Thermal Evolution of Asymmetric Hyperextended Magma‐Poor Rift Systems: Results From Numerical Modeling and Pyrenean Field Observations

Abstract We investigate the thermal and structural evolution of asymmetric rifted margin using numerical modeling and geological observations derived from the Western Pyrenees. Our numerical model provides a self‐consistent physical evolution of the top basement heat flow during asymmetric rifting. The model shows a pronounced thermal asymmetry that is caused by migration of the rift center toward the upper plate. The same process creates a diachronism for the record of maximum heat flow and maximum temperatures ( T max ) in basal rift sequences. The Mauléon‐Arzacq basin (W‐Pyrenees) corresponds to a former mid‐Cretaceous asymmetric hyperextended rift basin. New vitrinite reflectance data in addition to existing data sets from this basin reveal an asymmetry in the distribution of peak heat ( T max ) with respect to the rift shoulders, where highest values are located at the former upper‐ to lower‐plate transition. This data set from the Arzacq‐Mauléon field study confirms for the first time the thermal asymmetry predicted by numerical models. Numerical modeling results also suggest that complexities in synrift thermal architecture could arise when hanging‐wall‐derived extensional allochthons and related T max become part of the lower plate and are transported away from the upper‐ to lower‐plate transition. This study emphasizes the limitations of the common approach to integrate punctual thermal data from pre‐rift to synrift sedimentary sequences in order to describe the rift‐related thermal evolution and paleothermal gradients at the scale of a rift basin or a rifted margin.