Younger Dryas ice margin retreat triggered by ocean surface warming in central-eastern Baffin Bay

The transition from the last ice age to the present-day interglacial was interrupted by the Younger Dryas (YD) cold period. While many studies exist on this climate event, only few include high-resolution marine records that span the YD. In order to better understand the interactions between ocean,...

Full description

Bibliographic Details
Published in:Nature Communications
Main Authors: Oksman, Mimmi, Weckstrom, Kaarina, Miettinen, Arto, Juggins, Stephen, Divine, Dmitry V., Jackson, Rebecca, Telford, Richard, Korsgaard, Niels J., Kucera, Michal
Other Authors: Department of Geosciences and Geography, Environmental Sciences, Environmental Change Research Unit (ECRU)
Format: Article in Journal/Newspaper
Language:English
Published: Nature Publishing Group 2017
Subjects:
ABRUPT CLIMATE-CHANGE
LAST GLACIAL CYCLE
WEST GREENLAND
JAKOBSHAVN ISBRAE
FRESH-WATER
SOUTHEAST GREENLAND
HOLOCENE CLIMATE
OUTLET GLACIERS
NORTH-ATLANTIC
NORWEGIAN SEA
114 Physical sciences
1172 Environmental sciences
Arctic
Baffin Bay
Greenland
Norwegian Sea
Baffin
Climate change
Ice Sheet
Jakobshavn
North Atlantic
Online Access:http://hdl.handle.net/10138/228372
Description
Summary:The transition from the last ice age to the present-day interglacial was interrupted by the Younger Dryas (YD) cold period. While many studies exist on this climate event, only few include high-resolution marine records that span the YD. In order to better understand the interactions between ocean, atmosphere and ice sheet stability during the YD, more high-resolution proxy records from the Arctic, located proximal to ice sheet outlet glaciers, are required. Here we present the first diatom-based high-resolution quantitative reconstruction of sea surface conditions from central-eastern Baffin Bay, covering the period 14.0-10.2 kyr BP. Our record reveals warmer sea surface conditions and strong interactions between the ocean and the West Greenland ice margin during the YD. These warmer conditions were caused by increased Atlantic-sourced water inflow combined with amplified seasonality. Our results emphasize the importance of the ocean for ice sheet stability under the current changing climate. Peer reviewed

Similar Items