Mountain building and the initiation of the Greenland Ice Sheet

Anne Munck Solgaard, Johan Bonow, Peter Lang Langen, Peter Japsen, Christine Schøtt Hvidberg

18 Citations (Scopus)

Abstract

The effects of a new hypothesis about mountain building in Greenland on ice sheet initiation are investigated
using an ice sheet model in combination with a climate model. According to this hypothesis, low-relief landscapes
near sea level characterised Greenland in Miocene times until two phases of km-scale uplift in the late
Miocene and in the latest Miocene–Pliocene (beginning at 10 and ~5 Ma, respectively) initiated the formation
of the present-day mountains. The topography of Greenland, prior to these uplift events is reconstructed from
the present-day, isostatically compensated bedrock by mapping the two main steps in the landscape that
resulted from the two uplift phases. Ice sheet initiation is studied using the topography before uplift and after
each phase of uplift by applying different forcing conditions relevant for the late Cenozoic, which was
characterised by long-term cooling superimposed by cold and warm excursions. The modelling results show
that no ice initiates in the case of the low-lying and almost flat topography prior to the uplifts. However, the results
demonstrate a significant ice sheet growth in response to the orographically induced increase in precipitation
and the cooling of surface temperatures accompanying the uplift. Large amounts of ice are able to formafter
the first uplift event, but the ice sheet is sensitive to changes in climate. The results showthat the second phase of
uplift facilitates ice sheet build-up further and increases the stability of the ice sheet by providing anchoring
points which are not available to the same extent in the lower topographies. However, the results also reveal a
Föhn effect that inhibits ice sheet expansion into the interior Greenland and thus shifts the threshold of formation
of inland ice towards colder temperatures. Under conditions that are colder than the present, the ice can overcome
the Föhn effect, flow into the interior and form a coherent ice sheet. The results thus indicate that the
Greenland Ice Sheet of today is a relict formed under colder conditions. The modelling results are consistent
with the observed climatic variability superimposed on the general cooling trend in the late Cenozoic: e.g., ice
rafted debris in late Miocene deposits off southeast Greenland and the mid-PlioceneWarmth. The late Cenozoic
mountain building in Greenland augments the effects of the climatic deterioration leading to the Northern Hemisphere
glaciations, and without the second phase of uplift, the Greenland Ice Sheet would have been more sensitive
to the changes in climate over the past millions of years.
Original languageEnglish
JournalPalaeogeography, Palaeoclimatology, Palaeoecology - An International Journal for the Geo-Sciences
Volume392
Pages (from-to)161-176
ISSN0031-0182
Publication statusPublished - 15 Dec 2013

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