High-resolution temperature and evaporation changes during the Late Holocene in the northeastern Arabian Sea

In order to reconstruct the monsoonal variability during the late Holocene we investigated a complete, annually laminated sediment record from the oxygen minimum zone (OMZ) off Pakistan for oxygen isotopes of planktic foraminifera and alkenone‐derived sea surface temperatures (SST). Significant SST...

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Veröffentlicht in:Paleoceanography 2001-08, Vol.16 (4), p.358-367
Hauptverfasser: Doose‐Rolinski, Heidi, Rogalla, Ulf, Scheeder, Georg, Lückge, Andreas, Rad, Ulrich
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Sprache:eng
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Zusammenfassung:In order to reconstruct the monsoonal variability during the late Holocene we investigated a complete, annually laminated sediment record from the oxygen minimum zone (OMZ) off Pakistan for oxygen isotopes of planktic foraminifera and alkenone‐derived sea surface temperatures (SST). Significant SST changes of up to 3°C which cannot be explained by changes in the alkenone‐producing coccolithophorid species (inferred from the Gephyrocapsa oceanica / Emiliania huxleyi ratio) suggest that SST changes are driven by changes in the monsoon strength. Our high‐(decadal)‐resolution data indicate that the late Holocene in the northeastern Arabian Sea was not characterized by a stable uniform climate, as inferred from the Greenland ice cores, but by variations in the dominance of the SW monsoon conditions with significant effects on temperatures. Highest SST fluctuations of up to 3.0°C and 2.5°C were observed for the time interval from 4600 to 3300 years B.P. and during the past 500 years. The significant, short‐term SST changes during the past 500 years might be related to climatic instabilities known from the northern latitudes (“Little Ice Age”) and confirm global effects. Surface salinity values, reconstructed from δ18O records after correction for temperature‐related oxygen isotope fractionation, suggest that in general, the past 5000 years were characterized by higher‐than‐recent evaporation and more intense SW monsoon conditions. However, between 4600 and 3700 years B.P., evaporation dropped, SW monsoon weakened, and NE monsoon conditions were comparatively enhanced. For the past 1500 years we infer strongly fluctuating monsoon conditions. Comparisons of reconstructed salinity records with ice accumulation data from published Tibetan ice core and Tibetan tree ring width data reveal that during the past 2000 years, enhanced evaporation in the northeastern Arabian Sea correlates with periods of increased ice accumulation in Tibet, and vice versa. This suggests a strong climatic relationship between both monsoon‐controlled areas.
ISSN:0883-8305
1944-9186
DOI:10.1029/2000PA000511