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Simultaneous Inversion for 3D crustal Structure and regional Hypocenters beneath Germany in the Presence of an anisotropic upper Mantle
Thomas Willi Münch, Manfred Koch and Jörg Schlittenhardt
IntroductionAs recognized in previous studies (Song et al., 2001, 2004), travel times of Pn-phases across Germany show anisotropic behaviour. Main task here is to study the influence of the upper mantle anisotropy onto the tomographic reconstruction of the seismic velocities in the crust and upper mantle across Germany.
Dataset for the 3D SSH (Simultaneous inversion for Structure and Hypocenters, (Koch, 1993)) tomography consists of regional arrival times recorded across Germany between 1975 to 2003. Due to the large number of records (Table 1), good ray-coverage of study area is ensured (Fig. 1).
751873895PMP-Phases
5880900112804Pn-Phases
154382027946550Pg-Phases
1223181210058Events
N-obs >7, GAP <180N-obs > 7Total
Fig, 1: Regional seismic events and ray-coverage (P + S- phases) across Germany.
Anisotropy, preliminary investigations
Fig. 4: Determination of optimal anisotropy ellipse. For hypocenters fixed (Fig.4a) the optimal anisotropy angle of about 35°NE is obtained. For full inversion (Fig.4b) optimal angle is at 26°NE coinciding better with results of Enderle et al. (1999).
One aim of the study is to show influence of upper mantle Pn-anisotropy on the seismic inversion. Therefore, Pn- ray tracing is corrected by elliptical (azimuthal) anisotropy, quantified by the velocity contrast (%) and angle of the major axis (Fig.2)
Fig. 3: Original Pn residuals (blue) and optimally anisotropically corrected.
Fig. 3: Effects of anisotropic Pn-correction on the observed travel-time residuals (using a standard 1D- seismic velocity model for Germany). After anisotropic correction with -+2.5% contrast, the residuals nearly lie on a straight line.
Fig. 3:Anisotropicall corrected with +-1% (top) and with +-5% (bottom)
3D-seismic Models, synthetic Tests
Synthetic tests with random lateral velocity anomalies
An artificial anisotropic traveltime dataset with several anomalies in the four layers (depths=[0-10];[10-20];[20-30]; >30km) of the model (Fig. 5a) is synthesized and re-inverted. The traveltimes are computed using the original hypocenter locations and station records and putting arbitrary velocity anomalies as shown in Fig. 3a into the model.
The reconstructed anisotropic models are shown in Fig. 3b and 3d, respectively, without and with traveltime noise (σσσσ = 0.1s) included. Fig. 3c shows the isotropic inversion.
The anisotropic (Fig. 5b, Fig. 5d) reconstruction shows a good agreement with the original model (except in layer 3) due to the lack of earthquakes. The RMS of the data fit is also smaller than that of the isotropic reconstructed.
The isotropic (Fig. 5c) reconstruction has no resolution in the 1st
layer, produces only artefacts in the three next layers and has a three times higher RMS.
Figure 3d: anisotropically inverted modelwith noisy data, RMS = 0.1656 s
Figure 3a: Original model with random lateral pertubations
Figure 3b: anisotropically inverted modelRMS = 0.0771 s
Figure 3c: isotropically inverted model RMS = 0.2324 s
Figure 6c: Inversion with 35x35 blocs, RMS = 0.1593 s
Figure 6b: Inversion with 25x25 blocs, sigma = 0.1 s, RMS = 0.2069 s
Figure 6a: Inversion with 25x25 blocs, RMS = 0.1435 s
The checkerboard tests show where a good lateral resolution can be expected, reflecting the inhomo-geneous ray-coverage of the model area. Even with noisy data (Fig. 6b) a good resolution in the first and fourth layer for the 25x25 bloc models is obtained. For the second and third layer at a depth range between 10 and 30 km, good resolution is obtained only in the south-western part of the model. The other areas suffer from lack of seismic events and rays.Fig. 6c shows how the resolved areas are reduced when a 35x35 bloc discretization is used.
3D-seismic Models, Checkerboard-Tests
Fig. 7b: Anisotropic 25x25 model; TSS = 15113 s², RMS = 0.8197 s
Fig. 7a: Isotropic 25x25 3D mode
TSS = 17458 s², RMS = 0.8810 s
Fig.8a: Isotropic 35x35 model; TSS = 16995 s², RMS = 0.8693 s Fig. 8b: Anisotropic 35x35 model; TSS = 15767 s², RMS = 0.8373 s
The four 3D-tomographic seismic models for the crust and upper mantle exhibit slightly different features, mainly in the upper mantle layer. Based on the objective criteria of the Total Square Sum of the residuals (TSS) and the synthetic tests, the anisotropic models are considered to be more reliable.
25x25 bloc models (Fig. 7)The first layer nearly has the same structure for both model variants, although major shallow geological features (Rhinegraben area, Vogelsberg and NördlingerRies) are better recognized in the anisotropic model.
Starting with the second layer, structural differences show up between isotropic and anisotropic models
Structure in the fourth layer mainly follows some tectonic features in the tectonic map (Fig. 9), i.e. may represent ancient suture zones of the variscan orogeny.
35x35 bloc models (Fig. 8)Compared with the 25x25 models, datafit is improved. But resolution in some areas of the model is nottrustable, as shown by the checkerboard tests. Never-theless major structurural features are similar to thecoarser model.
Fig. 9: Tectonic map of Germany with major ancient suture zones
V. Simultaneously relocated hypocenters
Simultaneously with the isotropicand anisotropic optimal 3D velocitymodels relocated hypocenters showonly minor differences.
Isotropically computed epicenters(Fig. 9, left) appear to be moreclustered in the EW- direction (effectof anisotropic bias??) thananisotropically computed ones.
No visual differences in the depthshifts of the events.
Fig. 9: Epicentral and hypocentral (depth) shifts for simultaneously with 3D 25x25 optimal velocity models relocated events (left: isoptropic; right: anisotropic model
Table 2: Average shifts of epicenters and for different model variants; x= x-shift , y=y-shift; r = total horizontal shift; Φ=angle of shift.