Abstract
The Suru, Doda and Zanskar river valleys in the semi-arid region of Southern Zanskar Ranges (SZR) preserve a rich repository of the glacial and fluvial landforms, alluvial fans, and lacustrine deposits. Based on detailed field observations, geomorphic mapping and limited optical ages, we suggest four glaciations of decreasing magnitude in the SZR. The oldest Southern Zanskar Glaciation Stage (SZS-4) is inferred from glacially polished bedrock and tillite pinnacles. The SZS-4 is ascribed to the Marine Isotopic Stage (MIS)-4/3. The subsequent SZS-3 is represented by obliterated and dissected moraines, and is assigned to MIS-2/Last Glacial Maximum. The multiple recessional moraines of SZS-2 glaciation are assigned the early to mid Holocene age whereas, the youngest SZS-1 moraines were deposited during the Little Ice Age. We suggest that during the SZS-2 glaciation, the Drang-Drung glacier shifted its course from Suru Valley (west) to the Doda Valley (east). The study area has preserved three generations of outwash gravel terraces, which broadly correlate with the phases of deglaciation associated with SZS-3, 2, and 1. The alluvial fan aggradation, lacustrine sedimentation, and loess deposition occurred during the mid-to-late Holocene. We suggest that glaciation was driven by a combination of the mid-latitude westerlies and the Indian Summer Monsoon during periods of cooler temperature, while phases of deglaciation occurred during enhanced temperature.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
One of the major geomorphic expressions of the Quaternary climate variability in the northern latitude is the expansion and contraction of valley glaciers and the ice sheets (Lowe and Walker 2014). The multi-millennial scale climatic fluctuations are attributed to orbital forcings, which followed a distinct pattern with changes occurring at regular frequency. Superimposed on these were the abrupt short-term (centennial–millennial scale) climatic events that are well represented in the ice-core (Johnsen et al. 1992), marine (Bond et al. 2001; Schulz et al. 1998), continental records (Street-Perrott and Roberts 1983; Gasse et al. 1990), and the mid-latitude glaciers (Owen and Dortch 2014; Sati et al. 2014; Bisht et al. 2015; Sharma et al. 2016). In the last century, anthropogenically-induced rise in global temperature (Hughton et al. 2001) led to \(\sim \)100 m increase in equilibrium line altitude of the mountain glaciers (Grove 2008). The Himalayan glaciers also suffered from both length and ice volume reduction since the 19th century (Bolch et al. 2012). The rate of retreat, however, varies and is also modulated by factors like morphology, elevation, percentage of debris cover, etc. (Brahmbhatt et al. 2017; Singh et al. 2016). Consequently, shrinking glaciers during the last century became iconic image of global climate change and present a stunning evidence of how climate shapes the face of the planet Earth (Mote and Kaser 2007).
One of the important pre-requisites in paleo-glaciation studies is the identification of glacial–deglacial landforms, and their detailed geomorphic mapping. However, identification of moraines is not always easy because besides, the difficulty in differentiating the moraines from the mass-wasted deposits (Hewitt 1999; Benn et al. 2005), challenge is posed by the discontinuous nature of moraines, obliteration by younger and larger glacial advances, and modification of landforms by flash floods (Singh and Mishra 2002; Benn et al. 2005; Singh 2014). However, in the semi-arid and arid Trans-Himalaya (Ladakh and Zanskar), the earth surface processes are relatively subdued; as a result, the terrain has relatively high preservation potential of sedimentary records of the past glaciations (moraines) and deglaciations (outwash terraces) (Owen et al. 2006; Dortch et al. 2013; Sharma et al. 2016).
Climatically, the SZR is influenced both by the ISM and mid-latitude westerlies (Owen and Benn 2005; Leipe et al. 2014). However, studies pertaining to paleo-glaciation suggested that in the western part of the SZR, glaciers were driven by the mid-latitude westerlies (Taylor and Mitchell 2000; Lee et al. 2014). Compared to this, recent studies from the eastern part of the SZR have suggested that the late Quaternary glaciation was driven by a combination of the ISM and mid-latitude westerlies (Saha et al. 2015; Sharma et al. 2016).
The present study investigates the central segment of the SZR, which is located between the Nun-Kun massif in the west and the Sarchu plain in the east. Since the terrain lies in the central segment, it is likely that the influence of the ISM and mid-latitude westerlies would have a cumulative influence in the evolution of the glacial and paraglacial landforms. Although the study is preliminary in nature, it would help in building the skeletal framework of the late Quaternary glaciation and landform evolution in the SZR. Hence the objectives are to document (i) the nature and distribution of glacial and paraglacial landforms, (ii) reconstruct the event stratigraphy, and (iii) suggest factors responsible for the late Quaternary landform evolution.
2 The study area
The study was carried out in the east–west trending Suru, Doda (Stod) and the upper Zanskar river valleys (elevation 3500–7000 m) covering an area of \({\sim }7000\hbox { km}^{2}\) (Dèzes 1999). The Suru and Doda rivers originate from the Pensi-La (La=pass; 4400 m). The westward flowing Suru River meets the Dras River (at Kargil) before it joins the Indus River. The eastward flowing Doda River meets the Lingti or Tsarap Chu River at Padam (figure 1), and flows as the Zanskar River, which eventually meets the Indus river in Ladakh (near Nimu; Dèzes 1999). In the Suru river valley, we investigated the transverse Tangol, Shafat and Ringdom valleys (figure 1), and in the Doda and Zanskar river valleys, the study was carried out in Drang-Drung and the Seni glacier valleys.
2.1 Climate
In the complex mountain topography, there is a significant variation in precipitation and temperature over short distances (Beniston 2006). For example, at Leh, 30-yr climate record suggests \(\sim \)41% precipitation from the ISM (Benn and Owen 1998), while Dras and Kargil receive five times more winter precipitation than Leh (Lee et al. 2014). Similarly, the Zanskar Valley receives variable contribution of the ISM and mid-latitude Westerlies (Mayewski et al. 1984; Lee et al. 2014). The last 200-yr meteorological data from the NW Himalaya suggest a tele-connection between the North Atlantic Oscillations and winter precipitation (Bhutiyani et al. 2010). However, at local scale, 17-yr ice-core data from the Sentik glacier (Nun-Kun), located proximal to the northern fringe of the Higher Himalaya in the Suru River indicates dominance of the ISM (Mayewski et al. 1984). The topographic controlled rainfall gradient is manifested by relatively high precipitation (400–600 mm) in the SZR as compared to the northern Indus valley and Ladakh ranges (Lee et al. 2014) (figure 1b).
2.2 Geology
The lithology of Zanskar Valley is represented by the rocks belonging to pre- and post-collision history. The sedimentary sequences span from Proterozoic to Eocene, while the Higher Himalayan Crystallines (HHC) dominated by migmatitic ortho/para-gneisses is extensively intruded by the leucogranitic dikes (Searle 1986). The sedimentary formations belonging to the Tethyan Sedimentary Sequence (TSS) contain rocks ranging from Late Carboniferous till the India–Asia continental collision around Eocene (Dèzes 1999). The Zanskar shear zone is one of the major structures that is represented by the normal sense of faulting and is equivalent to the South Tibetan Detachment System (STDS) (Searle 2013). The Suru and Doda rivers broadly follow the trace of the Zanskar shear zone (figure 1c).
The modern glaciers are preferentially located on the northern fringes of the HHC (southern part of the Zanskar hill ranges) and flow towards the north into the northeast–southwest trending river valleys. These glaciers invariably terminate in the vicinity of the Zanskar shear zone (figure 1).
3 Methodology
3.1 Glacial and para-glacial landforms
The geomorphological mapping was carried out using topographic sheets, field observations, hand held GPS, and the Google Earth images. Broadly, four major landforms were identified and mapped in the north facing tributary valleys of the Suru, Doda and Zanskar rivers. These are the (i) moraines, (ii) glacio-fluvial terraces, (iii) scree and alluvial fans, and (iv) pro-glacial lake deposits. At places, scanty occurrence of loessic silt is also observed.
Stratigraphy of the moraine is reconstructed using the conventional criteria such as morphology, sedimentary texture, relative elevation, degree of weathering, and extent of vegetation cover. The moraines are numbered from the youngest to oldest. For example, TGm-1 corresponds to the youngest moraine (m) of Tarangoz (TG) glacier. Likewise, outwash gravel terraces are identified and classified into different generations using sedimentary attributes like sorting, orientation, imbrication and texture, relative elevation, extent of weathering, and development of soil cover. These are also numbered from the youngest to oldest in each valley (e.g., SFt-1 stands for the youngest terrace (T1) in Shafat valley). Loess occur as thin drape over moraines and alluvial fans, and was identified in the field by its yellowish, friable, massive texture having hairpin pores with occasional presence of paleosols (Pye 1995; Pant et al. 2005). Lake deposits are buff coloured, laminated, silty-clay layers (Juyal et al. 2004, 2009) occurring as discrete patches that overlie moraines and/or terrace gravels. Alluvial fans and scree deposits were identified from their fan-shaped morphology with distal and proximal grading in sediment texture. Alluvial fans are differentiated from scree fans being associated with distinct catchments with streams and having finer grain size at the distal end (Blair and McPherson 1994; Hales and Roering 2005).
Besides the existing chronology obtained on glaciogenic sediments in the SZR by various workers, e.g., Taylor and Mitchell (2000); Lee et al. (2014); Saha et al. (2015) and Sharma et al. (2016), three new optically stimulated luminescence (OSL) ages are obtained in the present study on coarse grain quartz extracted from moraine and loess at Drang-Drung and lake deposits at Padam. Since the overdispersion in the equivalent dose is \(\le \)32%, the ages were calculated using Central Age Model (CAM) (Bailey and Arnold 2006). The details regarding methodological aspects used in the optical dating are discussed in Sharma et al. (2016).
4 Results
4.1 The Suru Valley
4.1.1 Tarangoz glacier (\(34{^{\circ }}3'58.10''\text {N}, 75{^{\circ }}55'25.89''\text {E}; 3370\;\text {m}\))
Near Tarangoz village, two generations of lateral moraines and two levels of gravel terraces were identified on the southern valley flank. The oldest moraine (TGm-2), covered with shrubs and grasses, laterally extends down to the Suru River and is incised by the glacial melt stream. The moraine is represented by two recessional ridges. The sharp crested, crudely developed, curvilinear latero-frontal, younger moraine (TGm-1) terminates \(\sim \)1000 m above the older terminal moraine (TGm-2). It is devoid of vegetation and is fresh in appearance (figure 2a).
At the exit, along the Suru Valley (\(34{^{\circ }}05'13.0''\)N, \(76{^{\circ }}00'29.0''\)E), two generations of glacio-fluvial terraces were observed. The older terrace (TGt-2) is \(\sim \)8 m thick, where the lithoclast assemblages are dominated by moderately sorted, crudely upward fining, sub-rounded to rounded boulders embedded in gritty-sand matrix (figure 2a). The less extensive younger terrace (TGt-1) is located \(\sim \)1.5 m above the present riverbed. It is composed of poorly organized lithoclast assemblages (not shown in figure). The terraces are incised by tributary streams, which have also deposited alluvial fan facies insets.
4.1.2 Parkachik glacier (\(34^{\circ } 05'43.3''\text {N}, 76^{\circ } 00' 0.01''\text {E};3100\;\text {m}\))
This glacier has a catchment in the Nun-Kun massif. The snout has steep gradient; as a result, the snout is riddled with multiple transverse crevasses. The glacier has receded marginally in the recent times as indicated by the presence of proglacial lakes behind the recessional moraines (figure 2b).
Three generations of lateral moraines were identified along the western flank (figure 2b). The oldest lateral moraine (PCm-3) having a sub-rounded crest, is covered with grasses, and bifurcates into two linear moraine ridges. The second generation is represented by \(\sim \)300 m long, \(\sim \)50 m thick, paired, sharp crested, unstable lateral moraine ridges (PCm-2). The moraines are relatively fresh, comprise of matrix supported sub-angular to sub-rounded clast and are devoid of appreciable vegetation. The youngest PCm-1 is proximal to the modem glacier and represents the recent re-advancement (figure 2b).
4.1.3 Shafat glacier (\(34{^{\circ }}03'32.8''\)N, \(76{^{\circ }}10'27.2''\)E; 3940 m)
The wide north trending Shafat glaciated valley is well graded and meets the Suru river valley near Shafat village. The valley has multiple cirque glaciers, the avalanche debris emanating from these glaciers have significantly obliterated the moraine stratigraphy, except around the valley mouth where relatively well preserved, but fluvially modified moraines are observed (figure 3). The oldest glacier advancement (SFm-4) is represented by a hanging half ‘U’-shaped ridge at the confluence of the Shafat River and Suru River (figure 3a). The younger advancements are represented by the lateral moraine (SFm-3) and the latero-frontal moraines (SFm-2 and SFm-1). The SFm-3 moraine is degraded and can be traced along the southern flank of the Shafat valley near the confluence (figure 3a). The paired latero-frontal moraine SFm-2 has moderate cover of grasses and shrubs (figure 3a). The moraines are incised into semi-circular mounds by multiple fluvial channels and are draped with stratified, fluvial sand and gravel. The SFm-1 is the youngest latero-frontal moraine that can be differentiated into three distinct recessional moraine ridges (figure 3b and c). These ridges, draped by laminated sediment, have fresh appearance and are devoid of vegetation.
At the confluence, the Suru river flows through an exceptionally wide channel containing point and braid bars. The SFt-3 terrace gravels can be laterally traced in the upstream along the SFm-3 moraines. Thus, suggesting that these are the oldest terrace gravel deposited following the recession of SFm-3 moraine. However, a definite inference would await the chronometric data. The terrace gravels are degraded and overlain by pedogeneised sandy-silt patches. Also, the outwash gravel terrace (SFt-2) (figure 4a and b; \(34{^{\circ }}03'54.9''\)N, \(76{^{\circ }}10'16.1''\)E; 3922 m) is incised into five surfaces having vertical offset ranging between 1 and 3 m that abut the moraines on either banks of the river. The sediment texture and lithoclast assemblage are dominated by pebbly sandy matrix containing poorly sorted, sub-angular to sub-rounded, crystalline lithoclast. The sandy horizon shows presence of planar and ripple laminated, crudely upward fining, medium-coarse sand, alternating with discontinuous clay layers. The younger terrace (SFt-1) is preserved along the meandering loops and is represented by \(\sim \)5 m thick, laterally impersistent gravel (figure 4c and d). The sedimentary structures and texture is suggestive of deposition during flashy, high energy fluvial discharge (Miall 2013; Bisht et al. 2015).
4.1.4 Ringdom Gompa (\(34{^{\circ }}00'21.4''\text {N},\; 76{^{\circ }}22'41.3''\)E; 4039 m)
Around Ringdom Gompa, a lateral moraine (RIm-1), with three recessional ridges abuts the Suru Valley (figure 4e). The recessional moraines are draped by sub-rounded to sub-angular fluvial gravels. At places, active scree deposits concealed/eroded the moraines.
4.1.5 Tributary Glacier (\(33{^{\circ }}53'14.5''\)N, \(76{^{\circ }}20'18.1''\)E; 4439 m)
To the west of Pensi La, a major tributary glacier extends into the Suru Valley, and has deposited a prominent lateral moraine (TRm-1; figure 5a). The moraine is draped with gritty sand containing sub-rounded to angular lithoclast with occasional sand lenses implying short-lived fluvial activity. The moraine contains a modern and a buried soil (figure 5b). The modern soil has a 10 cm thick B-horizon of fine silty-sand, which is overlain by 10 cm thick humus horizon (A-horizon). The buried soil is \(\sim \)30 cm thick, containing 25 cm thick B-horizon that is dominated by light brown silty sand. It is followed by 5 cm thick humus/peat layer (A-horizon).
At the confluence of the Suru River, TRm-1 moraine is considerably modified by the fluvial activity. A fluvial terrace (TRt-1) incised into two surfaces, abuts the moraine. The sedimentary texture of the terrace comprises of crudely upward fining, platy pebbles, oriented crudely parallel to the bedding surface. At places, the edges of the platy lithoclast are sub-rounded. The terrace TRt-1 contains \(\sim \)40 cm thick, coarse-medium, moderately rubified sand with dispersed angular lithoclast. The sandy horizon is overlain by angular to sub-rounded boulders. In the downstream, where the river channel is wider, presence of alternate lake and fluvial gravel sequence suggests multiple impounding and breaching events (figure 5c and d).
4.2 Doda (Stod) and Zanskar Valley
4.2.1 Drang-Drung Glacier (\(33{^{\circ }}52'08.4''\)N, \(76{^{\circ }}21'11.7''\)E; 4365 m)
At Pensi La (La=pass; \(\sim \)4452 m), which is a water divide between the Suru and Doda River, three major glacial events can be discerned in the vicinity of Drang-Drung Glacier. The older events (DDm-3 and DDm-2) are represented by curvilinear, well-rounded moraine ridges, which are flanked by kettle holes. These have reasonably well-developed soil, are covered with grasses and can be differentiated into subsidiary (recessional) moraine ridges of decreasing elevation (figure 6). The last moraine ridge of DDm-2 terminates with a steep \(\sim \)50 m vertical scarp (figure 7). The third glacial advance, DDm-1, occurred after the glacier was deflected eastward into the Doda river valley. The DDm-1 glaciation is represented by around eight curvilinear, latero-frontal moraines (\(\sim \)4410 m), which bifurcate towards east after trending S–N (parallel to Drang-Drung Glacier; figure 7). The eighth (youngest) paired lateral moraine ridge is dated to 4.8±0.4 ka (\(\sim \)4009 m; figure 7d). The moraines are fresh, loose, and contain no vegetation cover. A pro-glacial lake and push moraines with dead ice are also observed near the snout of the glacier.
About 1 m thick loessic-silt containing two paleosols, overlies the DDm-2 moraine mixed avalanche debris sediments (\(33{^{\circ }}5'20.4''\)N, \(76{^{\circ }}21'51.2''\)E; 4410 m; figure 7a). The lower paleosol is divided into \(\sim \)40 cm thick, buff coloured, loess horizon, containing hairpin pores, and occasional pebbles (C-horizon). This is followed by \(\sim \)30 cm thick, weakly weathered B-horizon, which is capped by \(\sim \)15 cm thick, humus rich Ah-horizon. The upper soil profile does not have the parent C-horizon, instead it comprises of \(\sim \)10 cm thick B-horizon, and upper \(\sim \)10 cm thick A-horizon. The C-horizon (loess) of the lower paleosol is optically dated to 2.5±0.3 ka (figure 7a). A degraded relict lake deposit is also observed nestled between the curvilinear moraine ridges corresponding to DDm-2 glaciation at Pensi La (figure 7b).
4.2.2 Padam Valley (\(33{^{\circ }}29'39.5''\)N, \(76{^{\circ }}49'20.0''\)E; 3609 m)
In the Padam Valley, four generations of moraines representing four glaciations are preserved. The moraines emanate from the western tributary and are named as PDm-4 (oldest) to PDm-1 (youngest). The PDm-4 moraine is highly degraded, indurated and comprises of isolated tillite pinnacles that overlie the rocky slopes particularly around Stongde village (figure 8a). This seems to be the oldest moraine observed so far in the SZR. The PDm-3 lateral moraines abut the valley flanks, and extend up to \(\sim \)15 km downstream in the Zanskar Valley, where these terminate as latero-frontal moraines. In the upstream (around Karsha village), the moraines are differentiated into five discontinuous lateral moraine ridges (figure 8c), suggesting pulsating recession of PDm-3 glaciation. The recessional moraines are draped by fluvial gravels and also obliterated by the large alluvial fans, which are associated with relict or active cirques glaciers (figure 8b). The younger PDm-2 moraines preserved near the exit of the Seni Valley are dissected by the melt water streams and are draped with fluvial gravels giving rise to hummocky mounds (figure 8d). The youngest PDm-1 latero-frontal moraines are confined within the Seni Valley.
The two generations of outwash gravel terraces are also identified in the Padam Valley (figure 8b). The older PDt-2 outwash terrace gravel (\(33{^{\circ }}28'41.9''\)N, \(76{^{\circ }}53'55.4''\)E; 3551 m) is \(\sim \)15 m thick and has sub-rounded, clast supported deposit. It is overlain by laterally persistent relict lake sediments (figure 9a–c), which are preserved along the eastern flank of the Padam village (\(33{^{\circ }}28'41.9''\)N, \(76{^{\circ }}53'55.4''\)E; 3551 m). Based on the texture and sedimentary structures, the relict lake succession can be differentiated into two broad units. The lower 2 m thick unit-I is dominated by parallel laminated silty-clay (varves and rhythmites), alternating with coarse-gritty sand. The upper part of this unit show convolute bedding (cryoturbated?, figure 9c and e). The upper \(\sim \)2.5 m thick unit-II is dominated by crudely laminated, angular lithoclast with sub-ordinate silty-clay layers suggesting their deposition as alluvial fan facies. The frequency of clayey-silt layers decreases towards the top and weakly developed soil is also observed. The relict lake sediment overlying the fluvial gravel indicates that the lake came into existence following the obstruction caused by the alluvial fans (figure 9a and b). The middle part of the lake sediment is dated to 3.8±0.5 ka (figure 9c), implying that the lake probably represents the late Holocene climatic instability (aridity/cooling).
The younger outwash terrace (PDt-1) is \(\sim \)10 m thick and abuts the older terrace. Scree fans are present all along the valley slopes and at places drape the moraines and gravel terraces, thus suggesting them to be the youngest geomorphic feature in the study area (figure 9).
4.3 Composite stratigraphy
The composite alluvial stratigraphy is reconstructed based on the field relationship of the multiple generations of moraines, outwash gravel terraces, alluvial fans and lacustrine deposits observed in the seven glacier valleys. The inferred glacial stages are named using a common nomenclature, viz., the Southern Zanskar Glaciation Stage (SZS) (table 1). This allowed us to identify four major glacial stages – the SZS-4 (oldest) to SZS-1 (youngest) and three deglaciation events that broadly correlate with the SZS-3, 2, and 1. Detailed description is given in table 1 and figure 10.
5 Discussion
The semi-arid Ladakh and Karakoram ranges preserves the oldest record of glaciation in the Himalayan orogen (>430 ka; MIS-6/3; Phillips et al. 2000; Richards et al. 2000; Owen et al. 2006; Seong et al. 2007). Dortch et al. (2013) have summarized the existing chronology from the NW Himalaya and suggest that the terrain has preserved a record of around nine major glaciations starting from MIS-10/9, which they called the semi-arid Western Himalayan Tibetan stages (SWHTS). However, in the Zanskar Himalaya, the studies so far indicate five major glaciations. The oldest glaciation is dated to \(\sim \)311 and 116 ka in the northern Zanskar valleys and corresponds to the MIS-9/5 (Hedrick et al. 2011). This is equivalent to SWHTS 9/5E regional stages defined by Dortch et al. (2013). During this phase, the glaciers are suggested to expand >10 km from the present day ice margin into the main valleys. The next glacial advance is represented by subdued, highly eroded and obliterated moraines or the bedrock trim lines, which are dated/correlated to the MIS-4/3 (\(\sim \)80–40 ka; SWHTS 5A/3) in the southern Zanskar (Dortch et al. 2013). During MIS-4/3, it is suggested that trunk valleys were extensively glaciated (Taylor and Mitchell 2000; Damm 2006; Dortch et al. 2013; Lee et al. 2014; Sharma et al. 2016). The ELA was lowered between >1000 (north) and 350 m (south) with a corresponding temperature decrease of \({\sim }3{^{\circ }}\)C (Taylor and Mitchell 2000; Damm 2006; Hedrick et al. 2011; Orr et al. 2016). The third glaciation in Zanskar occurred during MIS-2 (equivalent to SWHTS 2B/C) and LGM in response to the mid-latitude westerlies (\(\sim \)20–16 ka) which is represented by well-preserved, vegetated moraines having rounded crests. The glaciers, however, did not expand beyond the exit of the tributary valleys (Taylor and Mitchell 2000; Lee et al. 2014; Sharma et al. 2016). The Zanskar glaciers also expanded during MIS-1 in late Pleistocene/early Holocene (14–7 ka; SWHTS 2B-1D), and lastly during early-mid Holocene (<6 ka; SWITS 1C-1A) in response to the North Atlantic Oscillations (Damm 2006; Lee et al. 2014; Saha et al. 2015; Sharma et al. 2016).
In order to provide the chronostratigraphy of the various glacial stages, we used the stratigraphically equivalent published ages from the Nun-Kun Massif in SZR by Lee et al. (2014) and three new optical ages obtained during the present study. The oldest age given by Lee et al. (2014) is from the bedrock trim line of the Sentik glacier (Nun-Kun massif), which they ascribe to the MIS-4/3 glacial stage (Achambur glaciation). In Padam Valley, Mitchell et al. (1999) and Taylor and Mitchell (2000) dated moraine dammed lake in the Tsarp Chu River to \(\sim \)80 ka and assigned it to the above glaciation. Stratigraphically equivalent moraines of SZS-4 glaciation would correspond to the MIS-4/3, which in the study area are represented by glacially polished ridges at Shafat and tillite pinnacles in Padam Valley. Thus, it would imply that the SZS-4 glaciation was driven by a combination of enhanced mid-latitude westerlies during the MIS-4 and/or strengthened ISM during the earlier part of pluvial MIS-3 (Owen et al. 2001; Juyal et al. 2006). This looks reasonable considering that the SZR is located in the transitional climatic zone and is influenced both by the ISM and mid-latitude westerlies (Owen and Benn 2005; Leipe et al. 2014).
The SZS-3 moraines terminate as poorly defined ridges at the tributary valley mouths, except in the case of relatively wide Padam Valley, where the moraines were deposited down to an elevation of 3500 m (\(\sim \)15 km from the snout). Also, at Drang-Drung these are preserved as curvilinear latero-frontal moraines (DDm-3). Stratigraphically, the moraines are equivalent to Tongul stage of Lee et al. (2014) that is dated between \(\sim \)14 and \(\sim \)19 ka. We suggest that the SZS-3 stage probably began around the LGM (mid MIS-2) and continued till the later part of the MIS-2, although a conclusive statement should await chronometric data. Unlike the east–west trending Doda and Suru valleys, the SZS-3 moraines in the north–south trending Padam Valley extended down into the Zanskar river valley implying that valley orientation (N–S) perhaps played an important role in glacier expansion. The SZS-3 glaciation in Padam Valley is represented by five linear moraine ridges of decreasing heights, suggesting pulsating reduction in ice volume (figure 8). Studies from the northwestern (Nagar et al. 2013; Sharma et al. 2016) and monsoon dominated western and central Himalaya (Ali et al. 2013; Bali et al. 2013; Bisht et al. 2015; Eugster et al. 2016) indicate that valley glaciers expanded during the LGM. However, compared to its older counterpart, the LGM glaciation was less extensive (Dortch et al. 2013 and references therein). Therefore, we suggest that the SZS-3 glaciation probably represent a period of intensified mid-latitude westerly corresponding to LGM (Benn and Owen 1998; Sharma et al. 2016) or later part of MIS-2 during which a gradual strengthening of ISM is suggested (Duplessy 1982; Schulz et al. 1998).
The SZS-2 moraines terminate marginally above the exit of the tributary valleys. Stratigraphically and morphologically the moraines are equivalent to ST1; TG2; and RT1 glaciers in Nun-Kun massif that are dated to early part of the late glacial (Amantick stage; Lee et al. 2014). In the eastern Zanskar Valley, the early Holocene advancement was suggested to be \(\sim \)8 ka (Sharma et al. 2016). Speculatively, we tend to suggest that SZS-2 glaciation occurred during the early to mid-Holocene – a period known for moderate ISM and cooler air temperature (Gasse et al. 1990; Thompson et al. 1997; Sati et al. 2014). Here it is important to mention that until around SZS-3, Drang-Drung Glacier was flowing westward into the Suru river valley. It was during the deposition of SZS-2 moraines, the pulsating decrease in ice volume led to the eastward deflection of the glacier snout (towards the Doda Valley). This is manifested by the presence of around eight curvilinear recessional moraine ridges (figure 7e and f). The youngest eighth moraine ridge is dated to \(\sim \)5 ka.
The youngest SZS-1 moraines are preserved as curvilinear ridges in Shafat Valley. Stratigraphically, the moraine is equivalent to the TG3 and TG4 moraines of the Nun-Kun massif that are dated to the Little Ice Age (LIA) (Lomp and Tanak stages; Lee et al. 2014). Though at Drang-Drung, Osmaston (2001) had suggested moraines near the snout to be few centuries old, the youngest lateral moraine ridge discerned by us is dated to \(\sim \)5 ka (late mid-Holocene; Walker et al. 2012).
Evidence of deglaciation is represented by the outwash gravel terraces. In the absence of absolute chronology, it is difficult to assign the glacial stages to individual outwash gravel terraces. However, given the fact that ISM fluctuated since MIS-2 (Thompson et al. 1997; Schulz et al. 1998, figure 11), the outwash gravel terraces would represent the phases of warm climatic intervals, which led to the mobilization of glacial and paraglacial sediment as also recently suggested by Jonell et al. 2017) in the Doda river valley. The alluvial fans show cross-cutting relationship with older terraces, and suggest that these were activated at the end of deglaciation events. Based on their stratigraphic position with respect to the lake deposits (dated to \(\sim \)4 ka), it would be reasonable to suggest that the alluvial fan aggradation would have occurred after mid-Holocene transitional climate. The loess deposits represent the drier conditions whereas, the intervening humus rich horizons imply temporary wetness (Pant et al. 2005). Lee et al. (2014) have dated the loess-paleosols in the adjoining valleys to c.1.5, c.3.4, and c.5.2 ka, and Sharma et al. (2016) have dated drumlins and lake deposits (representing deglaciation and warming) from eastern Zanskar to \(\sim \)4 and \(\sim \)3 ka. In the present study, the paleosol at Pensi La is dated to \(\sim \)2.5 ka that broadly lies within the above age brackets.
Figure 11 summarizes the observations made in the present study. The existing chronology from various studies including the present study in the Zanskar ranges is plotted against the \(\delta ^{18}\)O values from Guliya ice core (Thompson et al. 1997), which serve as a proxy for ISM intensity. The isotopically light values indicate weaker monsoons with cooler temperature and vice versa. The event stratigraphy from the present study is also plotted in the last panel. The study suggests that SZR responded sensitively to variability in both the ISM and mid-latitude westerlies. The glaciation seems to have occurred during wet phases when the temperature was low while the deglaciation perhaps occurred during warm pluvial phases. However, more definitive inferences towards the factors responsible for driving glaciation and deglaciation should await a detailed chronometric study.
6 Conclusions
The SZR has preserved at least four phases of glaciations (SZS-4 to SZS-1) and three phases of deglaciation since the last 80 ka. The oldest SZS-4 glaciation is assigned MIS-4/3 and the subsequent phases, viz., SZS-3, SZS-2, and SZS-1 are assigned MIS-2/LGM, early-mid Holocene, and the LIA, respectively.
The stratigraphic correlation of the glacial stages with that of the chronologically dated sequences in the region indicates a broad synchronicity in glacial advancements across the Zanskar Himalaya since the MIS-4. It seems that the most extensive glaciation in the southern Zanskar Valley was initiated during the strengthened mid-latitude westerlies (MIS-4) and sustained by the enhanced moisture contribution during the early phase of the pluvial MIS-3. The initiation of the SZS-3 glaciation is ascribed to the global LGM and MIS-2 implying the role of strengthened mid-latitude westerlies whereas, for the younger glaciations, viz., SZS-2 and 1, seems to be driven by a favourable combination of temperature and precipitation (ISM and mid-latitude westerlies). Our study suggests that the Drang-Drung Glacier that was feeding the Suru river valley in the west was deflected eastward into the Doda (Stod) river valley due to the decrease in ice volume after SZS-3.
The study identifies three phases of deglaciation that are ascribed to the post-LGM, insolation driven, strengthened ISM. The termination of the deglaciation is marked by alluvial fan sedimentation, which impounded the Zanskar River and created a temporary lacustrine condition during periods of low discharge. This phase corresponds to the late-Holocene aridity which is also indicated by the deposition of loess around Pensia La.
Although preliminary in nature, the study suggests that the SZR glaciers, being in transitional climatic zone, are likely to respond sensitively to even the minor changes in both ISM and the mid-latitude westerlies.
Change history
13 March 2018
The affiliations of the authors were inaccurate in the original publication.
References
Ali S N, Biswas R H, Shukla A D and Juyal N 2013 Chronology and climatic implications of Late Quaternary glaciations in the Goriganga valley, central Himalaya, India; Quat. Sci. Rev. 73 59–76.
Bali R, Ali S N, Agarwal K K, Rastogi S K, Krishna K and Srivastava P 2013 Chronology of late Quaternary glaciation in the Pindar valley, Alaknanda basin, central Himalaya (India); J. Asian Earth Sci. 66 224–233.
Bailey R M and Arnold L J 2006 Statistical modeling of single grain quartz de distributions and an assessment of procedures for estimating burial dose; Quat. Sci. Rev. 25 2475–2502.
Beniston M 2006 Mountain weather and climate: A general overview and a focus on climatic change in the Alps; Hydrobiologia 562(1) 3–16.
Benn D I and Owen L A 1998 The role of the Indian summer monsoon and the mid-latitude westerlies in Himalayan glaciation: Review and speculative discussion; J. Geol. Soc. 155(2) 353–363.
Benn D I, Owen L A, Osmaston H A, Seltzer G O, Porter S C and Mark B 2005 Reconstruction of equilibrium-line altitudes for tropical and sub-tropical glaciers; Quat. Int. 138 8–21.
Bhutiyani M R, Kale V S and Pawar N J 2010 Climate change and the precipitation variations in the northwestern Himalaya: 1866–2006; Int. J. Climatol. 30(4) 535–548.
Bisht P, Ali S N, Shukla A D, Negi S, Sundriyal Y P, Yadava M G and Juyal N 2015 Chronology of late Quaternary glaciation and landform evolution in the upper Dhauliganga valley (Trans Himalaya), Uttarakhand, India; Quat. Sci. Rev. 129 147–162.
Blair T C and McPherson J G 1994 Alluvial fan processes and forms; In: Geomorphology of desert environments, Springer Netherlands, pp. 354–402.
Bolch T, Kulkarni A, Kääb A, Huggel C, Paul F, Cogley J G, Frey H, Kargel J S, Fujita K, Scheel M and Bajracharya S 2012 The state and fate of Himalayan glaciers; Science 336(6079) 310–314.
Bond G, Kromer B, Beer J, Muscheler R, Evans M N, Showers W, Hoffmann S, Lotti-Bond R, Hajdas I and Bonani G 2001 Persistent solar influence on North Atlantic climate during the Holocene; Science 294(5549) 2130–2136.
Brahmbhatt R M, Bahuguna I M, Rathore B P, Kulkarni A V, Shah R D, Rajawat A S and Kargel J S 2017 Significance of glacio-morphological factors in glacier retreat: A case study of part of Chenab basin, Himalaya; J. Mt. Sci. 14(1) 128–141.
Brodzikowski K and Van Loon A J 1991 Review of glaciogenic sediments; Dev. Sedimentol. 49 688.
Dadson S J and Church M 2005 Postglacial topographic evolution of glaciated valleys: A stochastic landscape evolution model; Earth Surf. Process. 30(11) 1387–1403.
Damm B 2006 Late Quaternary glacier advances in the upper catchment area of the Indus River (Ladakh and western Tibet); Quat. Int. 154 87–99.
Dèzes P 1999 Tectonic and metamorphic evolution of the central Himalayan domain in southeast Zanskar (Kashmir, India) 145, Université de Lausanne.
Dortch J M, Owen L A and Caffee M W 2010 Quaternary glaciation in the Nubra and Shyok valley confluence, northernmost Ladakh, India; Quat. Res. 74(1)132–144.
Dortch J M, Owen L A and Caffee M W 2013 Timing and climatic drivers for glaciation across semi-arid western Himalayan–Tibetan orogen; Quat. Sci. Rev. 78 188–208.
Duplessy J C 1982 Glacial to interglacial contrasts in the northern Indian Ocean; Nature 295 494–498.
Eugster P, Scherler D, Thiede R C, Codilean A T and Strecker M R 2016 Rapid last glacial maximum deglaciation in the Indian Himalaya coeval with midlatitude glaciers: New insights from 10Be-dating of ice-polished bedrock surfaces in the Chandra Valley, NW Himalaya; Geo. Res. Lett., https://doi.org/10.1002/2015GL066077.
Gasse F, Tehet R, Durand A, Gilbert E and Fontes J-Ch 1990 The arid–humid transition in the Sahara and Sahel during the last deglaciation; Nature 346 141–146.
Grove A T 2008 A brief consideration of climate forcing factors in view of the Holocene glacier record; Global Planet Change 60 141–147.
Hales T C and Roering J J 2005 Climate-controlled variations in scree production, Southern Alps, New Zealand; Geology 33(9) 701–704.
Hedrick K A, Seong Y B, Owen L A, Caffee M W and Dietsch C 2011 Towards defining the transition in style and timing of Quaternary glaciation between the monsoon-influenced Greater Himalaya and the semi-arid Transhimalaya of northern India; Quat. Int. 236(1) 21–33.
Hewitt K 1999 Quaternary moraines vs. catastrophic rock avalanches in the Karakoram Himalaya, northern Pakistan; Quat. Res. 51(3) 220–237.
Hughton J T, Ding Y, Griggs D J, Noguer, M, van der Linden P J, Dai X, Maskell K and Johnson C A (eds) 2001 Climate change 2001: The scientific basis, Cambridge University Press, Cambridge, U.K.
Jonell T N, Carter A, Böning P, Pahnke K and Clift P D 2017 Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India; Geol. Soc. Am. Bull. 129(7–8) 820–836.
Johnsen S J, Clausen H B, Dansgaard W, Fuhrert K, Gundestrup N, Hammer C U, Iversen P, Jouzel I and Stauffer B 1992 Irregular glacial interstadials recorded in a new Greenland; Nature 3 311–313.
Juyal N, Chamyal L S, Bhandari S, Bhushan R and Singhvi A K 2006 Continental record of the southwest monsoon during the last 130 ka: Evidence from the southern margin of the Thar Desert, India; Quat. Sci. Rev. 25(19) 2632–2650.
Juyal N, Pant R K, Basavaiah N, Bhushan R, Jain M, Saini N K, Yadava M G and Singhvi A K 2009 Reconstruction of Last Glacial to early Holocene monsoon variability from relict lake sediments of the higher central Himalaya, Uttrakhand, India; J. Asian Earth Sci. 34(3) 437–449.
Juyal N, Pant R K, Basavaiah N, Yadava M G, Saini N K and Singhvi A K 2004 Climate and seismicity in the higher central Himalaya during 20–10 ka: Evidence from the Garbayang basin, Uttaranchal, India; Palaeogeogr. Paleoclimatol. Paleoecol. 213(3) 315–330.
Juyal N, Sundriyal Y P, Rana N, Chaudhary S and Singhvi A K 2010 Late Quaternary fluvial aggradation and incision in the monsoon-dominated Alaknanda valley, central Himalaya, Uttrakhand, India; J. Quat. Sci. 25(8) 1293–1304.
Lee S Y, Seong Y B, Owen L A, Murari M K, Lim H S, Yoon H I and Yoo K C 2014 Late Quaternary glaciation in the Nun-Kun massif, northwestern India; Boreas 43(1) 67–89.
Leipe C, Demske D, Tarasov P E, Wünnemann B, Riedel F and Members H P 2014 Potential of pollen and non-pollen palynomorph records from Tso Moriri (Trans-Himalaya, NW India) for reconstructing Holocene limnology and human–environmental interactions; Quat. Int. 348 113–129.
Lowe J J and Walker M J 2014 Reconstructing quaternary environments; 3rd edn, Routledge, Taylor & Francis Group, London & New York.
Mayewski P A, Lyons W B, Ahmad N, Smith G and Pourchet M 1984 Interpretation of the chemical and physical time-series retrieved from Sentik Glacier, Ladakh Himalaya, India; J. Glaciol. 30(104) 66–76.
Miall A 2013 The geology of fluvial deposits: Sedimentary facies, basin analysis, and petroleum geology; Springer.
Mitchell W A, Taylor P J and Osmaston H 1999 Quaternary geology in Zanskar, NW Indian Himalaya: Evidence for restricted glaciation and preglacial topography; J. Asian Earth Sci. 17(3) 307–318.
Mote P W and Kaser G 2007 The shrinking glaciers of Kilimanjaro: Can global warming be blamed?; Am. Sci. 95(4) 318–325.
Nagar Y C, Ganju A, Satyawali P K and Juyal N 2013 Preliminary optical chronology suggests significant advance in Nubra valley glaciers during the Last Glacial Maximum; Curr. Sci. 105(1) 96–101.
Orr E N, Owen L A, Murari M K, Saha S and Caffee M W 2016 The timing and extent of Quaternary glaciation of Stok, northern Zanskar Range, Transhimalaya, of northern India; Geomorphology 284 142–155, https://doi.org/10.1016/j.geomorph.2016.05.031.
Osmaston A H 2001 The geology, geomorphology and Quaternary history of Zangskar; In: Himalayan Buddhist Villages environment, resources, society and religion life in Zagskar, Ladakh (eds) Osmaston A H and Crook H J, University of Bristol.
Owen L A and Benn D I 2005 Equilibrium-line altitudes of the last glacial maximum for the Himalaya and Tibet: An assessment and evaluation of results; Quat. Int. 13855–78.
Owen L A and Dortch J M 2014 Nature and timing of Quaternary glaciation in the Himalayan–Tibetan orogen; Quat. Sci. Rev. 88 14–54.
Owen L A, Caffee M W, Bovard K R, Finkel R C and Sharma M C 2006 Terrestrial cosmogenic nuclide surface exposure dating of the oldest glacial successions in the Himalayan orogen: Ladakh Range, northern India; Geol. Soc. Am. Bull. 118(3–4) 383–392.
Owen L A, Gualtieri L, Finkel R C, Caffee M W, Benn D I and Sharma M C 2001 Cosmogenic radionuclide dating of glacial landforms in the Lahul Himalaya, northern India: Defining the timing of Late Quaternary glaciation; J. Quat. Sci. 16(6) 555–563.
Pant R K, Basavaiah N, Juyal N, Saini N K, Yadava M G, Appel E and Singhvi A K 2005 A 20-ka climate record from central Himalayan loess deposits; J. Quat. Sci. 20(5) 485–492.
Pye K 1995 The nature, origin and accumulation of loess; Quat. Sci. Rev. 14(7) 653–667.
Phillips W M, Sloan V F, Shroder J F, Sharma P, Clarke M L and Rendell H M 2000 Asynchronous glaciation at Nanga Parbat, northwestern Himalaya Mountains, Pakistan; Geology 28(5) 431–434.
Richards B W, Owen L A and Rhodes E J 2000 Timing of Late Quaternary glaciations in the Himalayas of northern Pakistan; J. Quat. Sci. 15(3) 283–297.
Saha S, Sharma M C, Murari M K, Owen L A and Caffee M W 2015 Geomorphology, sedimentology and minimum exposure ages of streamlined subglacial landforms in the NW Himalaya, India; Boreas 5(2) 284–303.
Sati S P, Ali S N, Rana N, Bhattacharya F, Bhushan R, Shukla A D, Sundriyal Y and Juyal N 2014 Timing and extent of Holocene glaciations in the monsoon dominated Dunagiri valley (Bangni glacier), central Himalaya, India; J. Asian Earth Sci. 91 125–136.
Schulz H, von Rad U and Erlenkeuser H 1998 Correlation between Arabian Sea and Greenland climate oscillations of the past 110,000 years; Nature 393(6680) 54–57.
Searle M P 1986 Structural evolution and sequence of thrusting in the High Himalayan, Tibetan–Tethys and Indus suture zones of Zanskar and Ladakh, western Himalaya; J. Struct. Geol. 8(8) 923–936.
Searle M 2013 Colliding continents: A geological exploration of the Himalaya, Karakoram, and Tibet; Oxford University Press.
Seong Y B, Owen L A, Bishop M P, Bush A, Clendon P, Copland L, Finkel R, Kamp U and Shroder J F 2007 Quaternary glacial history of the central Karakoram; Quat. Sci. Rev. 26(25) 3384–3405.
Sharma S, Chand P, Bisht P, Shukla A D, Bartarya S K, Sundriyal Y P and Juyal N 2016 Factors responsible for driving the glaciation in the Sarchu Plain, eastern Zanskar Himalaya, during the late Quaternary; J. Quat. Sci. 31(5) 495–511.
Singh D S 2014 Surface processes during flash floods in the glaciated terrain of Kedarnath, Garhwal Himalaya and their role in the modification of landforms; Curr. Sci. 106(4) 59.
Singh D S and Mishra A 2002 Role of tributary glaciers on landscape modification in the Gangotri Glacier area, Garhwal Himalaya, India; Curr. Sci. 82(5) 567–570.
Singh D S, Tangri A K, Kumar D, Dubey C A and Bali R 2016 Pattern of retreat and related morphological zones of Gangotri Glacier, Garhwal Himalaya, India; Quat. Int., https://doi.org/10.1016/j.quaint.2016.07.025.
Street-Perrott F A and Roberts N 1983 Fluctuations in closed-basin lakes as an indicator of past atmospheric circulation patterns; In: Variations in the Global Water Budget (eds) Street-Perrott F A, Beran M A and Ratcliffe R A S, Reidel, Dordrecht pp. 365–383.
Taylor P J and Mitchell W A 2000 The Quaternary glacial history of the Zanskar Range, north-west Indian Himalaya; Quat. Int. 65 81–99.
Thompson L O, Yao T, Davis M E, Henderson K A, Mosley-Thompson E, Lin P N, Beer J, Synal H A, Cole-Dai J and Bolzan J F 1997 Tropical climate instability: The last glacial cycle from a Qinghai–Tibetan ice core; Science 276(5320) 1821–1825.
Walker M J C, Berkelhammer M, Björck S, Cwynar L C, Fisher D A, Long A J, Lowe J J, Newnham R M, Rasmussen S O and Eiss H 2012 Formal subdivision of the Holocene Series/Epoch: A Discussion Paper by a Working Group of INTIMATE (Integration of ice-core, marine and terrestrial records) and the Subcommission on Quaternary Stratigraphy (International Commission on Stratigraphy); J. Quat. Sci., https://doi.org/10.1002/jqs.2565.
Acknowledgements
This work is an outcome of the DST-sponsored field training programme coordinated by KSKV Kutchch University in 2015. Dr Navin Juyal is acknowledged for his guidance in the field work. Dr Anil Shukla, PRL, Ahmedabad, is acknowledged for radioactivity data. SS especially thanks Prof. M G Thakkar, Kutchch University and Dr S K Parcha, WIHG for their care and support during the field injury. We are also thankful to the three anonymous reviewers for their critical comments and suggestions which helped in improving the manuscript greatly.
Author information
Authors and Affiliations
Corresponding author
Additional information
Corresponding editor: Navin Juyal
A correction to this article is available online at https://doi.org/10.1007/s12040-018-0946-z.
Rights and permissions
About this article
Cite this article
Sharma, S., Hussain, A., Mishra, A.K. et al. Geomorphic investigation of the Late-Quaternary landforms in the southern Zanskar Valley, NW Himalaya. J Earth Syst Sci 127, 9 (2018). https://doi.org/10.1007/s12040-017-0911-2
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12040-017-0911-2