Abstract EN:

The numerous discoveries realized in deep water, magma-poor rifted margins demonstrated the complex nature of these margins. However the processes enabling to accommodate the lithospheric extension and controlling the structural architecture are yet poorly understood. The aim of this thesis was to characterize the extensional deformation in time and space along magma-poor rifted margins. The results of this thesis highlight the importance to characterize the architecture of magma-poor rifted margins and the underlying extensional deformation by defining the building blocks of these margins. The systematic identification of these blocks either by direct observations (seismic images) or by indirect methods (potential methods) allowed four domains and three major limits to be defined. The major new concept developed in this study was to describe these domains and limits as part of the temporal and spatial evolution of the margins and to be able to characterize and quantify the deformation associated with these domains. This approach enabled us to propose a kinematic inversion of the Iberia-Newfoundland rift system and to test this new concept along the Brazilian and West-African rifted margins. Of major importance in the study of rifted margins is the role and evolution of intra-crustal decoupling horizons that control the extensional deformation. The interaction between brittle and ductile layers during rifting is complex, highly 3D and controlled by the structural, thermal, and compositional inheritance. Unraveling the complex interactions between inheritance and rifting processes in time and space appears essential to understand and predict the evolution of rifted margins.