Orbital-scale changes in redox condition and biogenic silica/detrital fluxes of the Middle Jurassic Radiolarite in Tethys (Sogno, Lombardy, N-Italy): Possible link with glaciation?

Orbital forcing has been shown to be a fundamental driver of climate change through both icehouse and greenhouse periods. To reveal the impact of orbital-forcing on the oceanic environment through a greenhouse icehouse transition, we established similar to 4 Myr-long cyclostratigraphy of the Bajocian-Callovian (Middle Jurassic; similar to 160 Ma) Basal Radiolarites at the Torre De Busi and Corre Di Sogno sections in the Lombardian Basin, N-Italy. Stratigraphic changes in chert abundance (chert/shale thickness ratio) and color (darkness) of Radiolarites show hierarchal periodicities of 8 cm, 16 cm, 40 cm, 160 cm, and similar to 4 m, corresponding to similar to 20 kyr, 40 kyr, 100 kyr, 400 kyr, and similar to 1 Myr cycles based on the biostratigraphic age model. Black cherts in intervals with high chert abundance might reflect oxygen-depleted conditions due to orbital-scale high productivity. On the other hand, black cherts in intervals with low chert abundance (high detrital input) might reflect oxygen depleted conditions, probably due to orbital-scale sea-level drop and stratification. On 40 kyr and 100 kyr cycles, the anoxic condition occurred in low chert abundance intervals across similar to 8 m above (similar to 2 Myr after) the base of the Radiolarites. These results imply that the formation of the restricted basin resulted from tectonic and/or eustatic sea-level drop, which is consistent with increased black chert deposition and redox-sensitive elements abundances (Mo/TOC, Mo/U). Their out-of-phase relationships on the 405 kyr cycle throughout the sequence (similar to 4 Myr-long) with increasing amplitude above - 8 M level would be caused possibly by tectonic activity, or more likely by glacio-eustatic sea-level changes reported from sequence stratigraphy, similar to those of the Oligocene to Pliocene glacial cycles, but probably with less amplitude. (C) 2016 Elsevier B.V. All rights reserved.