Holocene climate changes in eastern Beringia (NW North America) – A systematic review of multi-proxy evidence

Kaufman, Darrell S.; Axford, Yarrow; Henderson, Andrew C.G.; McKay, Nicholas P.; Oswald, W. Wyatt; Saenger, Casey; Anderson, R. Scott; Bailey, Hannah; Clegg, Benjamin F.; Gajewski, Konrad; Hu, Feng Sheng; Jones, Miriam C.; Massa, Charly; Routson, Cody; Werner, A.; Wooller, Matthew J.; Yu, Zicheng

doi:10.1016/j.quascirev.2015.10.021

Cited by 128 publications

(175 citation statements)

References 167 publications

Supporting

Mentioning

157

Contrasting

Order By: Relevance

“…This increase in abundance is correlated with an increase in perennial sea ice, and is more prominent in cores from the Lomonosov Ridge than in cores from the Mendeleev Ridge (most likely due to more persistent perennial sea-ice cover over the Lomonosov Ridge sites). The inferred middle to late Holocene development of perennial sea ice is consistent with interpretations from other seaice proxies (Xiao et al, 2015) and with the transition from an early-middle Holocene "thermal maximum" (Kaufman et al, , 2016 to cooler conditions during the last few thousand years. (2003) and Poirier et al (2012), and core AOS94 28 (PI-94-AR-BC28, 1990 m) in Darby et al (1997).…”

Section: The Holocene (∼ 11 To Present)supporting

confidence: 86%

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

et al. 2017

View full text Add to dashboard Cite

Abstract. Late Quaternary paleoceanographic changes at the Lomonosov Ridge, central Arctic Ocean, were reconstructed from a multicore and gravity core recovered during the 2014 SWERUS-C3 Expedition. Ostracode assemblages dated by accelerator mass spectrometry (AMS) indicate changing sea-ice conditions and warm Atlantic Water (AW) inflow to the Arctic Ocean from ∼ 50 ka to present. Key taxa used as environmental indicators include Acetabulastoma arcticum (perennial sea ice), Polycope spp. (variable seaice margins, high surface productivity), Krithe hunti (Arctic Ocean deep water), and Rabilimis mirabilis (water mass change/AW inflow). Results indicate periodic seasonally seaice-free conditions during Marine Isotope Stage (MIS) 3 (∼ 57-29 ka), rapid deglacial changes in water mass conditions (15-11 ka), seasonally sea-ice-free conditions during the early Holocene (∼ 10-7 ka) and perennial sea ice during the late Holocene. Comparisons with faunal records from other cores from the Mendeleev and Lomonosov ridges suggest generally similar patterns, although sea-ice cover during the Last Glacial Maximum may have been less extensive at the new Lomonosov Ridge core site (∼ 85.15 • N, 152 • E) than farther north and towards Greenland. The new data provide evidence for abrupt, large-scale shifts in ostracode species depth and geographical distributions during rapid climatic transitions.

show abstract

Section: The Holocene (∼ 11 To Present)supporting

confidence: 86%

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

et al. 2017

View full text Add to dashboard Cite

show abstract

“…4b). For example, multi-proxy data from the interior of Alaska and adjacent territories (Kaufman et al, 2016, and references therein) indicate overall drier and warmer conditions in the middle Holocene, consistent with a weaker Aleutian Low and stronger BSI. Diatom records from the southern Bering Sea indicate more abundant sea ice in the middle Holocene, also suggestive of a weaker Aleutian Low (Katsuki et al, 2009).…”

Section: Causes Of Bsi Variationsmentioning

confidence: 97%

Holocene dynamics in the Bering Strait inflow to the Arctic and the Beaufort Gyre circulation based on sedimentary records from the Chukchi Sea

et al. 2017

View full text Add to dashboard Cite

Abstract. The Beaufort Gyre (BG) and the Bering Strait inflow (BSI) are important elements of the Arctic Ocean circulation system and major controls on the distribution of Arctic sea ice. We report records of the quartz / feldspar and chlorite / illite ratios in three sediment cores from the northern Chukchi Sea, providing insights into the long-term dynamics of the BG circulation and the BSI during the Holocene. The quartz / feldspar ratio, interpreted as a proxy of the BG strength, gradually decreased during the Holocene, suggesting a long-term decline in the BG strength, consistent with an orbitally controlled decrease in summer insolation. We propose that the BG rotation weakened as a result of the increasing stability of sea-ice cover at the margins of the Canada Basin, driven by decreasing insolation. Millennial to multi-centennial variability in the quartz / feldspar ratio (the BG circulation) is consistent with fluctuations in solar irradiance, suggesting that solar activity affected the BG strength on these timescales. The BSI approximation by the chlorite / illite record, despite a considerable geographic variability, consistently shows intensified flow from the Bering Sea to the Arctic during the middle Holocene, which is attributed primarily to the effect of higher atmospheric pressure over the Aleutian Basin. The intensified BSI was associated with decrease in sea-ice concentrations and increase in marine production, as indicated by biomarker concentrations, suggesting a major influence of the BSI on sea-ice and biological conditions in the Chukchi Sea. Multi-century to millennial fluctuations, presumably controlled by solar activity, were also identified in a proxy-based BSI record characterized by the highest age resolution.

show abstract

“…This flooding event may have led to regional forcing, such as an increase in precipitation due to more northerly storm tracks (Kaufman et al, 2010) that may have influenced glacier mass balance. Of course, there could have been more glacier fluctuations during the Younger Dryas than are currently recognized because they may have occurred during a climate state that was warmer than the late Holocene (e.g., Kurek et al, 2009;Kaufman et al, 2016), and hence moraines were later obscured by subsequent glacier advances during the Holocene.…”

Section: What Is the Spatio-temporal Record Of Glacier Change During mentioning

confidence: 99%

“…We build from the most recent review of the Pleistocene glacier history of Alaska (Kaufman et al, 2011). There have been some new glacial chronology studies published since that time, and furthermore, unlike past reviews spanning the Late Pleistocene (Briner and Kaufman, 2008;Kaufman et al, 2011) and spanning the Holocene (Barclay et al, 2009;Kaufman et al, 2016), this paper focuses solely on the last deglaciation. This is the first review paper on the glaciation history of Alaska to do so.…”

Section: Introductionmentioning

confidence: 99%

The last deglaciation of Alaska

Briner

Tulenko

Kaufman

et al. 2017

CIG

View full text Add to dashboard Cite

show abstract

Holocene climate changes in eastern Beringia (NW North America) – A systematic review of multi-proxy evidence

Cited by 128 publications

References 167 publications

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

Holocene dynamics in the Bering Strait inflow to the Arctic and the Beaufort Gyre circulation based on sedimentary records from the Chukchi Sea

The last deglaciation of Alaska

Contact Info

Product

Resources

About

Holocene climate changes in eastern Beringia (NW North America) – A systematic review of multi-proxy evidence

Cited by 128 publications

References 167 publications

Central Arctic Ocean paleoceanography from ∼ 50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

Central Arctic Ocean paleoceanography from ∼ 50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

Holocene dynamics in the Bering Strait inflow to the Arctic and the Beaufort Gyre circulation based on sedimentary records from the Chukchi Sea

The last deglaciation of Alaska

Contact Info

Product

Resources

About

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition

Central Arctic Ocean paleoceanography from ∼  50 ka to present, on the basis of ostracode faunal assemblages from the SWERUS 2014 expedition