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Abstract:
The Cordilleran ice sheet, which covered the mountain ranges of north-western America during the last glacial
cycle, provides an ideal setting to study the effect of geothermal anomalies on subglacial water routing beneath
large-scale ice masses. First, the Cordilleran ice sheet rested directly on a geologically old yet still active subduction
zone, which is responsible for significant geothermal variability in the region. Second, the deep valleys and
intramontane basins that characterize the Cordilleran topography tend to act as flux wells to further enhance the
heterogeneity of this geothermal distribution. Third, compared to the currently ice covered areas such as Greenland
and Antarctica where direct observations of the geothermal distribution are exceedingly rare, the region of
the North American Cordillera offers insights into geothermal variability from numerous borehole measurements
taken across western territories of the US and Canada. Fourth and last, the subglacial water system left ample
evidence on the landscape, including vast esker systems, deep canyons and subglacial lake sediments, allowing for
an interpretation of the modeled hydrological networks and their comparison with geological data.
Here we use the Parallel Ice Sheet Model (PISM) to simulate ice dynamics and simplified subglacial hydrology of
the Cordilleran ice sheet through the last 120 000 years. We test several existing reconstructions of the geothermal
flux from direct and indirect observations versus a uniform distribution of heat flux to isolate the effects of regional
geothermal variability on thermo-hydrological conditions at the base of the last Cordilleran ice sheet. We find
that the uncertainties in the geothermal flux distribution as well as regional geothermal anomalies present in the
reconstructions have little effect on the modelled ice extent and thickness, but they affect the distribution of melt
rate and water routes beneath the ice sheet. All but one of the reconstructions used result in increased water content
in the Fraser Valley system due to high geothermal heat flux in upstream zones, showing the role of these regional
anomalies on the formation of subglacial lakes previously documented by geomorphology in this region.