Sea-level and climate forcing of the Sr isotope composition of marginal basins in the late Miocene Mediterranean Basin
Abstract
Sr isotope records from marginal marine basins track the mixing between sea water and local continental runoff. Because changes in sea level determine the amount of mixing between global marine and continental water, and climate affects the amount of continental runoff, both sea-level and climate changes can potentially be recorded in marine fossil Sr isotope composition. Our 128 new 87Sr/86Sr analyses on 73 oyster, foraminifera, and coral samples from eight late Miocene stratigraphic sections in southern Turkey, Crete, and Sicily show that 87Sr/86Sr in Mediterranean marginal basins started to depart from global ocean values several million years before the Messinian Salinity Crisis (MSC), with sub-basin 87Sr/86Sr commonly dropping 0.000100 below contemporaneous global ocean values. The marked departure coincided with tectonic uplift and basin shallowing along the margins of the Mediterranean Basin. In contrast, centrally-located basins within the Mediterranean (e.g., Cyprus, Sicily, Crete) only record departures during the MSC. Besides this general trend, our 57 new 87Sr/86Sr analyses from the astronomically tuned Lower Evaporite unit deposited during the MSC in the central Apennines (Italy) allow us to explore in detail the effect of sea-level and humidity changes on 87Sr/86Sr . Most of the variation in 87Sr/86Sr that we observe can be explained by changes in eustatic sea level, with greatest departures from global ocean values (with differences up to 0.000150) occurring during sea-level lowstands, which were characterized by relatively arid conditions in the Mediterranean. However, in a few cases, the greatest 87Sr/86Sr departures (up to 0.000300) occur during sea-level highstands, which are marked by more humid conditions. Because the correlations between peaks in Sr departures and highstands (humid conditions) occur only after episodes of prolonged aridity, variations of residence time of continental water (particularly groundwater) could have affected its Sr concentration, and hence the degree to which continental water could perturb 87Sr/86Sr in marine sub-basins. Although our results demonstrate that the forcing behind variations in Sr isotope composition in marginal marine basins is more complex than what is typically included in Sr isotope box models, they also imply that high-resolution records, particularly when combined with independent information on sea-level or climate changes, could offer unique insights into local tectonic, climatic, and sea-level variations.
- Publication:
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AGU Fall Meeting Abstracts
- Pub Date:
- December 2013
- Bibcode:
- 2013AGUFMPP43A2068S
- Keywords:
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- 1050 GEOCHEMISTRY Marine geochemistry;
- 4934 PALEOCEANOGRAPHY Insolation forcing;
- 4556 OCEANOGRAPHY: PHYSICAL Sea level: variations and mean;
- 4243 OCEANOGRAPHY: GENERAL Marginal and semi-enclosed seas