The present study uses a multiproxy approach in order to further understand the evolution of climate responses in the western Mediterranean as of the Last Glacial Maximum. Sediments from ODP Site 975 in the Algero–Balearic basin have been analysed at high resolution, both geochemically and mineralogicallly. The resulting data have been used as proxies to establish a sedimentary regime, primary marine productivity, the preservation of the proxies and oxygen conditions. Fluctuations in detrital element concentrations were mainly the consequence of wet/arid oscillations. Productivity has been established using Ba excess, according to which marine productivity appears to have been greatest during cold events Heinrich 1 and Younger Dryas. The S1 time interval was not as marked by increases in productivity as was the eastern Mediterranean. In contrast, the S1 interval was first characterized by a decreasing trend and then by a fall in productivity after the 8.2 ky BP dry-cold event. Since then productivity has remained low. Here we report that there was an important redox event in this basin, probably a consequence of the major oceanographic circulation change occurring in the western Mediterranean at 7.7 ky BP. This circulation change led to reventilation as well as to diagenetic remobilization of redox-sensitive elements and organic matter oxidation. Comparisons between our paleoceanographic reconstruction for this basin and those regarding other Mediterranean basins support the hypothesis that across the Mediterranean there were different types of responses to climate forcing mechanism. The Algero–Balearic basin is likely to be a key area for further understanding of the relationships between the North Atlantic and the eastern Mediterranean basins.

We are grateful to the ODP Core Repository personnel (Bremen, Germany) for their assistance with sampling. Analyses were performed at the Analytical Facilities (CIC) and Department of Mineralogy and Petrology (University of Granada), and at the Japanese Agency for Marine–Earth Sciences and Technology (JAMSTEC). The authors are indebted to Dr. K.-C. Emeis for stimulating discussion and to Dr. T. Correge, as editor, and to Dr. N. Fagel and one anonymous reviewer for their invaluable comments and reviews. We are likewise grateful to project CSD2006-00041 and to E. Pinero, E. Abarca, E. Holanda, J. Montes, C. Niembro, D. Ortega for laboratory assistance. Editing of the original English manuscript was done by M. Bettini. This study was financed by Projects REN2003-09130-CO2-01 and CGL2006-13327-C04-04/CLI (MEC), Project RNM432 and Research Group RNM0179 (Junta de Andalucía).

4 figures, 1 table.

Peer reviewed