Recycling of Pleistocene valley fills dominates 135 ka of sediment flux, upper Indus River

Munack, Henry; Blöthe, Jan Henrik; Fülöp, Réka‐Hajnalka; Codilean, Alexandru T.; Fink, David; Korup, Oliver

doi:10.1016/j.quascirev.2016.07.030

Cited by 14 publications

(17 citation statements)

References 62 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The abundance of quartzofeldspathic, micaceous, and schistose metamorphiclastic detritus in the Zara (ID #10) sample might suggest an overspill connection existed between Tso Kar and the Zanskar River, as proposed by Demske et al (2009) andWünnemann et al (2010). Our provenance data from the Zara River neither support nor preclude sediment supply to the Zanskar River via an overspill connection (e.g,, Munack et al, 2016).…”

Section: Downstream Provenance Evolutionmentioning

confidence: 64%

See 1 more Smart Citation

Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India

Jonell

Carter

Böning

et al. 2017

Geological Society of America Bulletin

View full text Add to dashboard Cite

Section: Downstream Provenance Evolutionmentioning

confidence: 64%

“…Significant dissection of Pleistocene valley-fills in the upper Tsarap catchment highlights a long history of sediment reworking into the paleo-Zanskar River (Munack et al, 2016).…”

Section: Controls On Erosionmentioning

confidence: 99%

Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India

Jonell

Carter

Böning

et al. 2017

Geological Society of America Bulletin

View full text Add to dashboard Cite

“…There are multiple opportunities for sediment buffering in the Indus basin, especially because the flood plains are long (>1,000 km; Figures 1 and 2). Sediment storage in mountain terraces is also well documented (Blöthe et al, 2014;Jonell, Owen, Carter, Schwenniger, & Clift, 2017;Munack et al, 2016), and a high fraction of the Holocene sediment supply appears to be derived by reworking from these terraces , as well as large-scale incision of the flood plains . Furthermore, the Indus River recycles sediment from the neighbouring Thar Desert (Figure 2), which itself is supplied by aeolian sediment transport from the delta, especially during interglacial times when the summer monsoon winds are powerful (East, Clift, Carter, Alizai, & VanLaningham, 2015).…”

Section: Buffering and Recyclingmentioning

confidence: 99%

Millennial and centennial variations in zircon U‐Pb ages in the quaternary indus submarine canyon

Clift

O’Sullivan³

2018

Basin Research

View full text Add to dashboard Cite

Use of deep‐water sediments in submarine fans to reconstruct changing erosion onshore is based on the premise of relatively simple transport between source and sink. However, debate continues regarding the degree of sediment buffering and recycling in the sediment transport process. In this study, we investigate the origin of sediment in the Indus Submarine Canyon since the Last Glacial Maximum (LGM; ~20 ka) using zircon U‐Pb dates. Zircon grains in the submarine canyon are resolvably different from those at the river mouth, at least before 6.6 ka, implying a disconnection between the river mouth and the canyon up to that time. Sand may be stored near the river mouth as sea level rose, while finer‐grained sediment was directly transferred into deeper water. Since 1 ka the upper canyon has shown big and rapid provenance changes, most notably a sharp increase in erosion from Nanga Parbat, whose influence is minor in the modern river. Such rapid changes imply a lack of buffering in the recent past. The modern river contrasts with sediments in the canyon in terms of its zircon U‐Pb age populations and may be influenced by significant anthropogenic impact on the terrestrial drainage basin, especially damming.

show abstract

“…Across the Himalaya, wide (>5 km), glacially scoured, and overdeepened intermontane river basins provide exceptional accommodation space for sediment storage (Owen et al, 2006; Korup et al, 2010; Bolch et al, 2012; Blöthe and Korup, 2013). Thick alluvial river terrace sequences document considerable storage and release of sediment on shorter, climate-relevant time scales (Bookhagen et al, 2006; Srivastava et al, 2008; Blöthe et al, 2014; Scherler et al, 2015; Dey et al, 2016; Munack et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Quantifying episodic erosion and transient storage on the western margin of the Tibetan Plateau, upper Indus River

et al. 2017

View full text Add to dashboard Cite

Transient storage and erosion of valley fills, or sediment buffering, is a fundamental but poorly quantified process that may significantly bias fluvial sediment budgets and marine archives used for paleoclimatic and tectonic reconstructions. Prolific sediment buffering is now recognized to occur within the mountainous upper Indus River headwaters and is quantified here for the first time using optically stimulated luminescence dating, petrography, detrital zircon U-Pb geochronology, and morphometric analysis to define the timing, provenance, and volumes of prominent valley fills. This study finds that climatically modulated sediment buffering occurs over 103–104yr time scales and results in biases in sediment compositions and volumes. Increased sediment storage coincides with strong phases of summer monsoon and winter westerlies precipitation over the late Pleistocene (32–25 ka) and mid-Holocene (~8–6 ka), followed by incision and erosion with monsoon weakening. Glacial erosion and periglacial frost-cracking drive sediment production, and monsoonal precipitation mediates sediment evacuation, in contrast to the arid Transhimalaya and monsoonal frontal Himalaya. Plateau interior basins, although volumetrically large, lack transport capacity and are consequently isolated from the modern Indus River drainage. Marginal plateau catchments that both efficiently produce and evacuate sediment may regulate the overall compositions and volumes of exported sediment from the Himalayan rain shadow.

show abstract

Recycling of Pleistocene valley fills dominates 135 ka of sediment flux, upper Indus River

Cited by 14 publications

References 62 publications

Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India

Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India

Millennial and centennial variations in zircon U‐Pb ages in the quaternary indus submarine canyon

Quantifying episodic erosion and transient storage on the western margin of the Tibetan Plateau, upper Indus River

Contact Info

Product

Resources

About