EGU2020-7916, updated on 20 Oct 2023
https://doi.org/10.5194/egusphere-egu2020-7916
EGU General Assembly 2020
© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Shear-Wave Velocity Model of the Bohemian Massif Crust from Ambient Noise Tomography

Jiří Kvapil1, Jaroslava Plomerová1, Vladislav Babuška1, Hana Kampfová Exnerová1, Luděk Vecsey1, AlpArray-EASI Working Group2, and AlpArray Working Group2
Jiří Kvapil et al.
  • 1Institute of Geophysics, Czech Academy of Sciences, Prague (j.kvapil@ig.cas.cz)
  • 2http://www.alparray.ethz.ch/

The current knowledge of the structure of the Bohemian Massif (BM) crust is mostly based on interpretation of refraction and reflection seismic experiments performed along 2D profiles. The recent development of ambient noise tomography, in combination with dense networks of permanent seismic stations and arrays of passive seismic experiments, provides unique opportunity to build the high-resolution 3D velocity model of the BM crust from long sequences of ambient seismic noise data.

The new 3D shear-wave velocity model is built from surface-wave group-velocity dispersion measurements derived from ambient seismic noise cross-correlations by conventional two-step inversion approach. First, the 2D fast marching travel time tomography is applied to regularise velocity dispersions. Second, the stochastic inversion is applied to compute 1D shear-wave velocity profiles beneath each location of the processing grid.

We processed continuous waveform data from 404 seismic stations (permanent and temporary stations of passive experiments BOHEMA I-IV, PASSEQ, EGER RIFT, ALPARRAY-EASI and ALPARRAY-AASN) in a broader region of the BM (in an area of 46-540 N 7-210 E). The overlapping period of each possible station-pair and cross-correlation quality review resulted in more than 21,000 dispersion curves, which further served as an input for surface-wave inversion at high-density grid with the cell size of 22 km.

We present the new high-resolution 3D shear-wave velocity model of the BM crust and uppermost mantle with preliminary tectonic interpretations. We compare this model with a compiled P-wave velocity model from the 2D seismic refraction and wide-angle reflection experiments and with the crustal thickness (Moho depth) extracted from P-wave receiver functions (see Kampfová Exnerová et al., EGU2020_SM4.3). 1D velocity profiles resulting from the stochastic inversions exhibit regional variations, which are characteristic for individual units of the BM. Velocities within the upper crust of the BM are ~0.2 km/s higher than those in its surroundings. The highest crustal velocities occur in its southern part (Moldanubian unit). The velocity model confirms, in accord with results from receiver functions and other seismic studies, a relatively thin crust in the Saxothuringian unit, whilst thickness of the Moldanubian crust is at least 36 km in its central and southern parts. The most distinct interface with a velocity inversion at the depth of about 20 to 25 km occurs in the Moldanubian unit. The velocity decrease in the lower crust reflects probably its transversely isotropic structure.

How to cite: Kvapil, J., Plomerová, J., Babuška, V., Kampfová Exnerová, H., Vecsey, L., Working Group, A.-E., and Working Group, A.: Shear-Wave Velocity Model of the Bohemian Massif Crust from Ambient Noise Tomography, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-7916, https://doi.org/10.5194/egusphere-egu2020-7916, 2020.

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