Abstract. Ground ice melt caused by climate-induced permafrost degradation may trigger
significant ecological change, damage infrastructure, and alter
biogeochemical cycles. The fundamental ground ice mapping for Canada is now
>20 years old and does not include significant new insights
gained from recent field- and remote-sensing-based studies. New modelling
incorporating paleogeography is presented in this paper to depict the
distribution of three ground ice types (relict ice, segregated ice, and wedge
ice) in northern Canada. The modelling uses an expert-system approach in a
geographic information system (GIS), founded in conceptual principles gained
from empirically based research, to predict ground ice abundance in
near-surface permafrost. Datasets of surficial geology, deglaciation,
paleovegetation, glacial lake and marine limits, and modern permafrost
distribution allow representations in the models of paleoclimatic shifts,
tree line migration, marine and glacial lake inundation, and terrestrial
emergence, and their effect on ground ice abundance. The model outputs are
generally consistent with field observations, indicating abundant relict ice
in the western Arctic, where it has remained preserved since deglaciation in
thick glacigenic sediments in continuous permafrost. Segregated ice is widely
distributed in fine-grained deposits, occurring in the highest abundance in
glacial lake and marine sediments. The modelled abundance of wedge ice
largely reflects the exposure time of terrain to low air temperatures in
tundra environments following deglaciation or marine/glacial lake inundation
and is thus highest in the western Arctic. Holocene environmental changes
result in reduced ice abundance where the tree line advanced during warmer
periods. Published observations of thaw slumps and massive ice exposures,
segregated ice and associated landforms, and ice wedges allow a favourable
preliminary assessment of the models, and the results are generally
comparable with the previous ground ice mapping for Canada. However, the
model outputs are more spatially explicit and better reflect observed ground
ice conditions in many regions. Synthetic modelling products that
incorporated the previous ground ice information may therefore include
inaccuracies. The presented modelling approach is a significant advance in
permafrost mapping, but additional field observations and volumetric ice
estimates from more areas in Canada are required to improve calibration and
validation of small-scale ground ice modelling. The ground ice maps from this
paper are available in the supplement in GeoTIFF format.
Ground Probing Radar Investigations of Massive Ground Ice and near Surface Geology in Continuous Permafrost