Local Earthquake Magnitude Scale and<i>b</i>‐Value for the Danakil Region of Northern Afar

Illsley‐Kemp, Finnigan; Keir, Derek; Bull, Jonathan M.; Ayele, Atalay; Hammond, James; Kendall, J.‐M.; Gallacher, R. J.; Gernon, Thomas M.; Goitom, Berhe

doi:10.1785/0120150253

Cited by 36 publications

(29 citation statements)

References 73 publications

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“…This distribution in seismicity implies that faulting in the Danakil Depression accommodates a larger proportion of extension than elsewhere in Afar. Additionally, local seismicity recorded in the Danakil during 2011-2013 shows that the in-rift fault system near Dallol is seismically active (Illsley-Kemp et al, 2017), consistent with the view that the role of magmatism in achieving extension here is reduced. To facilitate mechanical upper crustal extension and rapid basin subsidence, it is likely that contemporaneous ductile stretching of the lower crust and mantle lithosphere has occurred; this would explain the marked thinning of the crust in Danakil (~15 km) compared to elsewhere in Afar (~25 km; (Eagles et al, 2002).…”

Section: Formation Of the Danakil Depressionsupporting

confidence: 72%

The Development of Late‐Stage Continental Breakup: Seismic Reflection and Borehole Evidence from the Danakil Depression, Ethiopia

et al. 2018

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During continental breakup, the locus of strain shifts from a broad region of border faulting and ductile plate stretching to a narrow zone of magma intrusion in a young ocean basin. Recent studies of volcanic rifts and margins worldwide suggest this shift occurs subaerially, before the onset of seafloor spreading. We test this hypothesis using recently acquired seismic reflection and borehole data from the Danakil Depression, Ethiopia, a unique region of transition between continental rifting and seafloor spreading. Our data, located near Dallol, ~30 km northwest of the Erta'Ale Volcanic Segment, reveal a remarkably thick (>1‐km) sequence of young (~100‐ka) evaporites in a basin bound by a major (≤400‐m‐throw), east‐dipping normal fault. To generate such a large amount of subsidence in such a relatively short time, we propose that upper‐crustal extension in Danakil is currently dominated by faulting, not magmatic intrusion. Given the region's markedly thinned crust (~15‐km‐thick), relative to elsewhere in Afar where magma‐assisted rifting dominates and maintains crustal thickness at ~25 km, mechanical extension in Danakil is likely coupled with ductile extension of the lower‐crust and mantle lithosphere. Despite proximity to the voluminous lavas of the active Erta'Ale Volcanic Segment, evidence for igneous material in the upper ~2 km of the 6‐ to 10‐km‐wide basin is limited. Late‐stage stretching was likely aided by thermal/strain‐induced lithospheric weakening following protracted magma‐assisted rifting. Basin formation immediately prior to the onset of seafloor spreading may also explain the accumulation of thick marine‐seepage‐fed evaporite sequences akin to those observed, for example, along the South Atlantic rifted margins.

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Section: Formation Of the Danakil Depressionsupporting

confidence: 72%

The Development of Late‐Stage Continental Breakup: Seismic Reflection and Borehole Evidence from the Danakil Depression, Ethiopia

et al. 2018

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“…The b ‐value of 0.87 ± 0.03 estimated for the Magadi‐Natron‐Manyara rift zone is identical to the b ‐value of 0.87 for the central Kenya rift [ Tongue et al ., ], and similar to the b ‐value of 0.84 for Tanzania, which includes the Archaean craton [ Langston et al ., ], and 0.9 for the intensely intruded and faulted Danakil Depression [ Illsley‐Kemp et al ., ] (supporting information Figure SM1). A large number of earthquakes occurred south of our array in the Manyara basin where Albaric et al .…”

Section: Resultsmentioning

confidence: 99%

“…[] estimate an unusually low b ‐value of 0.77 for a 7 month time period of observation in the Magadi basin, which included an intense swarm interpreted as a dike intrusion. Inclusion of events from the 1989 Magadi swarm may explain the apparent temporal variations between the two studies, as has been observed in other magmatically active zones [e.g., Wiemer et al ., ; Illsley‐Kemp et al ., ].…”

Section: Resultsmentioning

confidence: 99%

Fault‐magma interactions during early continental rifting: Seismicity of the Magadi‐Natron‐Manyara basins, Africa

Weinstein

Oliva

Ebinger

et al. 2017

Geochem Geophys Geosyst

100

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Although magmatism may occur during the earliest stages of continental rifting, its role in strain accommodation remains weakly constrained by largely 2‐D studies. We analyze seismicity data from a 13 month, 39‐station broadband seismic array to determine the role of magma intrusion on state‐of‐stress and strain localization, and their along‐strike variations. Precise earthquake locations using cluster analyses and a new 3‐D velocity model reveal lower crustal earthquakes beneath the central basins and along projections of steep border faults that degas CO2. Seismicity forms several disks interpreted as sills at 6–10 km below a monogenetic cone field. The sills overlie a lower crustal magma chamber that may feed eruptions at Oldoinyo Lengai volcano. After determining a new ML scaling relation, we determine a b‐value of 0.87 ± 0.03. Focal mechanisms for 65 earthquakes, and 13 from a catalogue prior to our array reveal an along‐axis stress rotation of ∼60° in the magmatically active zone. New and prior mechanisms show predominantly normal slip along steep nodal planes, with extension directions ∼N90°E north and south of an active volcanic chain consistent with geodetic data, and ∼N150°E in the volcanic chain. The stress rotation facilitates strain transfer from border fault systems, the locus of early‐stage deformation, to the zone of magma intrusion in the central rift. Our seismic, structural, and geochemistry results indicate that frequent lower crustal earthquakes are promoted by elevated pore pressures from volatile degassing along border faults, and hydraulic fracture around the margins of magma bodies. Results indicate that earthquakes are largely driven by stress state around inflating magma bodies.

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“…A total of 4,971 earthquakes of magnitude 0.4–5.8 was recorded during the experiment and was located with a 2‐D velocity model (Hammond et al, ; Lomax et al, ; Makris & Ginzburg, ). These earthquakes have average location errors of ±1.9 km and ±4.1 km in the horizontal and vertical directions, respectively, and the catalogue is complete above magnitude 2.0 (Illsley‐Kemp et al, ). Generally, earthquakes are focused at the western rift margin, which separates the Ethiopian plateau from the Afar depression, or in the vicinity of volcanic centers (Illsley‐Kemp et al, ; Figure ).…”

Section: Observational Methods and Resultsmentioning

confidence: 99%

Initiation of a Proto‐transform Fault Prior to Seafloor Spreading

Illsley‐Kemp

Bull

Keir

et al. 2018

Geochem Geophys Geosyst

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Transform faults are a fundamental tenet of plate tectonics, connecting offset extensional segments of mid‐ocean ridges in ocean basins worldwide. The current consensus is that oceanic transform faults initiate after the onset of seafloor spreading. However, this inference has been difficult to test given the lack of direct observations of transform fault formation. Here we integrate evidence from surface faults, geodetic measurements, local seismicity, and numerical modeling of the subaerial Afar continental rift and show that a proto‐transform fault is initiating during the final stages of continental breakup. This is the first direct observation of proto‐transform fault initiation in a continental rift and sheds unprecedented light on their formation mechanisms. We demonstrate that they can initiate during late‐stage continental rifting, earlier in the rifting cycle than previously thought. Future studies of volcanic rifted margins cannot assume that oceanic transform faults initiated after the onset of seafloor spreading.

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Local Earthquake Magnitude Scale andb‐Value for the Danakil Region of Northern Afar

Cited by 36 publications

References 73 publications

The Development of Late‐Stage Continental Breakup: Seismic Reflection and Borehole Evidence from the Danakil Depression, Ethiopia

The Development of Late‐Stage Continental Breakup: Seismic Reflection and Borehole Evidence from the Danakil Depression, Ethiopia

Fault‐magma interactions during early continental rifting: Seismicity of the Magadi‐Natron‐Manyara basins, Africa

Initiation of a Proto‐transform Fault Prior to Seafloor Spreading

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