Abstract
ABSTRACTThe subglacial observatory beneath the Argentière glacier provides a rare opportunity to study the interactions between glacier sliding velocity and subglacial runoff. The sliding velocity has been monitored in this cavity almost continuously since 1997 and the resulting data indicate a decrease in annual sliding velocities over the last two decades. We found close relationships between annual surface velocity, sliding velocity and ice thickness. These relationships indicate that the ice-flow velocity changes do not depend on subglacial water runoff changes at the annual timescale. The seasonal magnitudes of sliding also show a decrease over the last two decades. At the seasonal timescale, sliding velocity increases before or simultaneously with the large runoff increase in May, indicating a distributed drainage system. Conversely, at the end of the melt season, sliding velocity continues to decrease after the runoff returns to low winter values. The simultaneous increases of runoff and sliding velocity occur mainly before the spring transition. Later, sliding velocity generally appears not to be related to water inputs coming from the surface, except for some large accelerations after midAugust that are always associated with periods of rapidly increasing water inputs to the subglacial drainage system.
Highlights
Basal motion is a crucial component of the dynamic behavior of glaciers but is still a poorly understood aspect of glacier physics (e.g. Clarke, 1996; Fountain and Walder, 1998; Cuffey and Paterson, 2010)
Our results suggest that annual velocity variations are driven by thickness changes
Our present study shows that the thickness and ice-flow velocity changes measured at cross section No 4 are very similar to cumulative mass balance changes
Summary
Basal motion is a crucial component of the dynamic behavior of glaciers but is still a poorly understood aspect of glacier physics (e.g. Clarke, 1996; Fountain and Walder, 1998; Cuffey and Paterson, 2010). Increased water pressures reduce the frictional drag and increase the sliding rate. In this way effective pressure, which is the difference between water pressure and pressure in the surrounding ice, decreases. Low effective pressures allow the formation of large cavities, which reduce the area of contact between the ice and bed (Lliboutry, 1968). The study of Harper and others (2007) revealed two separate modes of accelerated sliding during the annual spring increase of meltwater flux to the bed. Basal sliding influences hydrology (Hoffman and Price, 2014) Such feedbacks remain poorly understood they play a crucial role in seasonal variations of glacier flow (Cuffey and Paterson, 2010). Beneath glaciers with abundant summertime surface melt, water pressures and fluxes vary greatly in daily cycles and over seasons (e.g. Bartholomaus and others, 2008; Werder and others, 2013)
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