Abstract
Understanding the dynamics that drove past abrupt climate changes, such as the Dansgaard-Oeschger (DO) events, depends on combined proxy evidence from disparate archives. To identify leads, lags and synchronicity between different climate system components, independent and robust chronologies are required. Cryptotephrochronology is a key geochronological tool as cryptotephra horizons can act as isochrons linking disparate and/or distant records. Here, we investigated marine sediment core MD99-2284 from the Norwegian Sea to look for previously identified Greenland ice core cryptotephra horizons and define time-parallel markers between the archives. We explored potential secondary transport and depositional mechanisms that could hamper the isochronous integrity of such horizons. We identified six cryptotephra layers of which four correlate to previously known Greenland ice core horizons. None of those were identified in other marine cores and thus, this study contributes greatly to the North Atlantic tephra framework tripling the original amount of existing isochrons between ca. 25 and 60 ka b2k. The latter allow a synchronization between MD99-2284 and the Greenland ice cores between ca. 32–40 ka b2k, which is, in the North Atlantic, the shortest time-interval during the Last Glacial Period to be constrained by four independent tephra isochrons. These findings provide essential tephra-based evidence for synchronous and rapid oceanic and atmospheric temperature rises during the Greenland Stadial-Interstadial transitions. Furthermore, it enables us to estimate the average peak-duration of interstadial temperature overshoots at approximately 136 years. As such, this well-targeted high-resolution investigation successfully demonstrates the use of cryptotephra for geochronological purposes in the marine realm.
Highlights
IntroductionTephrochronology is considered to be a key correlation tool forS.M.P. Berben et al / Quaternary Science Reviews 236 (2020) 106277 past events (e.g. Lowe, 2011; Davies, 2015)
Tephrochronology is considered to be a key correlation tool forS.M.P
For each transition into an interstadial, we create new tuningpoints (TPin) by correlating the onset of the marine SST increase to the start of the ice core d18O increase (Fig. 9c; green crosses; Table 4). We acknowledge that these newly created TPin tuning-points for the Greenland Stadials (GS)-10/Greenland Interstadials (GI)-9, GS-9/GI-8, GS-8/GI-7 and GS-7/ GI-6 transitions are based on the assumption of a similar synchronous marine SST and ice core d18O increase, we argue that the isochrons provide enough evidence to justify this choice
Summary
Tephrochronology is considered to be a key correlation tool forS.M.P. Berben et al / Quaternary Science Reviews 236 (2020) 106277 past events (e.g. Lowe, 2011; Davies, 2015). Determining the phasing of events is crucial for understanding the dynamics controlling abrupt climate changes such as the Dansgaard-Oeschger (DO)-events. These events were recorded during the Last Glacial Period in the Greenland ice cores (Bond et al, 1993; Dansgaard et al, 1993) as well as in the North Atlantic marine realm To obtain a full picture of the fluctuations in, and/or interactions between, the atmosphere and ocean during these events and to fully comprehend the dynamics involved, it is crucial to combine and compare the disparate climate archives on independent age models An independent method to correlate these records and test the synchronous or nonsynchronous responses (leads/lags) to climatic fluctuations is required and can be provided by tephrochronology
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