Abstract
The Arctic's glacial history has classically been interpreted from marine records in terms of the fluctuations of the Eurasian and North American ice sheets. However, the existence, size, and timing of the East Siberian Ice Sheet (ESIS) remains highly uncertain. A recently discovered glacially scoured cross-shelf trough extending to the edge of the continental shelf north of the De Long Islands has provided additional evidence that glacial ice existed on parts of the East Siberian Sea (ESS) during previous glacial periods (MIS 6 and 4). This study concentrates on defining the mineralogical signature and dynamics of the ESIS. Sediment materials from the East Siberian shelf and slope were collected during the 2014 SWERUS-C3 expedition. The cores studied are 20-GC1 from the East Siberian shelf, 23-GC1 and 24-GC1 from the De Long Trough (DLT), and 29-GC1 from the southern Lomonosov Ridge (LR). Heavy mineral assemblages were used to identify prominent parent rocks in hinterland and other sediment source areas. The parent rocks areas include major eastern Siberian geological provinces such as the Omolon massif, the Chukotka Fold Belt, the Verkhoyansk Fold Belt, and possibly the Okhotsk–Chukotka Volcanic Belt. The primary riverine sources for the ESS sediments are the Indigirka and Kolyma rivers, which material then was glacially eroded and re-deposited in the DLT. The higher abundances of hornblendes in the heavy mineral assemblages may indicate ESS paleovalley of the Indigirka river as a major pathway of sediments, while the Kolyma river paleovalley pathway relates to a higher share of pyroxenes and epidote. Mineralogical signature in the DLT diamicts, consisting predominantly of amphiboles and pyroxenes with minor content of garnet and epidote, show clear delivery from the eastern sector of the ESIS. Although the physical properties of the DLT basal diamict closely resemble a pervasive diamict unit recovered across the southern LR, their source material is slightly different according to their heavy mineral content. Assemblages with elevated amphibole and garnet content, along with higher titanite and ilmenite content from core 29-GC1 from the southern LR emphasise the Verkhoyansk Fold Belt as a possible source. This suggests that glacial ice not only grew out from the East Siberian shelf, but also from the New Siberian Islands and westerly sources due to the dynamics in the ice flow and deposition. An increase in the iron oxides in the sediments overlying the diamicts relates to the deglaciation cycle of the ESIS when the central plateau, or at least the shoreline and river discharge region, were possibly free from ice, and the reworking as well as enrichment of iron oxides was possible. This indicates sea-ice rather than iceberg transport for the present distal shelf sediments.
Highlights
The existence, timing and extent of ice sheets during the Pleistocene glaciations on the Siberian continental shelf of the East 40 Siberian Sea is still largely undetermined
Regardless of the lack of characteristic glacial features, previous studies have suggested the existence of ice sheets over parts of the East Siberian continental shelf during the larger Pleistocene glaciations following the mid-Pleistocene transition (Colleoni et al, 2016; Niessen et al, 2013), the Saalian (Marine Isotope Stage 6) (Jakobsson et al, 2016)
Parent rocks determine the basics for heavy mineral assemblages, and since sedimentary processes are governed by glacial ice dynamics, it can be assumed that changes in mineralogy reflect changes in sediment sources and ice streaming before final deposition and burial
Summary
The existence, timing and extent of ice sheets during the Pleistocene glaciations on the Siberian continental shelf of the East 40 Siberian Sea is still largely undetermined. The sparse geophysical and marine geological data obtained from this area are highly important in defining the glacial history of the region and its relationship to the wider Eurasian Arctic glaciations. 30 This study concentrates on defining the mineralogical signature and distribution of the ESIS from marine sediments from the East Siberian shelf and slope, especially from a glacial trough and related trough mouth fan setting. The mineralogical components and mineral-geochemical characteristics of these samples provide interpretative data for reconstruction of potential source areas and pathways for glacially entrained sediments. Provenance information can be derived from individual sand-size heavy mineral grains or populations of grains and identification of mineral assemblages indicating certain metamorphic and igneous source terranes provide a key provenance information
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