Abstract
ABSTRACTA suite of surface and basal measurements during and after borehole drilling is used to perform in situ investigation of the local basal drainage system and pressure forcing in western Greenland. Drill and borehole water temperature were monitored during borehole drilling, which was performed with dyed hot water. After drilling, borehole water pressure and basal dye concentration were measured concurrently with positions in a GPS strain diamond at the surface. Water pressure exhibited diurnal changes in antiphase with velocity. Dye monitoring in the borehole revealed stagnant basal water for nearly 2 weeks. The interpretation of initial connection to an isolated basal cavity is corroborated by the thermal signature of borehole water during hot water drilling. Measurement-based estimates of cavity size are on the order of cubic meters, and analysis indicates that small changes in its volume could induce the observed pressure variations. It is found that longitudinal coupling effects are unable to force necessary volume changes at the site. Sliding-driven basal cavity opening and elastic uplift from load transfer are plausible mechanisms controlling pressure variations. Elastic uplift requires forcing from a hydraulically connected reach, which observations suggest must be relatively small and in close proximity to the isolated cavity.
Highlights
Basal processes can force large changes in ice motion over short timescales
Borehole water temperature and in situ dye tracing at the bed via borehole injection indicates connection to an isolated basal cavity, which we estimate to be on the order of cubic meters in size
Measurements of basal water pressure in the isolated cavity show diurnal swings, which are out of phase with surface velocity recorded by a GPS strain diamond encompassing the borehole measurement
Summary
On the Greenland ice sheet (GrIS), observations have established a link between surface melt input and dynamical ice motion over daily to seasonal periods (Zwally and others, 2002; Bartholomew and others, 2010; Hoffman and others, 2011). This forcing on velocity by surface input is attributed to the subglacial drainage system, which modulates sliding by adjusting the balance of forces at the bed through changes in drainage system pressure distribution and water coverage. It has been hypothesized that the seasonal slowdown in Greenland during the melt season is the result of the incorporation of isolated basal cavities by more interconnected reaches of the ice-sheet drainage network (Andrews and others, 2014)
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