Impact of the Nares Strait sea ice arches on the long-term stability of the Petermann Glacier ice shelf
Permanent lenke
https://hdl.handle.net/10037/32444Dato
2023-12-12Type
Journal articleTidsskriftartikkel
Peer reviewed
Sammendrag
One of the last remaining floating tongues of
the Greenland ice sheet (GrIS), the Petermann Glacier ice
shelf (PGIS), is seasonally shielded from warm Atlantic water (AW) by the formation of sea ice arches in the Nares
Strait. However, continued decline of the Arctic sea ice extent and thickness suggests that arch formation is likely to
become anomalous, necessitating an investigation into the
response of PGIS to a year-round mobile and thin sea ice
cover. We use a high-resolution unstructured grid 3-D ocean–
sea ice–ice shelf setup, featuring an improved sub-ice-shelf
bathymetry and a realistic PGIS geometry, to investigate in
unprecedented detail the implications of transitions in the
Nares Strait sea ice regime, that is, from a thick and landfast
sea ice regime to a mobile, and further, a thin and mobile sea
ice regime, with regard to PGIS basal melt. In all three sea
ice regimes, basal melt near the grounding line (GL) presents
a seasonal increase during summer, driven by a higher thermal driving. The stronger melt overturning increases the friction velocity slightly downstream, where enhanced frictiondriven turbulent mixing further increases the thermal driving,
substantially increasing the local melt. As the sea ice cover
becomes mobile and thin, wind and (additionally in winter)
convectively upwelled AW from the Nares Strait enter the
PGIS cavity. While its effect on basal melting is largely limited to the shallower ( < 200 m) drafts during winter, in summer it extends to the GL (ca. 600 m) depth. In the absence
of an increase in thermal driving, increased melting under
the deeper (> 200 m) drafts in winter is solely driven by the
increased vertical shear of a more energetic boundary layer
current. A similar behaviour is noted when transitioning from
a mobile to a thin mobile sea ice cover in summer, when
increases in thermal driving are negligible and increases in
melt are congruent with increases in friction velocity. These
results suggest that the projected continuation of the warming of the Arctic Ocean until the end of the 21st century and
the accompanying decline in the Arctic sea ice extent and
thickness will amplify the basal melt of PGIS, impacting the
long-term stability of the Petermann Glacier and its contribution to the future GrIS mass loss and sea level rise.
Forlag
Copernicus PublicationsSitering
Prakash, Zhou, Hattermann, Kirchner. Impact of the Nares Strait sea ice arches on the long-term stability of the Petermann Glacier ice shelf. The Cryosphere. 2023;17(12):5255-5281Metadata
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