Serripes groenlandicus

Abstract: Nioghalvfjerdsfjorden in North-East Greenland is at present covered by a floating glacier. Raised marine deposits in the surrounding area contain shells of marine molluscs, bones of marine mammals and pieces of driftwood. A fairly systematic sampling of such material has been conducted, followed by extensive radiocarbon dating. We suggest that the Greenland ice sheet extended onto the shelf offshore North-East Greenland during isotope stage 2, perhaps even reaching the shelf break. During the subsequent recession of the ice sheet, the entrance of Nioghalvfjerdsfjorden had become ice-free by 9.7 cal. ka BP. The recession culminated between 7.7 and 4.5 cal. ka BP, during which time the fjord was glacier-free along its entire 80 km length. No dates younger than 4.5 cal. ka BP are available on marine material from the fjord, and it seems probable that the fjord has been continuously covered by the floating glacier since this time. The maximum glaciation was attained around AD 1900, after which thinning and recession took place. The marine limit increases from c. 40 m above sea level near the present margin of the Inland Ice to c. 65 m above sea level at the outer coast. These figures fit into the regional pattern of the marine limit for areas both to the south and north. The marine fauna comprise two bivalves, Macoma calcarea and Serripes groenlandicus, that may represent a southern element present during the Holocene temperature optimum. Remains of three taxa of southern extralimital terrestrial and limnic plants were dated to 5.1 cal. ka BP, and remains of another extralimital plant were dated to 8.8 and 8.5 cal. ka BP. The known Holocene time ranges of the willow Salix arctica and the lemming Dicrostonyx torquatus have been extended back to 8.8 and 6.4 cal. ka BP, respectively, providing minimum dates for their immigration to Greenland.

Abstract: [1] Oxygen and carbon isotope profiles of bivalve mollusks (Serripes groenlandicus and Macoma calcarea) record distinct changes of water mass properties in the Bering Strait region associated with the seasonal discharge of estuarine freshwater from Kolyuchin Bay into the western Chukchi Sea. Cycles in the δ18O profiles are correlated with shell growth bands and interpreted as annual; maximum δ18O values corresponding to coldest water temperatures coincide with dark internal bands in the shell that mark slower growth during winter. A 0.5 ‰ offset between the baseline winter δ18O values of two specimens (HX68 and HX65), at different distances from the estuarine discharge, is attributed to a difference in seawater δ18O between the two sites and indicates that the influence of the estuarine water persists through much of the year. The isotope profiles of specimen AK55, collected north of Bering Strait in the Chukchi Sea, reflect the Bering Shelf-Anadyr Water flowing from south of Bering Strait. Comparison of the δ13C profiles shows that HX68, collected closer to Kolyuchin Bay, has high-amplitude negative δ13C excursions associated with incorporation of dissolved inorganic carbon that is isotopically depleted in 13C, probably from terrestrial runoff. The significant positive correlation between δ18O and δ13C values in these specimens suggests that the properties of the ambient water masses are reflected in the stable isotope profiles. These results show that the stable isotope profiles of mollusk shells can serve as proxy indicators of water mass properties, particularly during runoff events in Arctic coastal regions that are logistically difficult to sample directly.