India)
Valdiya KS (2013) The River Saraswati was a Himalayan-born river. Curr Sci 104(1):42–54
Verma AK, Pati P, Sharma V (2017) Soft sediment deformation associated with the East Patna fault south of the Ganga River, northern India: influence of the Himalayan tectonics on the Southern Ganga Plain. J Asian Earth Sci 143:109–121
Wilhelmy H (1966) Das urstromtai zur ostrand der Indusbene und das Saraswati-problem. Z Geomorph Suppl Bd 8:76–93
Yashpal SB, Sood RK, Agarwal DE (1980) Remote sensing of the “lost” Saraswati River. Proc Ind Nat Sci Acad (Earth and Planetary Sciences) 69:317–331
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Pati, P., Acharya, V., Verma, A.K. et al. Holocene tectono-geomorphic evolution of Haryana plains, Western Ganga plain, India. Arab J Geosci 11, 361 (2018). https://doi.org/10.1007/s12517-018-3714-0
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DOI: https://doi.org/10.1007/s12517-018-3714-0