2010
DOI: 10.1016/j.quascirev.2010.06.005
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Spatial and temporal Arctic Ocean depositional regimes: a key to the evolution of ice drift and current patterns

Abstract: a b s t r a c tSediment physical properties measured in cores from all the major ridges and plateaus in the central Arctic Ocean were studied in order to analyze the spatial and temporal consistency of sediment depositional regimes during the Quaternary. In total, six physiographically distinct areas are outlined. In five of these, cores can be correlated over large distances through characteristic patterns in sediment physical properties. These areas are (1) the southern Mendeleev Ridge, (2) the northern Mend… Show more

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Cited by 40 publications
(24 citation statements)
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“…Clark, 1970) to the Brunhes/Matuyama boundary, which has a present inferred age of 780 ka (Lourens et al, 2004). Sellén et al (2010) point to the recent study of Channell and Xuan (2009), which shows that inclinations in Arctic Ocean cores may, in fact, not at all be related to the "real" established and dated paleomagnetic reversals and/or shorter duration magnetic excursions. Instead paleoceanographic conditions on a basin-wide scale in combination with relatively low sedimentation rates may have generated near bottom environments where oxidation processes caused titano-magnetities to transform into titano-maghematites and, during this diagenetic change, acquire a chemical remnant magnetization that is partially self reversed ).…”
Section: Arctic Ocean Sediment Stratigraphymentioning
confidence: 55%
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“…Clark, 1970) to the Brunhes/Matuyama boundary, which has a present inferred age of 780 ka (Lourens et al, 2004). Sellén et al (2010) point to the recent study of Channell and Xuan (2009), which shows that inclinations in Arctic Ocean cores may, in fact, not at all be related to the "real" established and dated paleomagnetic reversals and/or shorter duration magnetic excursions. Instead paleoceanographic conditions on a basin-wide scale in combination with relatively low sedimentation rates may have generated near bottom environments where oxidation processes caused titano-magnetities to transform into titano-maghematites and, during this diagenetic change, acquire a chemical remnant magnetization that is partially self reversed ).…”
Section: Arctic Ocean Sediment Stratigraphymentioning
confidence: 55%
“…Perhaps the most conspicuous of these markers is the first encountered prominent paleomagnetic inclination change, which occurs in the stratigraphy in all cores, from the southern part of the Mendeleev Ridge, across the Arctic Ocean and the Lomonosov Ridge to the Morris Jesup Rise. This inclination change occurs towards the end of MIS 7 according to the established chronostratigraphy by Sellén et al (2010), but was ascribed earlier (e.g. Clark, 1970) to the Brunhes/Matuyama boundary, which has a present inferred age of 780 ka (Lourens et al, 2004).…”
Section: Arctic Ocean Sediment Stratigraphymentioning
confidence: 85%
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