Seismic tomography reveals a mid-crustal intrusive body, fluid pathways and their relation to the earthquake swarms in West Bohemia/Vogtland

Mousavi, Sima; Bauer, Klaus; Korn, M.; Hejrani, Babak

doi:10.1093/gji/ggv338

Cited by 29 publications

(27 citation statements)

References 62 publications

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“…13), got crystallized and by decompression/differentiation formed the rhyolite and granophyric like rocks as reported in the region (Sethna, 2003). Similar to our observation, the presence of mid-crustal solidified intrusive body (higher Vp and higher Vp/Vs) below the earthquake swarm focal zone has earlier been reported for a non-volcanic regions (e.g., Kato et al, 2010;Mousavi et al, 2015) as well as volcanic region (e.g., Chiarabba and Moretti, 2006;Patanè et al, 2003). We consider the imaged crystallized mafic magma as a pronounced heterogeneity within the crust; and by reducing the crustal strength it provides a locale for the stress accumulation at its contact (McGinnis and Ervin, 1974).…”

Section: Results and Interpretationsupporting

confidence: 92%

“…Further, the seismic swarm-like earthquake activity at shallower depths may be due to the feeding of the crustal fluid, which was released from the mapped crystallized magma (Mousavi et al, 2015). The observed lower b-value (0.67, Rastogi et al, 2013) of the seismic swarm-like earthquake activity in this intraplate setting also indicates the possibility of increase in the pore pressure, possibly due to crustal fluids.…”

Section: Results and Interpretationmentioning

confidence: 80%

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The role of crystallized magma and crustal fluids in intraplate seismic activity in Talala region (Saurashtra), Western India: An insight from local earthquake tomography

Mahesh

Gupta

2016

Tectonophysics

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Section: Results and Interpretationsupporting

confidence: 92%

Section: Results and Interpretationmentioning

confidence: 80%

The role of crystallized magma and crustal fluids in intraplate seismic activity in Talala region (Saurashtra), Western India: An insight from local earthquake tomography

Mahesh

Gupta

2016

Tectonophysics

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“…Theoretically, the accuracy of the V S model from arrival time inversion is lower than that of the V P model, due to the lower accuracy of S wave phase picking. Therefore, the velocity ratio V P / V S is generally not determined by division of the inverted P and S velocities; instead, it is acquired from a simultaneous inversion for V P and V P / V S (Thurber, 1993; Thurber and Eberhart‐Phillips, 1999; Mousavi et al, 2015). Nevertheless, if the resolutions of P and S are almost the same and the scale of spatial inhomogeneity of the velocity structure is much greater than the wavelength, division of V p by V S can to some extent describe the true velocity ratio (Nakajima et al, 2001).…”

Section: Results and Analysismentioning

confidence: 99%

Three dimensional velocity structure and accurate earthquake location in Changning–Gongxian area of southeast Sichuan

Feng

Zhang

et al. 2020

Earth and Planetary Physics

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In order to understand the crustal structure and tectonic background of the Changning–Gongxiang area, southeastern Sichuan Province, where a series of moderate‐to‐strong earthquakes occurred in recent years, we utilized the seismic phase data both from a local dense array and from the regional seismic networks; we used the tomoDD program to invert for the high‐resolution three‐dimensional velocity structure within the depth range of 0–10 km and for accurate hypocentral locations in this area. We analyzed the seismogenic structures for the events of XingwenM5.7 in 2018 and Gongxian M5.3 and Changning M6.0 in 2019. The results show that: (1) widespread lateral inhomogeneity exists in the velocity structure of the study area, and the location of the velocity anomaly is largely consistent with known structures. In the range of distinguishable depth, the inhomogeneity decreases with increasing depth, and the velocity structure anomalies in some areas are continuous in depth; (2) earthquakes occurred in clusters, showing the characteristics of zonal folding trends in the NW‐SE and NE‐SW directions; the focal depth in the area is generally shallow in both the sedimentary cap and the crystalline basement. The seismogenic structures of small earthquake clusters are different in size and occurrence in different sections, and the clusters occurred mostly in regions with high P‐ or S‐wave velocities; (3) synthesis of a variety of data suggests that the seismogenic structures of the Xingwen M5.7 and Changning M6.0 earthquakes are associated with slip faults that trend NW‐SE in, respectively, the south wing and the axis of the Changning–Shuanghe anticline, while that of the GongxianM5.3 earthquake is associated with thrust faults that trend N‐S in the Jianwu syncline region. The dynamic sources of the three earthquakes are all from the SE pushing of the Qinghai–Tibet block on the Sichuan basin; (4) the risk of future strong earthquakes in this area must be reevaluated in light of the facts (a) that in recent years, moderate‐to‐strong earthquake swarms have occurred frequently in southeast Sichuan; (b) that the complex structural area exhibits the easy‐to‐trigger characteristic, and (c) that the small‐scale faults in this area are characterized by the phenomenon of stress “lock and release”.

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“…Mousavi et al . () performed seismic travel‐time tomography of the larger NW Bohemia/Vogtland region. An area of increased P‐ to S‐velocity ratio, pointing to low S‐velocity, is visible south (and partly also north) of the main hypocentral zone, stretching from the hypocentral depth to the surface.…”

Section: Seismicity Of the Regionmentioning

confidence: 99%

“…In spite of these observations, the relation between movements of fluids, CO 2 emissions, and earthquake swarms in the Cheb Basin is not yet fully understood, as the Nový Kostel epicentral zone is situated 10 km north from the main degassing area near Hartoušov. Mousavi et al (2015) performed seismic travel-time tomography of the larger NW Bohemia/Vogtland region. An area of increased P-to S-velocity ratio, pointing to low S-velocity, is visible south (and partly also north) of the main hypocentral zone, stretching from the hypocentral depth to the surface.…”

Section: Geological Framementioning

confidence: 99%

Locating mofettes using seismic noise records from small dense arrays and matched field processing analysis in the NW Bohemia/Vogtland Region, Czech Republic

Estrella

Umlauft

Schmidt

et al. 2016

Near Surface Geophysics

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The NW Bohemia/Vogtland region is characterized by currently ongoing geodynamic processes within the intracontinental lithospheric mantle. Among others, this activity results in the occurrence of mid‐crustal earthquake swarms and CO2 degassing zones called mofettes. These two natural phenomena are related to each other since it is considered that fluid flow and fluid‐induced effective stress can trigger earthquake swarms. At the Earth’s surface, they appear spatially separated, but their connection could be explained by the existence of pathways within the crust that allow efficient and permanent fluid transport. However, neither the structure nor the position of such pathways has been imaged yet. With this background, we used a matched field processing analysis within the NW Bohemia/Vogtland region to locate mofettes and investigate their characteristics. Considering the CO2 degassing process as a high‐frequency noise source, we chose two different test sites: the Dolní Částkov Borehole, which is an artificial mofette that we used to validate the method, and the South Hartoušov mofette field, a natural CO2 degassing area. On both sites, we measured seismic noise in a continuous mode for several hours (7 hours to 9 hours), with a sampling frequency of 250 samples/second, in multiple campaigns using an array of about 60 × 60 m2 with approximately 30 randomly distributed stations. For the matched field processing computation, the phase velocity c(▯) of the study area is required, which we obtained from active seismic experiments with vertical hammer‐blow as the source. The phase velocity varies between 200 m/s and 420 m/s for Dolní Částkov and between 100 m/s and 280 m/s for South Hartoušov, both in a frequency range of 7 Hz–60 Hz. With the matched field processing analysis at the artificial mofette in Dolní Částkov, we could relocate the noise source successfully. In the South Hartoušov mofette field, we detected one dominant vertically extended noise source, probably a fluid pathway, as well as a small matched field processing maxima at the surface that can be related to a dry mofette.

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Seismic tomography reveals a mid-crustal intrusive body, fluid pathways and their relation to the earthquake swarms in West Bohemia/Vogtland

Cited by 29 publications

References 62 publications

The role of crystallized magma and crustal fluids in intraplate seismic activity in Talala region (Saurashtra), Western India: An insight from local earthquake tomography

The role of crystallized magma and crustal fluids in intraplate seismic activity in Talala region (Saurashtra), Western India: An insight from local earthquake tomography

Three dimensional velocity structure and accurate earthquake location in Changning–Gongxian area of southeast Sichuan

Locating mofettes using seismic noise records from small dense arrays and matched field processing analysis in the NW Bohemia/Vogtland Region, Czech Republic

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