Holocene multidecadal‐ to millennial‐scale variations in Iceland‐Scotland overflow and their relationship to climate

Mjell, Tor Lien; Ninnemann, Ulysses S; Eldevik, Tor; Kleiven, H. F.

doi:10.1002/2014pa002737

Cited by 34 publications

(39 citation statements)

References 66 publications

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“…Using the prominent AMOC perturbations characterizing the Younger Dryas (YD) and Heinrich Stadial 1 (HS1) as test cases, our model faithfully reproduces the amplitude of both (Andersen et al, 2004). (b) Sortable silt records of ISOW strength from (right axis) Core GS06-144 08GC (Mjell et al, 2015) and an (left axis) Iceland slope stack (Thornalley et al, 2013). (c) Relative abundance of the polar foraminifer N. pachyderma from the Core MD99-2251 (Ellison et al, 2006).…”

Section: Discussionmentioning

confidence: 99%

Constraining the Variability of the Atlantic Meridional Overturning Circulation During the Holocene

Lippold

Pöppelmeier

Süfke

et al. 2019

Geophysical Research Letters

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There is a converging body of evidence supporting a measurable slowdown of the Atlantic Meridional Overturning Circulation (AMOC) as climate warms and Northern Hemisphere ice sheets inexorably shrink. Within this context, we assess the variability of the AMOC during the Holocene based on a marine sediment core retrieved from the deep northwest Atlantic, which sensitively recorded large-scale deglacial transitions in deep water circulation. While there is a diffuse notion of Holocene variability in Labrador and Nordic Seas overturning, we report a largely invariable deep water circulation for the last 11,000 years, even during the meltwater pulse associated with the 8.2-ka event. Sensitivity tests along with high-resolution 231 Pa/ 230 Th data constrain the duration and the magnitude of possible Holocene AMOC variations. The generally constant baseline during the Holocene suggests attenuated natural variability of the large-scale AMOC on submillennial timescales and calls for compensating effects involving the upstream components of North Atlantic Deep Water.

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Section: Discussionmentioning

confidence: 99%

Constraining the Variability of the Atlantic Meridional Overturning Circulation During the Holocene

Lippold

Pöppelmeier

Süfke

et al. 2019

Geophysical Research Letters

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“…Several bottom flow speed reconstructions (Table ) exist across the pathway of the deep overflow waters that cross the Iceland‐Scotland Ridge. The subdecadal sortable silt records closer to the sill (2,300–2,080‐m depth) reveal broad similarities on multicentennial scales with an increase in flow speed from 0 years CE until 600–800 CE followed by a gradual decline of ISOW flow vigor toward the modern (Mjell et al, ; Moffa‐Sanchez et al, ; Mjell et al, ; Figures a and b). Farther downstream, and at similar depths, the SSrecords also coincide with the slow ISOW between 0 and 600 CE but the rest of the records diverge from the upstream records by showing a steady increase toward the present with several step changes including an increase in the flow at ~1400 CE (Moffa‐Sánchez & Hall, ; Figure c).…”

Section: North Atlantic Variability Over the Last 2000 Years: A Proxmentioning

confidence: 99%

“…Bathymetric base map is made using Ocean Data View (ODV; (Schlitzer, ). The graph is ordered from the ISOW from north to south including (a) RAPiD‐17‐5P, which is south of Iceland and close to the Greenland‐Scotland Ridge (Moffa‐Sanchez et al, ; note that the SS from the DSOW, also shown in (e) has been plotted in blue in reverse to show the antiphasing); (b) GS06‐144‐09MC (dark red; (Mjell et al, ) and GS06‐144‐08GC (red; Mjell et al, ; note the discrepancy when splicing); (c) Southern Gardar drift SS from RAPiD‐21‐3K (Moffa‐Sánchez & Hall, ) and magnetic susceptibility from MD99‐2251 (Kissel et al, ); (d) magnetic susceptibility from the deep Charles Gibbs Fracture Zone (CGFZ) CH77‐02 and DD08‐3182C1 (Kissel et al, ); (e) SS record from the from RAPiD‐35‐COM in the Eirik Drift off the southern tip of Greenland in the path of the DSOW (Moffa‐Sanchez et al, ); and (e) sortable silt record from KNR‐178‐48JPC/56JPC in the pathway of lower LSW/upper DWBC (uDWBC; Thornalley et al, ). The record in grey denotes three‐point smoothed benthic foraminiferal Mg/Ca temperatures at 1,845 m on the Scotian Shelf interpreted as deep LSW (Marchitto & de Menocal, ; note that the data from the top 23.5 cm of this record were plotted on the updated age model for KNR‐158‐10MC from Thornalley et al, ).…”

Section: North Atlantic Variability Over the Last 2000 Years: A Proxmentioning

confidence: 99%

Variability in the Northern North Atlantic and Arctic Oceans Across the Last Two Millennia: A Review

Moffa-Sánchez

Moreno-Chamarro

Reynolds

et al. 2019

Paleoceanog and Paleoclimatol

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The climate of the last two millennia was characterized by decadal to multicentennial variations, which were recorded in terrestrial records and had important societal impacts. The cause of these climatic events is still under debate, but changes in the North Atlantic circulation have often been proposed to play an important role. In this review we compile available high‐resolution paleoceanographic data sets from the northern North Atlantic and Nordic Seas. The records are grouped into regions related to modern ocean conditions, and their variability is discussed. We additionally discuss our current knowledge from modeling studies, with a specific focus on the dynamical changes that are not well inferred from the proxy records. An illustration is provided through the analysis of two climate model ensembles and an individual simulation of the last millennium. This review thereby provides an up‐to‐date paleoperspective on the North Atlantic multidecadal to multicentennial ocean variability across the last two millennia.

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“…However, the intense volcanic activity of the 19th century (1809, 1815 and around 1840; Sigl et al, 2015) may also explain the apparent early warming trend, suggesting that it may have been recovery from an exceptionally cool phase. On the scale of the Holocene, internal fluctuations occurring on a millennial scale have been identified in the subarctic North Atlantic area and were tentatively related to ocean dynamics (Debret et al, 2007;Mjell et al, 2015). Therefore, to better understand the cooling trend of the last 2 millennia in a larger temporal context, taking into account the role of oceanic variability in the long-term temperature variations, a longer time series encompassing the entire Holocene would be useful.…”

Section: Long-term Tendenciesmentioning

confidence: 99%

Climate variability in the subarctic area for the last 2 millennia

et al. 2018

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Abstract.To put recent climate change in perspective, it is necessary to extend the instrumental climate records with proxy data from paleoclimate archives. Arctic climate variability for the last 2 millennia has been investigated using statistical and signal analyses from three regionally averaged records from the North Atlantic, Siberia and Alaska based on many types of proxy data archived in the Arctic 2k database v1.1.1. In the North Atlantic and Alaska, the major climatic trend is characterized by long-term cooling interrupted by recent warming that started at the beginning of the 19th century. This cooling is visible in the Siberian region at two sites, warming at the others. The cooling of the Little Ice Age (LIA) was identified from the individual series, but it is characterized by wide-range spatial and temporal expression of climate variability, in contrary to the Medieval Climate Anomaly. The LIA started at the earliest by around AD 1200 and ended at the latest in the middle of the 20th century. The widespread temporal coverage of the LIA did not show regional consistency or particular spatial distribution and did not show a relationship with archive or proxy type either. A focus on the last 2 centuries shows a recent warming characterized by a well-marked warming trend parallel with increasing greenhouse gas emissions. It also shows a multidecadal variability likely due to natural processes acting on the internal climate system on a regional scale. A ∼ 16-30-year cycle is found in Alaska and seems to be linked to the Pacific Decadal Oscillation, whereas ∼ 20-30-and ∼ 50-90-year periodicities characterize the North Atlantic climate variability, likely in relation with the Atlantic Multidecadal Oscillation. These regional features are probably linked to the sea ice cover fluctuations through ice-temperature positive feedback.

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Holocene multidecadal‐ to millennial‐scale variations in Iceland‐Scotland overflow and their relationship to climate

Cited by 34 publications

References 66 publications

Constraining the Variability of the Atlantic Meridional Overturning Circulation During the Holocene

Constraining the Variability of the Atlantic Meridional Overturning Circulation During the Holocene

Variability in the Northern North Atlantic and Arctic Oceans Across the Last Two Millennia: A Review

Climate variability in the subarctic area for the last 2 millennia

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