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Tributary glacier surges: an exceptional concentration at Panmah Glacier, Karakoram Himalaya

Published online by Cambridge University Press:  10 October 2017

Kenneth Hewitt*
Affiliation:
Cold Regions Research Centre, Wilfrid Laurier University, 100 University Avenue, Waterloo, Ontario N2L 3C5, Canada E-mail: khewitt@wlu.ca
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Abstract

Four tributaries of Panmah Glacier have surged in less than a decade, three in quick succession between 2001 and 2005. Since 1985, 13 surges have been recorded in the Karakoram Himalaya, more than in any comparable period since the 1850s. Ten were tributary surges. In these ten a full run-out of surge ice is prevented, but extended post-surge episodes affect the tributary and main glacier. The sudden concentration of events at Panmah Glacier is without precedent and at odds with known surge intervals for the glaciers. Interpretations must consider the response of thermally complex glaciers, at exceptionally high altitudes and of high relief, to changes in a distinctive regional climate. It is suggested that high-altitude warming affecting snow and glacier thermal regimes, or bringing intense, short-term melting episodes, may be more significant than mass-balance change.

Information

Type
Research Article
Copyright
Copyright © International Glaciological Society 2007
Figure 0

Fig. 1. Map of Panmah Glacier showing four recent surges. The heads of ice streams are shown schematically to reflect how most of the basin above 5000 m consists of rock walls, seasonally or perennially snow-covered, subject to all-season avalanching, and with countless small, steep ice masses that contribute to the trunk streams through ice avalanches.

Figure 1

Table 1. Surging tributaries: dimensions of Panmah and other glaciers with tributaries that recently surged in the central Karakoram

Figure 2

Fig. 2. Overview of Maedan (M) surge in July 2005 where it enters the Chiring (C) and Nobande Sobande (NS). The lobe Chiring (C) surge ice is also seen and the conspicuous pressure ridge at its rim. The outer part of the Shingchukpi (S) surge is visible in the middle distance.

Figure 3

Fig. 3. Shingchukpi Glacier surge, July 2005. The surface consists almost wholly of seracs, and dirty ice is thrust up irregularly at margins. View is from Nobande Sobande ice in foreground.

Figure 4

Fig. 4. Ice ridge on Nobande Sobande Glacier, 100 m from contact with the Shingchukpi Glacier surge ice (to left of photograph). Cupola-like bridges are shown and ice breccia beneath.

Figure 5

Fig. 5. Drenmang in July 2005, looking up the left-flank surging tributary from Nobande Sobande. Arrows identify surge-generated disturbances.

Figure 6

Fig. 6. Panmah Glacier surface changes associated with surges: (a) 1993, prior to Chiring surge; ice of 1977–8 Drenmang surge was just passing the mouth of Chiring indicating an average annual movement of about 500 m; (b) 1996, conditions following the 1994–5 Chiring surge; (c) 2005, showing complex interactions of older Drenmang and Chiring surges with ongoing Maedan and Shingchukpi events. The new Drenmang surge has barely affected the main glacier.

Figure 7

Fig. 7. Stagnant surge ice (arrows) along the post-surge Chiring margins, 1996. The heavily crevassed active ice (A) is 30 m below surge height but 50 m thicker than in 2005 when several other bands of dead ice were present below that shown here (cf. Fig. 2 and Hewitt, 1998).

Figure 8

Fig. 8. Area–altitude relations of glacier environments in the central Karakoram identify regime factors that could affect surging or climatic influences on it. The air temperatures shown differ from accumulation zone snow and ice. In open, avalanche-free areas at 5000–6000 m a.s.l., firn temperatures at depth in pits and cores were at least 5°C warmer (Wake, 1989).