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Schmidt-hammer exposure-age dating (SHD) was applied to a variety of boulder-dominated periglacial landforms in an attempt to establish a local mid-/late-Holocene chronology for the Geirangerfjellet in South Norway. Landform ages were obtained by application of a local calibration curve for Schmidt hammer R-values based on young and old control points comprising fresh road cuts and a bedrock surface in proximity to the study area, respectively. The area was deglaciated ~11.5 ka ago according to independent age information. Investigation of age, formation and stabilization of the periglacial landforms and processes involved allowed assessment of the underlying Holocene climate variability and its relationship to landform evolution. Our SHD ages range from 7.47 ± 0.73 ka for glacially abraded bedrock at the valley bottom to 2.22 ± 0.49 ka for surface boulders of a rock-slope failure. All landforms shared negative skewness and largely have narrow tailed frequency distributions of their R-values. This points to either substantial reworking of the boulders within a landform or continuous debris supply. Our results show that most landforms stabilized during the Holocene Thermal Maximum (~8.0–5.0 ka). The findings do not support the hypothesis that rock-slope failures predominately occur shortly after local deglaciation. Instead, it appears that they cluster during warm periods due to climate-driven factors, for example, decreasing permafrost depth or increasing cleft-water pressure leading to slope instabilities. Periglacial boulder-dominated landforms in the western maritime fjord region seem to react sensitively to Holocene climate variability and may constitute valuable but to date mostly unexplored sources of palaeoclimatic information.
Abstract. We present new 10Be surface exposure ages from two selected
locations in southern Norway. A total of five 10Be samples allow a first
assessment of local deglaciation dynamics of the Scandinavian Ice Sheet at
Dalsnibba (1476 m a.s.l.) in southwestern Norway. The bedrock ages from the
summit of Dalsnibba range from 13.3±0.6 to 12.7±0.5 ka
and probably indicate the onset of deglaciation as a glacially transported
boulder age (16.5±0.6 ka) from the same elevation likely shows
inheritance. These ages indicate initial deglaciation commencing at the end
of the Bølling–Allerød interstadial (∼ 14.7–12.9 kyr BP)
and ice-free conditions at Dalsnibba's summit during the Younger Dryas.
Bedrock samples at lower elevations imply vertical ice surface lowering down
to 1334 m a.s.l. at 10.3±0.5 ka and a longer overall period of
downwasting than previously assumed. Two further 10Be samples add to
the existing chronology at Blåhø (1617 m a.s.l.) in south-central Norway. The 10Be erratic boulder sample on the summit of Blåhø
sample yields 20.9±0.8 ka, whereas a 10Be age of 46.4±1.7 ka for exposed summit bedrock predates the Late Weichselian Maximum.
This anomalously old bedrock age infers inherited cosmogenic nuclide
concentrations and suggests low erosive cold-based ice cover during the Last Glacial Maximum.
However, due to possible effects of cryoturbation and frost heave processes
affecting the erratic boulder age and insufficient numbers of 10Be
samples, the glaciation history on Blåhø cannot conclusively be
resolved. Comparing the different timing of deglaciation at both locations
in a rather short west–east distance demonstrates the complex dynamics of
deglaciation in relation to other areas in southern Norway.
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