Holocene climate optimum and last glacial maximum in the Mediterranean: the marine oxygen isotope record
Holocene climate optimum and last glacial maximum in the Mediterranean: the marine oxygen isotope record
Reconstructions with comprehensive estimates of confidence intervals are presented of changes in the W–E stable oxygen isotope gradient in Mediterranean surface waters between the Holocene Climate Optimum and the Present, and between the Last Glacial Maximum and the Present. Rigorous statistical assessment is made of the significances of the mean geographic trends observed in these reconstructions. Firstly, it is concluded that any reconstruction should strictly be based on values obtained by analyses of one single foraminiferal species throughout the basin, as different species are found to respond with isotopic variations of different amplitudes to climatic/hydrographic change. This difference is tentatively related to differences between the habitats and seasons of growth of the various species. Secondly, a significant increase of roughly a factor 3 is found in the Mediterranean W–E oxygen isotope gradient during the Last Glacial Maximum, relative to the Present. This difference is almost entirely due to increased glacial values in the Levantine Sea, which are considered to be a result of a combination of increased evaporation rates and/or somewhat cooler than anticipated surface water conditions. Thirdly, an eastward increase of roughly half the present-day magnitude is found for the W–E oxygen isotope gradient during the Holocene Climate Optimum. Values in the Levantine Sea appear to have undergone up to 0.3‰ more depletion than those elsewhere in the eastern Mediterranean. However, no significant trends are found between the eastern and western parts of the Levantine Sea, nor between values near the Nile delta and those from elsewhere in the Levantine Sea. The Holocene Climate Optimum's eastward increase in the Mediterranean oxygen isotope gradient, although weaker than the Present, suggests that the Mediterranean continued to function as a concentration basin, albeit in a less vigorous way than today. Finally, simple mixing arguments are used to argue that inferred oxygen isotope ratios of surface waters may not be used as an indication of conservative property (e.g. salinity) distribution on geological timescales, but instead show amplitudes of response to climatic/hydrographic changes that likely are >2 times larger than the corresponding amplitudes of response for truly conservative properties.
Last Glacial Maximum, Holocene, Mediterranean, oxygen isotopes, palaeoclimatology
57-75
Rohling, E.J.
a2a27ef2-fcce-4c71-907b-e692b5ecc685
De Rijk, S.
b6fc7c3a-2d43-468d-9caf-e07d810a0af7
1999
Rohling, E.J.
a2a27ef2-fcce-4c71-907b-e692b5ecc685
De Rijk, S.
b6fc7c3a-2d43-468d-9caf-e07d810a0af7
Rohling, E.J. and De Rijk, S.
(1999)
Holocene climate optimum and last glacial maximum in the Mediterranean: the marine oxygen isotope record.
Marine Geology, 153 (1-4), .
(doi:10.1016/S0025-3227(98)00020-6).
Abstract
Reconstructions with comprehensive estimates of confidence intervals are presented of changes in the W–E stable oxygen isotope gradient in Mediterranean surface waters between the Holocene Climate Optimum and the Present, and between the Last Glacial Maximum and the Present. Rigorous statistical assessment is made of the significances of the mean geographic trends observed in these reconstructions. Firstly, it is concluded that any reconstruction should strictly be based on values obtained by analyses of one single foraminiferal species throughout the basin, as different species are found to respond with isotopic variations of different amplitudes to climatic/hydrographic change. This difference is tentatively related to differences between the habitats and seasons of growth of the various species. Secondly, a significant increase of roughly a factor 3 is found in the Mediterranean W–E oxygen isotope gradient during the Last Glacial Maximum, relative to the Present. This difference is almost entirely due to increased glacial values in the Levantine Sea, which are considered to be a result of a combination of increased evaporation rates and/or somewhat cooler than anticipated surface water conditions. Thirdly, an eastward increase of roughly half the present-day magnitude is found for the W–E oxygen isotope gradient during the Holocene Climate Optimum. Values in the Levantine Sea appear to have undergone up to 0.3‰ more depletion than those elsewhere in the eastern Mediterranean. However, no significant trends are found between the eastern and western parts of the Levantine Sea, nor between values near the Nile delta and those from elsewhere in the Levantine Sea. The Holocene Climate Optimum's eastward increase in the Mediterranean oxygen isotope gradient, although weaker than the Present, suggests that the Mediterranean continued to function as a concentration basin, albeit in a less vigorous way than today. Finally, simple mixing arguments are used to argue that inferred oxygen isotope ratios of surface waters may not be used as an indication of conservative property (e.g. salinity) distribution on geological timescales, but instead show amplitudes of response to climatic/hydrographic changes that likely are >2 times larger than the corresponding amplitudes of response for truly conservative properties.
This record has no associated files available for download.
More information
Published date: 1999
Keywords:
Last Glacial Maximum, Holocene, Mediterranean, oxygen isotopes, palaeoclimatology
Identifiers
Local EPrints ID: 28826
URI: http://eprints.soton.ac.uk/id/eprint/28826
ISSN: 0025-3227
PURE UUID: 789e6c99-971f-466e-b556-7b6b3ffa010a
Catalogue record
Date deposited: 05 May 2006
Last modified: 16 Mar 2024 02:46
Export record
Altmetrics
Contributors
Author:
S. De Rijk
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
