Analog models of oblique rifting in a cold lithosphere

New lithospheric analog models of oblique rifting presented here capture the main characteristics of natural oblique rifts and provide insights into the fault evolution, basin segmentation, and mantle exhumation occurring during rift localization. We present two models: one with a preexisting oblique lithospheric weakness (model B) and another with no weakness zone (model A). Both oblique rifts have an obliquity of about 40°. The main results are as follows. (1) The fault populations, especially during the early stages of deformation, are composed of faults that in strike are largely intermediate between rift‐parallel and perpendicular to displacement. This fault population is characteristic of oblique rifts observed in previous studies. (2) In later stages, faults parallel to the rift become numerous in both models. Buoyancy forces related to thickness variations in the lithosphere during rift localization play a significant role and control the initiation of rift‐parallel faults. (3) During the final stages of extension, in model B the crust is deformed by rift‐parallel faults, while in the basins the small‐scale deformation pattern is composed of displacement‐normal faults. However, in model A, displacement‐normal faults tend to accommodate most of the extension, controlling its final stages. They probably also control the formation of the ocean‐continent transition, any possible mantle exhumation, as well as the geometry of oceanic accretion centers. These results provide an insight into the possible evolution of the Gulf of Aden conjugate margins, which developed in an oblique context and most probably without any preexisting rift‐parallel localizing heterogeneity in the lithosphere.