Centennial to millennial climate variability in the far northwestern Pacific (off Kamchatka) and its linkage to the East Asian monsoon and North Atlantic from the Last Glacial Maximum to the early Holocene

Gorbarenko, Sergey A; Shi, Xuefa; Malakhova, G. I.; Bosin, Aleksandr A.; Zou, Jianjun; Liu, Yanguang; Chen, Min‐Te

doi:10.5194/cp-13-1063-2017

Cited by 10 publications

(13 citation statements)

References 84 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…According to our SST compilation (Figure 3), most SST records in the subarctic Pacific show abrupt warming into the BA and cooling into the YD. In detail, the BA warming was consistent with elevated primary productivity and reduced spring sea-ice coverage in the Northwestern Pacific (Caissie et al, 2010;Gorbarenko et al, 2017;Max et al, 2012;Méheust et al, 2016Méheust et al, , 2018 and Northeastern Pacific (Davies et al, 2011;Méheust et al, 2018). During the YD, the rapid cooling in the Northwestern Pacific and its marginal seas was closely coupled to extended spring sea-ice coverage (Max et al, 2012;Méheust et al, 2016Méheust et al, , 2018.…”

Section: Sst Changes In the Subarctic Pacific Since The Last Ice Agementioning

confidence: 68%

“…We will explore the possible mechanisms responsible for these contrasting phase relationships in Section 4.2. Despite inconsistent patterns in the subarctic Pacific, the SST remained at relatively low values during HS1 on both sides of the subarctic Pacific (Figure 3), corresponding to the southward expansion of the spring sea‐ice coverage and low marine productivity (Davies et al., 2011; Gorbarenko et al., 2017; Max et al., 2012; Méheust et al., 2018).…”

Section: Discussionmentioning

confidence: 99%

“…Core LV63‐41‐2 (52°34′N, 160°01′E; water depth = 1,924 m; length = 467 cm) was collected from the Northwestern Pacific off the Kamchatka Peninsula during the joint Chinese‐Russian Expedition on R/V Akademik M. A. Lavrentyev in 2013. The age model of core LV63‐41‐2 is well established based on AMS 14 C dating on foraminiferal shells and age tie points obtained by tuning to a nearby core SO201‐2‐12KL and the Chinese stalagmite δ 18 O records (Gorbarenko et al., 2017; Yu et al., 2020). We have re‐calibrated the AMS 14 C data into calendar ages using Calib 8.20 with the latest Marine20 calibration curve (Table S1 in Supporting Information ) and revised the chronology of core LV63‐41‐2.…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

An Integrated View of Organic Biomarker‐Based Sea Surface Temperature Changes in the Subarctic Pacific Since the Last Ice Age

Chen

et al. 2022

Paleoceanog and Paleoclimatol

Self Cite

View full text Add to dashboard Cite

A prevailing view for abrupt millennial-scale climate fluctuations during the last deglaciation in the Northern Hemisphere is tightly linked to changes in the Atlantic meridional overturning circulation (AMOC) (McManus et al., 2004). Evidence suggests that perturbations in the North Pacific can also have a significant impact on regional and global climate fluctuations by altering the poleward transport of heat and moisture (Praetorius

show abstract

Section: Sst Changes In the Subarctic Pacific Since The Last Ice Agementioning

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

An Integrated View of Organic Biomarker‐Based Sea Surface Temperature Changes in the Subarctic Pacific Since the Last Ice Age

Chen

et al. 2022

Paleoceanog and Paleoclimatol

Self Cite

View full text Add to dashboard Cite

show abstract

“…The third and last hypothesis is that a change(s) among the terrigenous deposits explain the lower SD ferromagnetic grains input into the central Okhotsk Sea. Previous studies reported contemporaneous (i.e., <500 ka) environmental changes during interglacial intervals such as decreasing of IRD (e.g., Nürnberg and Tiedemann, 2004;Gorbarenko et al, 2017) and the increasing of sea level (e.g., Thomas et al, 2009). The latter strongly modified the input of terrigenous sediments in the center of Okhotsk Sea (e.g., Liu et al, 2006;Nürnberg et al, 2011;Jimenez-Espejo et al, 2018).…”

Section: Paleoenvironment In the Central Okhotsk Sea During Stronger-interglacial/ Interglacial Intervalsmentioning

confidence: 99%

Controls on Terrigenous Detritus Deposition and Oceanography Changes in the Central Okhotsk Sea Over the Past 1550 ka

Chou

Jiang

et al. 2021

Front. Earth Sci.

Self Cite

View full text Add to dashboard Cite

The Okhotsk Sea, which connects the high latitude Asian continent and the North Pacific, plays an important role in modern and past climate changes due to seasonal sea ice coverage and as a precursor of the North Pacific Intermediate Water. The long-term glacial-interglacial changes of sea ice coverage and its impacts on terrigenous transport and surface primary productivity in the Okhotsk Sea remain, however, not well constrained. Base on the paleomagnetic, rock magnetic, micropaleontological (diatom), and geochemical studies of the marine sediment core MD01-2414 (53°11.77′N, 149°34.80′E, water depth: 1,123 m) taken in the central Okhotsk Sea, we reconstruct the terrigenous sediment transport and paleoceanographic variations during the past 1550 thousand years (kyr). Seventeen geomagnetic excursions are identified from the paleomagnetic directional record. Close to the bottom of the core, an excursion was observed, which is proposed to be the Gilsa event ∼1550 thousand years ago (ka). During glacial intervals, our records reveal a wide extension of sea ice coverage and low marine productivity. We observed ice-rafted debris from mountain icebergs composed of coarse and high magnetic terrigenous detritus which were derived from the Kamchatka Peninsula to the central Okhotsk basin. Still during glacial intervals, the initiation (i.e., at ∼900 ka) of the Mid-Pleistocene Transition marks the changes to even lower marine productivity, suggesting that sea-ice coverage became larger during the last 900 ka. During interglacial intervals, the central Okhotsk Sea was either devoid of sea-ice or the ice was at best seasonal; resulting in high marine productivity. The weaker formation of Okhotsk Sea Intermediate Water, lower ventilation, and microbial degradation of organic matter depleted the oxygen concentration in the bottom water and created a reduced environment condition in the sea basin. The freshwater supplied by snow or glacier melting from Siberia and Kamchatka delivered fine grain sediments to the Okhotsk Sea. During the stronger interglacial intervals after the Mid-Brunhes Transition (i.e., Marine Isotope Stages 1, 5e, 9, and 11), strong freshwater discharges from Amur River drainage area are in association with intensified East Asian Summer Monsoon. This process may have enhanced the input of fine-grained terrigenous sediments to the central Okhotsk Sea.

show abstract

“…All these background conditions differ significantly from present background conditions. Previous studies suggest that, during the last deglaciation, a tight coupling between the Asian summer monsoon and the North Atlantic temperature changes exists at centennial to millennial timescales [13,[16][17][18]. However, the characteristics of multidecadal-scale oscillations of the vegetation and climate in the Asian monsoon region, and their linkages with the North Atlantic climates remain controversial.…”

Section: Introductionmentioning

confidence: 99%

Multidecadal Monsoon Variations during the Early Last Deglaciation Revealed by Speleothem Record from Southwestern China

Liang,

Zhang,

et al. 2024

Minerals

View full text Add to dashboard Cite

The Asian monsoon (AM) has direct and profound effects on the livelihoods of residents in South Asia and East Asia. Modern observations have shown multi-decadal alternations of flood and drought periods in these regions, likely influenced by climatic processes such as the Atlantic Multidecadal Oscillation and the Pacific Decadal Oscillation. However, our understanding of the multi-decadal variability of the AM under different climatic conditions remains uncertain. In this study, we collected an annually laminated and 780-mm stalagmite (sample number: BJ7) from Binjia (BJ) Cave in southwestern China, which is deeply influenced by the Asian monsoon system. Based on this sample, we established 6-year resolution and multi-proxy records for the Asian summer monsoon (ASM) variabilities during the early last termination, spanning from 18.2 to 16.1 ka BP. Measurements of five pairs of uranium and thorium solutions for 230Th dating were conducted using a multi-collector inductively coupled plasma mass spectrometer (MC-ICP- MS), and 374 pairs of stable isotope (δ18O and δ13C) analyses were run on a Kiel Carbonate Device connected with Finnigan MAT-253 at Nanjing Normal University. The chronology for this sample was established by annual layer counting anchored with 230Th dating results. Our BJ7 δ18O record replicates well with other Chinese δ18O records on the general trend, all of which are superimposed by frequent multidecadal-scale fluctuations at approximately 60 years periodicity. Inspection of the 60-year band in BJ7 δ18O and δ13C records and results of the cross-wavelet analysis indicate coherent changes in the ASM and biomass production/karst processes during most of the studied period. In addition, the 60-year band of BJ7 and NGRIP δ18O records are consistent, implying the impacts of the high-latitude North Atlantic or Atlantic Multidecadal Oscillation on the ASM. Our study suggests that the 60-year variability should be an intrinsic feature of the climate system regardless of glacial or interglacial backgrounds.

show abstract

Centennial to millennial climate variability in the far northwestern Pacific (off Kamchatka) and its linkage to the East Asian monsoon and North Atlantic from the Last Glacial Maximum to the early Holocene

Cited by 10 publications

References 84 publications

An Integrated View of Organic Biomarker‐Based Sea Surface Temperature Changes in the Subarctic Pacific Since the Last Ice Age

An Integrated View of Organic Biomarker‐Based Sea Surface Temperature Changes in the Subarctic Pacific Since the Last Ice Age

Controls on Terrigenous Detritus Deposition and Oceanography Changes in the Central Okhotsk Sea Over the Past 1550 ka

Multidecadal Monsoon Variations during the Early Last Deglaciation Revealed by Speleothem Record from Southwestern China

Contact Info

Product

Resources

About