Erik Thomsen scite author profile

Two cores from the southwestern shelf and slope of Storfjorden, Svalbard, taken at 389 m and 1485 m water depth have been analyzed for benthic and planktic foraminifera, oxygen isotopes, and ice-rafted debris. The results show that over the last 20,000 yr, Atlantic water has been continuously present on the southwestern Svalbard shelf. However, from 15,000 to 10,000 14C yr BP, comprising the Heinrich event H1 interval, the Bølling–Allerød interstades and the Younger Dryas stade, it flowed as a subsurface water mass below a layer of polar surface water. In the benthic environment, the shift to interglacial conditions occurred at 10,000 14C yr BP. Due to the presence of a thin upper layer of polar water, surface conditions remained cold until ca. 9000 14C yr BP, when the warm Atlantic water finally appeared at the surface. Neither extensive sea ice cover nor large inputs of meltwater stopped the inflow of Atlantic water. Its warm core was merely submerged below the cold polar surface water.

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The role of the North Atlantic Drift in the millennial timescale glacial climate fluctuations

Rasmussen¹,

Thomsen

2004

Palaeogeography, Palaeoclimatology, Palaeoecology

182

207

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The evolution of western Scandinavian topography: A review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis

Nielsen

Gallagher

Leighton

et al. 2009

Journal of Geodynamics

179

233

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a b s t r a c tTectonics and erosion are the driving forces in the evolution of mountain belts, but the identification of their relative contributions remains a fundamental scientific problem in relation to the understanding of both geodynamic processes and surface processes. The issue is further complicated through the roles of climate and climatic change. For more than a century it has been thought that the present high topography of western Scandinavia was created by some form of active tectonic uplift during the Cenozoic. This has been based mainly on the occurrence of surface remnants and accordant summits at high elevation believed to have been graded to sea level, the inference of increasing erosion rates toward the present-day based on the age of offshore erosion products and the erosion histories inferred from apatite fission track data, and on over-burial and seaward tilting of coast-proximal sediments.In contrast to this received wisdom, we demonstrate here that the evidence can be substantially explained by a model of protracted exhumation of topography since the Caledonide Orogeny. Exhumation occurred by gravitational collapse, continental rifting and erosion. Initially, tectonic exhumation dominated, although erosion rates were high. The subsequent demise of onshore tectonic activity allowed slow erosion to become the dominating exhumation agent. The elevation limiting and landscape shaping activities of wet-based alpine glaciers, cirques and periglacial processes gained importance with the greenhouse-icehouse climatic deterioration at the Eocene-Oligocene boundary and erosion rates increased. The flattish surfaces that these processes can produce suggest an alternative to the traditional tectonic interpretation of these landscape elements in western Scandinavia. The longevity of western Scandinavian topography is due to the failure of rifting processes in destroying the topography entirely, and to the buoyant upward feeding of replacement crustal material commensurate with exhumation unloading.We emphasize the importance of differentiating the morphological, sedimentological and structural signatures of recent active tectonics from the effects of long-term exhumation and isostatic rebound in understanding the evolution of similar elevated regions.

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Rapid changes in surface and deep water conditions at the Faeroe Margin during the last 58,000 years

Rasmussen¹,

Thomsen²,

Weering³

et al. 1996

Paleoceanography

194

151

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A high‐resolution piston core, ENAM93‐21, from a water depth of 1020 m near the Faeroe‐Shetland Channel is investigated for variations in magnetic susceptibility, surface oxygen isotopes, grain size distribution, content of ice‐rafted detritus (IRD), and distribution of planktonic and benthic foraminifera. The core, covering the last 58,000 years, is correlated with the Greenland ice cores and compared with paleorecords from the Norwegian Sea and the North Atlantic Ocean. All fifteen Dansgaard‐Oeschger climatic cycles recognized from the investigated time period in the Greenland ice cores have been identified in the ENAM93‐21 core. Each cycle is subdivided into three intervals on the basis of characteristic benthic and planktonic faunas. Interstadial intervals contain a relatively warm planktonic fauna and a benthic fauna similar to the modern fauna in the Norwegian Sea. This indicates thermohaline convection as at present, with a significant contribution of deep water to the North Atlantic Deep Water (NADW). Transitional cooling intervals are characterized by more cold water planktonic foraminfera and ice‐related benthic species. The benthic fauna signifies restricted bottom water conditions and a reduced contribution to the NADW. The peak abundance of N. pachyderma (s.) and the coldest surface water conditions are found in the stadial intervals. The benthic fauna is dominated by species with an association to Atlantic Intermediate Water, suggesting an increased Atlantic influence in the Norwegian Sea, and there was probably no contribution to the NADW through the Faeroe‐Shetland Channel. The three different modes of circulation can be correlated to paleoceanographic events in the Norwegian Sea and the North Atlantic Ocean.

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Circulation changes in the Faeroe-Shetland Channel correlating with cold events during the last glacial period (58–10 ka)

Rasmussen

Thomsen

Labeyrie

et al. 1996

Geol

127

140

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Erik Thomsen

Paleoceanographic evolution of the SW Svalbard margin (76°N) since 20,000 ¹⁴C yr BP

The role of the North Atlantic Drift in the millennial timescale glacial climate fluctuations

The evolution of western Scandinavian topography: A review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis

Rapid changes in surface and deep water conditions at the Faeroe Margin during the last 58,000 years

Circulation changes in the Faeroe-Shetland Channel correlating with cold events during the last glacial period (58–10 ka)

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Erik Thomsen

Paleoceanographic evolution of the SW Svalbard margin (76°N) since 20,000 14C yr BP

The role of the North Atlantic Drift in the millennial timescale glacial climate fluctuations

The evolution of western Scandinavian topography: A review of Neogene uplift versus the ICE (isostasy–climate–erosion) hypothesis

Rapid changes in surface and deep water conditions at the Faeroe Margin during the last 58,000 years

Circulation changes in the Faeroe-Shetland Channel correlating with cold events during the last glacial period (58–10 ka)

Contact Info

Product

Resources

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Paleoceanographic evolution of the SW Svalbard margin (76°N) since 20,000 ¹⁴C yr BP