Holocene weak summer East Asian monsoon intervals in Taiwan and plausible mechanisms

Multi-proxy records in two sediment cores (R and Rd) from the subalpine Retreat Lake in NE Taiwan document 5 centennial-scale periods (∼7.3–6.9, 6.35–5.9, 5.8–5.1, 4.5–∼2.1, and 2.0–1.6 ka BP) of relatively reduced summer East Asian monsoon (EAM) precipitation that were superimposed on the long-term...

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Bibliographic Details
Published in:Quaternary international 2011, Vol.229 (1), p.57-66
Main Authors: Selvaraj, Kandasamy, Arthur Chen, Chen-Tung, Lou, Jiann-Yuh, Kotlia, B.S.
Format: Article
Language:English
Subjects:
bulk density
carbon nitrogen ratio
climate
cooling
El Nino
heat
lakes
Marine
monsoon season
sediments
solar radiation
summer
surface water temperature
water content
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Summary:Multi-proxy records in two sediment cores (R and Rd) from the subalpine Retreat Lake in NE Taiwan document 5 centennial-scale periods (∼7.3–6.9, 6.35–5.9, 5.8–5.1, 4.5–∼2.1, and 2.0–1.6 ka BP) of relatively reduced summer East Asian monsoon (EAM) precipitation that were superimposed on the long-term decreasing monsoon trend from ∼8 ka BP onwards. The first three intervals of weak summer EAM indicated by low TOC, C/N ratio and water content within the Holocene optimum (∼8.6–4.5 ka BP) correlate with solar activity, revealing that the centennial-scale summer monsoon variations in a warm climate were related to weak solar irradiance. The desiccation of the lake (4.5–∼2.1 ka BP), followed by a weak monsoon event at ∼2.0–1.6 ka BP, may coincide with decreased sea surface temperature in the tropical Pacific. High water content and low dry bulk density in core Rd at ∼7.6, 7.46, 6.8–6.54, 6.1, 5.8, 5.6, and 5.0 ka BP imply a significant increase of summer EAM during these periods, and thus suggest an unstable optimum climate in Taiwan. A possible linkage of weak summer EAM with the tropical Pacific and North Atlantic cooling during these intervals may be driven by coupled ocean–atmosphere interactions, especially reduced heat and moisture transport and enhanced El Niño-Southern Oscillation in the tropical Pacific, as well as solar activity. The centennial-scale reorganizations in the tropical Pacific climate dynamics may have played an important role in the summer EAM instability, particularly during the late Holocene.
ISSN:1040-6182
1873-4553
DOI:10.1016/j.quaint.2010.01.015