Incarbona, Alessandro; Di Stefano, Enrico; Patti, Bernardo; Pelosi, Nicola; Bonomo, Sergio; Mazzola, Salvatore; Sprovieri, Rodolfo; Tranchida, Giorgio; Zgozi, Salem; Bonanno, Angelo (2008): Holocene millenial-scale productivity record in the Mediterranean Sea [dataset publication series]. PANGAEA, https://doi.org/10.1594/PANGAEA.832127,

---

Supplement to: Incarbona, A et al. (2008): Holocene millennial-scale productivity variations in the Sicily Channel (Mediterranean Sea). Paleoceanography, 23(3), PA3204, https://doi.org/10.1029/2007PA001581

The calcareous nannofossil assemblages of Ocean Drilling Program Hole 963D from the central Mediterranean Sea have been investigated to document oceanographic changes in surface waters. The studied site is located in an area sensitive to large-scale atmospheric and climatic systems and to high- and low-latitude climate connection. It is characterized by a high sedimentation rate (the achieved mean sampling resolution is <70 years) that allowed the Sicily Channel environmental changes to be examined in great detail over the last 12 ka BP. We focused on the species Florisphaera profunda that lives in the lower photic zone. Its distribution pattern shows repeated abundance fluctuations of about 10-15%. Such variations could be related to different primary production levels, given that the study of the distribution of this species on the Sicily Channel seafloor demonstrates the significant correlation to productivity changes as provided by satellite imagery. Productivity variations were quantitatively estimated and were interpreted on the basis of the relocation of the nutricline within the photic zone, led by the dynamics of the summer thermocline. Productivity changes were compared with oceanographic, atmospheric, and cosmogenic nuclide proxies. The good match with Holocene master records, as with ice-rafted detritus in the subpolar North Atlantic, and the near-1500-year periodicity suggest that the Sicily Channel environment responded to worldwide climate anomalies. Enhanced Northern Hemisphere atmospheric circulation, which has been reported as one of the most important forcing mechanisms for Holocene coolings in previous Mediterranean studies, had a remarkable impact on the water column dynamics of the Sicily Channel.