Arctic margin gravity highs: Deeper meaning for sediment depocenters?

Morphologic, gravity, and seismic reflection/refraction data from ca. 10,000 km of Arctic passive continental margins suggest that the numerous oval free-air gravity anomalies, their +50-150 mGal extrema typically located just landward of shelf breaks, are caused by combinations of rapidly deposited...

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Bibliographic Details
Published in:Marine geophysical researches 1998-10, Vol.20 (5), p.459-477
Main Authors: Vogt, Peter R, Jung, Woo-yeol, Brozena, John
Format: Article
Language:English
Subjects:
Basalt
Continental margins
Geology
Marine
Marine sediments
Oceanic crust
Pleistocene
Sediments
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Summary:Morphologic, gravity, and seismic reflection/refraction data from ca. 10,000 km of Arctic passive continental margins suggest that the numerous oval free-air gravity anomalies, their +50-150 mGal extrema typically located just landward of shelf breaks, are caused by combinations of rapidly deposited Plio-Pleistocene glacial marine sediment loads, older post-breakup sediments, and perhaps causally related density anomalies (mascons) in the underlying oceanic crust. Dispersed seismicity associated with some gravity highs may reflect ongoing brittle, flexural adjustment to the loads. Multi-channel-seismic-controlled depocenter models for several prominent highs (including the Hornsund gravity high re-examined here) suggest that sediments alone do not suffice to explain the gravity highs, unless depocenter seismic velocities have been significantly underestimated. A flexural backstripping model for the Hornsund anomaly only roughly replicates observed gravity. Subjacent 'mascons', if present below some depocenters, may be caused by (1) anomalous subsidence of initially formed dense/thin crust; (2) depocenter blanketing of early-formed crust, mitigating hydrothermal fracturing and related density reduction; or (3) metastable phase transitions, converting basalt/gabbro to denser phases (Neugebauer-Spohn hypothesis), while cracks close or fill under the increased pressures and temperatures.[PUBLICATION ABSTRACT]
ISSN:0025-3235
1573-0581
DOI:10.1023/A:1004775228851