Continental rifting is an important component of the Wilson cycle, and a process-level description requires integration of constraints from seismic tomography, seismic anisotropy, and non-isostatic topography in addition to geological observations. We discuss the evolution of the East African Rift (EAR) and the European Cenozoic Rift System (ECRIS) and define two end members. 1) a-type rifts, such as the EAR and ECRIS, form parallel to mantle flow above elongated, asthenospheric anomalies of low-seismic velocity, “fingers” (LVF) and stay at embryonic stage with slow extension mostly driven by gravitational potential energy. 2) b-type rifts, such as the Menderes and Corinth Rifts, form perpendicular to mantle flow and lead to oceanisation; the Gulf of Aden, Red Sea and Baikal are intermediate. We then propose a new model for the evolution of the short-lived ECRIS (∼44–33 Ma) in the magma-poor period of transition between the Pyrenean orogeny and Mediterranean back-arc extension. The propagation of a LVF toward the north emanating from the Canaries hotspot, all the way to the Massif Central and the upper and lower Rhine region formed the rift on top of a positive anomaly of non-isostatic topography. Fast slab retreat from the end of the Eocene modified asthenospheric mantle flow, initiating the recent Mediterranean subduction regime with back-arc basin opening and dispersal of the asthenospheric anomaly. From ∼8 Ma, slab retreat successively ceased in the central and western Mediterranean, giving way to compression and resumption of volcanism, possibly related to the reestablishment of a mantle LVF. We conclude speculating on the respective roles of a-type and b-type rifts for plate tectonics more general, including for the Mesozoic fragmentation of Pangea.
Jolivet, L., Faccenna, C., Becker, T., Davaille, A., Lasseur, E., Briais, J., et al. (2025). Continental rifts and mantle convection. EARTH-SCIENCE REVIEWS, 270(November 2025) [10.1016/j.earscirev.2025.105243].
Continental rifts and mantle convection
Sternai P.;
2025
Abstract
Continental rifting is an important component of the Wilson cycle, and a process-level description requires integration of constraints from seismic tomography, seismic anisotropy, and non-isostatic topography in addition to geological observations. We discuss the evolution of the East African Rift (EAR) and the European Cenozoic Rift System (ECRIS) and define two end members. 1) a-type rifts, such as the EAR and ECRIS, form parallel to mantle flow above elongated, asthenospheric anomalies of low-seismic velocity, “fingers” (LVF) and stay at embryonic stage with slow extension mostly driven by gravitational potential energy. 2) b-type rifts, such as the Menderes and Corinth Rifts, form perpendicular to mantle flow and lead to oceanisation; the Gulf of Aden, Red Sea and Baikal are intermediate. We then propose a new model for the evolution of the short-lived ECRIS (∼44–33 Ma) in the magma-poor period of transition between the Pyrenean orogeny and Mediterranean back-arc extension. The propagation of a LVF toward the north emanating from the Canaries hotspot, all the way to the Massif Central and the upper and lower Rhine region formed the rift on top of a positive anomaly of non-isostatic topography. Fast slab retreat from the end of the Eocene modified asthenospheric mantle flow, initiating the recent Mediterranean subduction regime with back-arc basin opening and dispersal of the asthenospheric anomaly. From ∼8 Ma, slab retreat successively ceased in the central and western Mediterranean, giving way to compression and resumption of volcanism, possibly related to the reestablishment of a mantle LVF. We conclude speculating on the respective roles of a-type and b-type rifts for plate tectonics more general, including for the Mesozoic fragmentation of Pangea.
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