International audienceWhile several tectonic models (e.g., simple shear, detachment or mantle exhumation) are proposed to explain theformation of extensive basins and passive margins; a single thermal model (McKenzie, 1978), as a kind of dogma,is used to model the formation and evolution of sedimentary basins. The thermal evolution of such basins, coupledwith other tectonic models, have been scarcely studied in detail. For instances, petrological changes (i.e. phasetranisitions), related to temperature changes, affect rock density and thus influence the subsidence history of thebasin. Recent studies of continental passive margins collectively describe a great number of processes accountingfor the extreme thinning of the continental crust. Among all the parameters that may act during crustal stretching,the thermal state of the system and the temporal evolution of the heat distribution during thinning appear of majorimportance.We explore the effect of different thermal evolution models on petrological changes and their consequences on thegeophysical signature of rifted zones.We will present computed geodynamic models quantifying mineralogical and physical changes in the lithosphereduring rifting processes and early margin formation. In the light of these high temperature evolution modelssupported by new field data from the north Pyrenean basins, we discuss the effect on subsidence as well as ongravimetric and seismic velocities signatures of passive margins.Consequently, we are able to distinguish two types of margins according to their thermal evolution:- An Alpine-type basin in which the temperature increase is 50 to 100 Ma older than the tectonic extension,leading to the "cold" opening of the ocean.- A Pyrenean type basin where heating is coincident with basin formation, leading to a crustal boudinage andformation of an “anomalous” geophysical layer at the OC
