Mean element and biogenic silica concentrations in Arctic Ocean sediments (Table 1)

Quantitative determination of biogenic silica in Late Cretaceous and Paleogene deep-sea sediment cores from the central Arctic Ocean provides evidence of open-ocean polar upwelling. The timing of polar upwelling coincides with periods of a weakened meridional thermal gradient, suggesting that heat t...

Full description

Bibliographic Details
Main Authors: Kitchell, Jennifer A, Clark, David L
Format: Dataset
Language:English
Published: PANGAEA 1982
Subjects:
54-422
56-437
Aluminium
Atomic absorption spectrometry (AAS)
Calculated
Deep Sea Drilling Project
Depth
bottom/max
sediment/rock
top/min
DRILL
Drilling/drill rig
DSDP
Elevation of event
Event label
Glomar Challenger
Latitude of event
Leg54
Leg56
Longitude of event
Magnesium
North Pacific
North Pacific/RIDGE
Opal
biogenic silica
Silicon
Silicon dioxide
Alpha Ridge
Arctic
Arctic Ocean
Bering Sea
Faroe-Iceland Ridge
Greenland
Pacific
Svalbard
alpha ridge
Greenland Sea
Iceland
North Atlantic
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.701639
https://doi.org/10.1594/PANGAEA.701639
Description
Summary:Quantitative determination of biogenic silica in Late Cretaceous and Paleogene deep-sea sediment cores from the central Arctic Ocean provides evidence of open-ocean polar upwelling. The timing of polar upwelling coincides with periods of a weakened meridional thermal gradient, suggesting that heat transport to the poles by oceanic circulation may have been important. The timing of biogenic silica deposition in the Arctic precedes its deposition in both the Norwegian-Greenland Sea of the North Atlantic and the Bering Sea of the North Pacific. Tectonic events may be responsible for the timing and siting of sites of deposition of biogenic silica in high northern latitudes, particularly the tectonic evolution of sites of deep-water exchange between the Arctic and the world ocean. We outline three phases in the post-mid-Cretaceous history of silica deposition in high northern latitudes. During Phase I, the Arctic is a silica sink, with deep-water formation but with no deep-water outflow. The transition to Phase II is brought about by opening of the Svalbard-Greenland Strait to deep-water outflow from the Arctic to the Norwegian-Greenland Sea. The transition to Phase III is initiated by submergence of the Faroe-Iceland Ridge and deep-water outflow from the Arctic to the North Atlantic. Climatic conditions in the Arctic during Late Cretaceous and Paleogene time are predicted to have favored open-ocean upwelling due to a circulation pattern dominated by cyclonic conditions, resulting from the establishment of a semi-permanent atmospheric low over the Alpha Ridge. Bathymetry of the Alpha Ridge may have intensified paleo-upwelling.

Similar Items