SEDIS - Publications
SEDIS Home
Home
Login
Maslin, M. A. et al. (2011): Dynamic boundary-monsoon intensity hypothesis; evidence from the deglacial Amazon River discharge record
Leg/Site/Hole:
Related Expeditions:
ODP 155
ODP 155 942
Identifier:
ID:
2012-037084
Type:
georefid
ID:
10.1016/j.quascirev.2011.10.007
Type:
doi
Creator:
Name:
Maslin, M. A.
Affiliation:
University College London, Environmental Change Research Centre, London, United Kingdom
Role:
author
Name:
Ettwein, V. J.
Affiliation:
Lawrence Livermore National Laboratory, United States
Role:
author
Name:
Wilson, K. E.
Affiliation:
University of Massachusetts, United States
Role:
author
Name:
Guilderson, T. P.
Affiliation:
University of Leicester, United Kingdom
Role:
author
Name:
Burns, S. J.
Affiliation:
Role:
author
Name:
Leng, M. J.
Affiliation:
Role:
author
Identification:
Title:
Dynamic boundary-monsoon intensity hypothesis; evidence from the deglacial Amazon River discharge record
Year:
2011
Source:
Quaternary Science Reviews
Publisher:
Elsevier, International
Volume:
30
Issue:
27-28
Pages:
3823-3833
Abstract:
Glacioeustatic- and temperature-corrected planktonic foraminiferal oxygen isotope (Delta delta (super 18) O) records from ODP Site 942 on the Amazon Fan provide a means of monitoring past changes in the outflow of the Amazon River. This study focuses on the last deglaciation and reveals that during this period there were significant variations in the outflow, which implies large changes in moisture availability in the Amazon Basin. Aridity in the Amazon Basin seems to occur between 20.5 ka (calendar) to 17.0 ka and 13.6 ka to 11 ka. The second arid period correlates with the start of the Antarctic Cold Reversal and aridity continues throughout the Younger Dryas period. We find that the large-scale trends in Amazon River outflow are dissimilar to high-latitude variability in either hemisphere. Instead high-resolution variations correlate with the delta (super 18) O difference between Greenland and Antarctica ice core temperature records. This suggests a link between Hemispheric temperature gradients and moisture availability over the Amazon. Based on our results and previously published work we present a new testable 'dynamic boundary-monsoon intensity hypothesis', which suggests that tropical moisture is not a simple belt that moves north or south. Rather, the northern and southern boundaries of the South American Summer Monsoon (SASM) are independently dynamic and driven by temperature gradients within their individual hemispheres. The intensity of rainfall within the SASM, however, is driven by precessionally modulated insolation and the resultant convection strength. Combining these two influences produces the dynamic heterogenic changes in the moisture availability observed over tropical South America since the Last Glacial Maximum. Abstract Copyright (2011) Elsevier, B.V.
Language:
English
Genre:
Serial
Rights:
URL:
Coverage:
Geographic coordinates:
North:5.4433
West:-49.0528
East: -49.0528
South:5.4433
Keywords:
Quaternary geology; absolute age; alkaline earth metals; Amazon Basin; Amazon Fan; Amazon River; Atlantic Ocean; C-14; calcium; carbon; Cenozoic; chemostratigraphy; chronostratigraphy; climate change; cores; dates; discharge; Equatorial Atlantic; Foraminifera; Invertebrata; isotope ratios; isotopes; Leg 155; lithostratigraphy; magnesium; marine sediments; metals; Mg/Ca; microfossils; models; North Atlantic; O-18/O-16; Ocean Drilling Program; ODP Site 942; oxygen; paleoclimatology; paleohydrology; paleotemperature; Pleistocene; Protista; Quaternary; radioactive isotopes; sea-surface temperature; sediments; South America; stable isotopes; upper Pleistocene;
.
Copyright © 2006-2007 IODP-MI