Tomographic images of the Iberian subcrustal lithosphère and asthenosphere

Corchete, V.; Badal, José; Serón, Francisco J.; Soria, Ana Rosa

doi:10.1029/95jb00979

Cited by 29 publications

(26 citation statements)

References 23 publications

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“…The surface waves observed on records of earthquakes are predominantly fundamental mode Rayleigh-and Love-waves and their group velocities along their respective great-circle propagation paths are mainly controlled by variations in the velocity structure of the crust and mantle. Therefore, in view of the dispersive character of the elastic medium, a detailed group velocity dispersion analysis of the waves recorded from earthquakes leads to a good resolution for depth-layered properties, and may be of great interest for the determination of regional seismic velocity structure and exploration of the contrasting geology between neighbouring geological formations (CORCHETE et al, 1995;BADAL et al, 1996;BONNER and HERRIN, 1999;MARTÍNEZ et al, 2000;FREDERIKSEN et al, 2001;MISHRA et al, 2005;MITRA et al, 2006). Surface wave velocity tomography (YANOVSKAYA et al, 2000;HUANG et al, 2003;YANOVSKAYA and KOZHEVNIKOV, 2003) is a useful tool for this purpose and for monitoring nuclear explosions with discriminants (PASYANOS and WALTER, 2001).…”

Section: Introductionmentioning

confidence: 99%

Love and Rayleigh Wave Tomography of the Qinghai-Tibet Plateau and Surrounding Areas

Chen

Badal

2009

Pure Appl. Geophys.

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Surface wave data were initially collected from events of magnitude Ms C 5.0 and shallow or moderate focal depth occurred between 1980 and 2002: 713 of them generated Rayleigh waves and 660 Love waves, which were recorded by 13 broadband digital stations in Eurasia and India. Up to 1,525 source-station Rayleigh waveforms and 1,464 Love wave trains have been processed by frequency-time analysis to obtain group velocities. After inverting the path-averaged group times by means of a damped least-squares approach, we have retrieved location-dependent group velocities on a 2°9 2°-sized grid and constructed Rayleighand Love-wave group velocity maps at periods 10.4-105.0 s. Resolution and covariance matrices and the rms group velocity misfit have been computed in order to check the quality of the results. Afterwards, depth-dependent SV-and SH-wave velocity models of the crust and upper mantle are obtained by inversion of local Rayleigh-and Love-wave group velocities using a differential damped least-squares method. The results provide: (a) Rayleighand Love-wave group velocities at various periods; (b) SV-and SH-wave differential velocity maps at different depths; (c) sharp images of the subducted lithosphere by velocity cross sections along prefixed profiles; (d) regionalized dispersion curves and velocity-depth models related to the main geological formations. The lithospheric root presents a depth that can be substantiated at *140 km (Qiangtang Block) and exceptionally at *180 km in some places (Lhasa Block), and which exhibits laterally varying fast velocity very close to that of some shields that even reaches *4.8 km/s under the northern Lhasa Block and the Qiangtang Block. Slow-velocity anomalies of 7-10% or more beneath southern Tibet and the eastern edge of the Plateau support the idea of a mechanically weak middle-to-lower crust and the existence of crustal flow in Tibet.

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Section: Introductionmentioning

confidence: 99%

Love and Rayleigh Wave Tomography of the Qinghai-Tibet Plateau and Surrounding Areas

Chen

Badal

2009

Pure Appl. Geophys.

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“…The deployment during 1988 -1989 of the broadband NARS stations as part of the ILIHA experiment [Paulssen, 1990] provided a significant impulse to surface wave studies in the Iberian Peninsula. Using two-station dispersion measurements, Corchete et al [1995] obtained shearwave images of the lithosphere and asthenosphere beneath the Iberian Peninsula. The shallow structure has also been studied using short period (1 -6 seconds) Rg Rayleigh waves from small earthquakes and explosions for different regions of Iberia (e.g., Chourak et al [2005] for the Betics).…”

Section: Introductionmentioning

confidence: 99%

Ambient noise surface wave tomography of the Iberian Peninsula: Implications for shallow seismic structure

Villaseñor¹,

Yang²,

Ritzwoller³

et al. 2007

Geophysical Research Letters

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We have obtained high resolution group velocity maps of Rayleigh waves at periods from 8 to 25 seconds across the Iberian Peninsula by cross‐correlating four months of ambient noise data recorded by 40 permanent broadband stations. Group velocity maps accurately image the main structural elements of the Iberian upper crust, including the Iberian Massif, Alpine orogens and major sedimentary basins. The Pyrenees and the Iberian Chain are imaged as relatively high group velocities, in contrast with the Betic Cordillera, which is characterized by low velocities. We explain these low velocities in the Betics by the presence of widespread intramontane basins created in an extensional episode simultaneous with north–south convergence between the African and Eurasian plates. The most prominent low velocity anomalies in the Iberian Peninsula are related to the Guadalquivir Basin, the flysch units of the Campo de Gibraltar, and the sediments of the Gulf of Cadiz.

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“…Previous studies, which cover all Iberian area also performed with longperiod Rayleigh waves, never attained a minimum depth less than 24 km (Badal et al 1990(Badal et al , 1992. Nevertheless, further studies performed also with Rayleigh waves in the Iberian area, attained to increase the maximum depth of the S-wave velocity models down to 200 km (Corchete et al 1995;Badal et al 1996). On the other hand, several S-wave velocity models of the Iberian area have been obtained for shallow depths (from 0 to 4 or 5 km of depth) from shortperiod Rayleigh waves (Sarrate et al 1993;Navarro et al 1997;Chourak et al 2003).…”

Section: Introductionmentioning

confidence: 88%

Shear-wave velocity structure of the south-eastern part of the Iberian Peninsula from Rayleigh wave analysis

Corchete

Chourak²

2010

Int J Earth Sci (Geol Rundsch)

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In this study, we present the lithospheric structure of the south-eastern part of the Iberian Peninsula by means of a set of 2D images of shear velocity, for depths ranging from 0 to 50 km. This goal will be attained by means of the inversion of the Rayleigh wave dispersion. For it, the traces of 25 earthquakes occurred on the neighbouring of the study area, from 2001 to 2003, will be considered. These earthquakes have been registered by 11 broadband stations located on Iberia. All seismic events have been grouped in source zones to get an average dispersion curve for each source-station path. The dispersion curves have been measured for periods between 2 and 45 s, by combination of two digital filtering techniques: Multiple Filter Technique and Time Variable Filtering. The resulting set of source-station averaged dispersion curves has been inverted according to the generalized inversion theory, to get S-wave velocity models for each source-station path. Later, these models have been interpolated using the method of kriging, to obtain a 2D mapping of the S-wave velocity structure for the south-eastern part of Iberia. The results presented in this paper show that the techniques used here are a powerful tool to investigate the crust and upper mantle structure, through the dispersion analysis and its inversion to obtain shear velocity distributions with depth. By means of this analysis, principal structural features of the south-eastern part of Iberia, such as the existence of lateral and vertical heterogeneity in the whole study area, or the location of the Moho discontinuity at 30 km of depth (with an average S-velocity of uppermost mantle of 4.7 km/s), have been revealed. Other important structural features revealed by this analysis have been that the uppermost of Iberian massif shows higher velocity values than the uppermost of the Alpine domain, indicating that the massif is old and tectonically stable. The average velocity of the crust in Betic cordillera is of 3.5 km/s, while in the Iberian massif is 3.7 km/s. All these features are in agreement with the geology and other previous geophysical studies.

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Tomographic images of the Iberian subcrustal lithosphère and asthenosphere

Cited by 29 publications

References 23 publications

Love and Rayleigh Wave Tomography of the Qinghai-Tibet Plateau and Surrounding Areas

Love and Rayleigh Wave Tomography of the Qinghai-Tibet Plateau and Surrounding Areas

Ambient noise surface wave tomography of the Iberian Peninsula: Implications for shallow seismic structure

Shear-wave velocity structure of the south-eastern part of the Iberian Peninsula from Rayleigh wave analysis

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