Continental rifting at magmatic centres: structural implications from the Late Quaternary Menengai Caldera, central Kenya Rift

Riedl, Simon; Melnick, Daniel; Mibei, Geoffrey; Njue, Lucy Muthoni; Strecker, Manfred R.

doi:10.1144/jgs2019-021

Cited by 15 publications

(11 citation statements)

References 122 publications

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“…It has, however, been suggested that due to the alternating layers of volcanics and sedimentary strata of the intrarift units of the NKR, such steep dip estimates from purely volcanic settings cannot be transferred to the NKR (Le Gall et al., 2000). At the surface, extensional fractures are suggested to partly accommodate the near‐surface extension at subvertical fault scarps (e.g., Acocella et al., 2003; Corti, 2009), and such extensional fractures are very common in the Kenya Rift (e.g., Atmaoui & Hollnack, 2003; Muirhead et al., 2016; Riedl et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

Mid‐Pleistocene to Recent Crustal Extension in the Inner Graben of the Northern Kenya Rift

Riedl

Melnick

Njue³

et al. 2022

Geochem Geophys Geosyst

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Magmatic continental rifts often constitute nascent plate boundaries, yet long‐term extension rates and transient rate changes associated with these early stages of continental breakup remain difficult to determine. Here, we derive a time‐averaged minimum extension rate for the inner graben of the Northern Kenya Rift (NKR) of the East African Rift System for the last 0.5 m.y. We use the TanDEM‐X science digital elevation model to evaluate fault‐scarp geometries and determine fault throws across the volcano‐tectonic axis of the inner graben of the NKR. Along rift‐perpendicular profiles, amounts of cumulative extension are determined, and by integrating four new 40Ar/39Ar radiometric dates for the Silali volcano into the existing geochronology of the faulted volcanic units, time‐averaged extension rates are calculated. This study reveals that in the inner graben of the NKR, the long‐term extension rate based on mid‐Pleistocene to recent brittle deformation has minimum values of 1.0–1.6 mm yr−1, locally with values up to 2.0 mm yr−1. A comparison with the decadal, geodetically determined extension rate reveals that at least 65% of the extension must be accommodated within a narrow, 20‐km‐wide zone of the inner rift. In light of virtually inactive border faults of the NKR, we show that extension is focused in the region of the active volcano‐tectonic axis in the inner graben, thus highlighting the maturing of continental rifting in the NKR.

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Section: Discussionmentioning

confidence: 99%

Mid‐Pleistocene to Recent Crustal Extension in the Inner Graben of the Northern Kenya Rift

Riedl

Melnick

Njue³

et al. 2022

Geochem Geophys Geosyst

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“…We applied classical techniques in tectonic geomorphology summarized in seminal textbooks [45][46][47] for mapping newly-identified faults and remapping structures from previous studies at a uniform 1:25,000 scale. We rely on our past experience in mapping active faults in different tectonic environments using field observations and remote sensing data 16,[48][49][50][51][52][53][54][55][56] , in addition to the criteria used in previous active fault databases [57][58][59][60][61] . We paid special attention to interpreting fault trace continuity using a uniform mapping scale based on the surface expression of faults, not the inferred seismogenic expression at depth.…”

Section: Methodsmentioning

confidence: 99%

“…Further applications have been, for example, assessing anthropogenic factors in triggered and induced seismicity 12 such as stress changes to the crust caused by hydroelectric reservoirs, underground gas storage, groundwater pumping, or fracking 13 , 14 . Many geothermal fields occur in tectonically-active regions and maps of active faults have been used both for exploration and selection of drilling sites 15 , 16 as well as for reservoir modelling during exploitation 17 , 18 . Active fault databases have been also used in studies of volcanotectonic interactions and structural control on volcanism in rifts 19 and arcs 20 , in the interpretation of present-day stress indicators 21 , 22 as well as to infer sources of pre-instrumental earthquakes 23 and the response of groundwater to near and farfield earthquakes 24 .…”

Section: Background and Summarymentioning

confidence: 99%

A comprehensive database of active and potentially-active continental faults in Chile at 1:25,000 scale

2021

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In seismically-active regions, mapping active and potentially-active faults is the first step to assess seismic hazards and site selection for paleoseismic studies that will estimate recurrence rates. Here, we present a comprehensive database of active and potentially-active continental faults in Chile based on existing studies and new mapping at 1:25,000 scale using geologic and geomorphic criteria and digital elevation models derived from TanDEM-X and LiDAR data. The database includes 958 fault strands grouped into 17 fault systems and classified based on activity (81 proved, 589 probable, 288 possible). The database is a contribution to the world compilation of active faults with applications among others in seismic hazard assessments, territorial planning, paleoseismology, geodynamics, landscape evolution processes, geothermal exploration, and in the study of feedbacks between continental deformation and the plate-boundary seismic cycle along subduction zones.

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“…As such, Quaternary volcano‐sedimentary units are areally restricted to the inner graben, which has been the focus of densely spaced normal faulting that has resulted in a horst‐and‐graben landscape (Hackman, 1988; McCall, 1967; Thompson & Dodson, 1963). Furthermore, the inner graben has been characterized by volcanic, seismic, and hydrothermal activity during the last 2 Ma (Clarke et al., 1990; Riedl et al., 2020; Tongue et al., 1992).…”

Section: Geological Backgroundmentioning

confidence: 99%

Controls on Asymmetric Rift Dynamics: Numerical Modeling of Strain Localization and Fault Evolution in the Kenya Rift

et al. 2021

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Asymmetric rifting, which is characterized by a dominant single border fault, is known to have played a major role in the evolution of many past rift systems (e.g., Schlische et al., 2003;Withjack et al., 2013). It can also be observed in many presently active extensional tectonic settings (e.g., Gawthorpe & Leeder, 2008;Ebinger & Scholz, 2011), where it governs basin geometry, topography evolution, erosion, and sedimentation patterns. One such setting is the largest continental rift system in existence today: the East African Rift System (EARS). It exhibits a wide array of developmental stages from youthful extension with incipient faulting to final continental breakup (Corti, 2009;Ebinger & Scholz, 2011;Ring, 2014) and is thus an ideal location for studying the stages of early rifting that involve asymmetric normal fault activity followed by hanging-wall segmentation. In this study, we focus on the southern and central sectors of the Kenya Rift, which are in an early phase of active continental rifting (Ebinger et al., 2017) characterized by the transition from waning border fault activity to enhanced intra-basinal faulting and subsidence (Muirhead et al., 2016).The first-order tectonic characteristics of continental rifts are known to be influenced by a large range of structural, petrological, and thermal parameters, which have been investigated in previous numerical modeling studies (e.g.,

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Continental rifting at magmatic centres: structural implications from the Late Quaternary Menengai Caldera, central Kenya Rift

Cited by 15 publications

References 122 publications

Mid‐Pleistocene to Recent Crustal Extension in the Inner Graben of the Northern Kenya Rift

Mid‐Pleistocene to Recent Crustal Extension in the Inner Graben of the Northern Kenya Rift

A comprehensive database of active and potentially-active continental faults in Chile at 1:25,000 scale

Controls on Asymmetric Rift Dynamics: Numerical Modeling of Strain Localization and Fault Evolution in the Kenya Rift

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