TY - JOUR A1 - Richter, Maximilian A1 - Brune, Sascha A1 - Riedl, Simon A1 - Glerum, Anne A1 - Neuharth, Derek A1 - Strecker, Manfred T1 - Controls on asymmetric rift dynamics BT - Numerical modeling of strain localization and fault evolution in the Kenya Rift JF - Tectonics / American Geophysical Union, AGU ; European Geophysical Society, EGS N2 - Complex, time-dependent, and asymmetric rift geometries are observed throughout the East African Rift System (EARS) and are well documented, for instance, in the Kenya Rift. To unravel asymmetric rifting processes in this region, we conduct 2D geodynamic models. We use the finite element software ASPECT employing visco-plastic rheologies, mesh-refinement, distributed random noise seeding, and a free surface. In contrast to many previous numerical modeling studies that aimed at understanding final rifted margin symmetry, we explicitly focus on initial rifting stages to assess geodynamic controls on strain localization and fault evolution. We thereby link to geological and geophysical observations from the Southern and Central Kenya Rift. Our models suggest a three-stage early rift evolution that dynamically bridges previously inferred fault-configuration phases of the eastern EARS branch: (1) accommodation of initial strain localization by a single border fault and flexure of the hanging-wall crust, (2) faulting in the hanging-wall and increasing upper-crustal faulting in the rift-basin center, and (3) loss of pronounced early stage asymmetry prior to basinward localization of deformation. This evolution may provide a template for understanding early extensional faulting in other branches of the East African Rift and in asymmetric rifts worldwide. By modifying the initial random noise distribution that approximates small-scale tectonic inheritance, we show that a spectrum of first-order fault configurations with variable symmetry can be produced in models with an otherwise identical setup. This approach sheds new light on along-strike rift variability controls in active asymmetric rifts and proximal rifted margins. KW - asymmetric rifting KW - rift variability KW - numerical model KW - structural KW - inheritance KW - Kenya Rift Y1 - 2021 U6 - https://doi.org/10.1029/2020TC006553 SN - 0278-7407 SN - 1944-9194 VL - 40 IS - 5 PB - American Geophysical Union CY - Washington ER - TY - JOUR A1 - Baes, Marzieh A1 - Sobolev, Stephan A1 - Gerya, Taras V. A1 - Brune, Sascha T1 - Plume-induced subduction initiation BT - single-slab or multi-slab subduction? JF - Geochemistry, geophysics, geosystems N2 - Initiation of subduction following the impingement of a hot buoyant mantle plume is one of the few scenarios that allow breaking the lithosphere and recycling a stagnant lid without requiring any preexisting weak zones. Here, we investigate factors controlling the number and shape of retreating subducting slabs formed by plume-lithosphere interaction. Using 3-D thermomechanical models we show that the deformation regime, which defines formation of single-slab or multi-slab subduction, depends on several parameters such as age of oceanic lithosphere, thickness of the crust and large-scale lithospheric extension rate. Our model results indicate that on present-day Earth multi-slab plume-induced subduction is initiated only if the oceanic lithosphere is relatively young (<30-40 Myr, but >10 Myr), and the crust has a typical thickness of 8 km. In turn, development of single-slab subduction is facilitated by older lithosphere and pre-imposed extensional stresses. In early Earth, plume-lithosphere interaction could have led to formation of either episodic short-lived circular subduction when the oceanic lithosphere was young or to multi-slab subduction when the lithosphere was old. KW - subduction zone KW - plume KW - numerical model KW - singleslab KW - multi-slab Y1 - 2020 U6 - https://doi.org/10.1029/2019GC008663 SN - 1525-2027 VL - 21 IS - 2 PB - American Geophysical Union CY - Washington ER -