B. Tadili scite author profile

We integrate observations based on teleseismic P wave travel times and available geologic data to infer that the lithosphere beneath the intraplate Atlas mountains is thin and/or it is characterized by lower P wave velocities, while beneath the interplate Rif mountains and the adjacent Alboran Sea a previously thickened lithosphere has been delaminated into the upper mantle. Using surface geology and geochronology data, previous studies have proposed that lithospheric delamination took place in this region. In this study we show through analysis of teleseismic P wave residuals the existence of a high‐velocity (>3%) upper mantle body, which is interpreted to be the delaminated, rigid lithosphere. This high‐velocity layer is overlain by a very low velocity uppermost mantle material (Pn velocities of about 7.6–7.7 km s−1) interpreted to be asthenospheric material replacing the delaminated lithosphere. Teleseismic P waves recorded by a recently installed digital seismic network and an older analog network in Morocco provide the residuals database. A total of 734 P wave residuals from 92 selected teleseismic earthquakes are used to document the spatial pattern of upper mantle velocity structure beneath northern Morocco and the Alboran Sea. Subsequent use of these residuals in a tomographic inversion scheme produced a three‐dimensional velocity image of the upper mantle. We infer from the P residuals that strong upper mantle velocity anomalies exist beneath both the Rif and Atlas regions. The Rif stations show negative residuals (∼1–1.5 s) for ray paths from the east and northeast and show positive residuals (∼1–1.5 s) for ray paths from the northwest and southwest. Tomographic results indicate the existence of a high‐velocity body (∼3% higher velocities) in the upper mantle beneath the eastern Rif and Alboran Sea, extending approximately from subcrustal depths down to a depth of at least 350 km. In the western Rif, however, 1–2% lower velocity material is imaged in the upper mantle. The residuals of the Atlas stations also show azimuthal variations. In general, most of the P waves that travel beneath the High and Middle Atlas have about 0.5–1.0 s delays. In contrast, the rays that travel beneath the northwestern margin of the Atlas mountains and the adjacent Moroccan Meseta area show negative residuals (∼1 s), suggesting that higher velocity material exists beneath the platform area adjacent to the Atlas mountains. Tomographic results indicate that beneath most of the Atlas system the uppermost mantle has about 1% lower velocities. Beneath the Alboran Sea region, however, reported low uppermost mantle Pn velocities contrast strongly with higher velocity upper mantle velocities obtained by our analysis. Low‐velocity uppermost mantle beneath the Alboran Sea underlain by a high‐velocity upper mantle material is used to support earlier interpretations of lithospheric delamination beneath the Rif and Alboran Sea regions. The enigmatic occurrence of subcrustal earthquakes in these regions is also consistent with this active...

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A Catalog of Main Moroccan Earthquakes from 1045 to 2005

Peláez

Chourak

Tadili

et al. 2007

Seismological Research Letters

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Duration Magnitude Scale and Site Residuals for Northern Morocco

Mouayn¹,

Tadili²,

Brahim³

et al. 2004

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Seismicity of Morocco for the Period 1987?1994

Alami

Tadili

Brahim

et al. 2004

Pure and Applied Geophysics

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A seismic data file of 3,740 earthquakes from January 1987 to December 1994 has been elaborated for Morocco and the border regions, with 10 main events registering magnitudes from 5 to 5.6. Such seismicity is particularly important for Morocco as the released seismic energy constitutes a considerable part of the total energy radiated during the 20th century. Relative seismicity maps confirm the persistence of the major features of the seismicity of Morocco. An important seismic activity is observed in the Alboran region continental crust, which absorbs the maximum deformation resulting from the convergence of the African and Iberian plates. However, in the longitude window 3.5°-6°W at depths of 25 to 50 km, a seismic gap zone seems to take place. An explanation of this phenomenon may be provided by the slab breakoff model. Even if the seismicity of Morocco remains moderate, heavy damage is observed when the magnitude of earthquakes exceeds 4.5, especially in the case of traditional buildings.

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Sn to Sg conversion and focusing along the Atlantic Margin, Morocco: Implications for earthquake hazard evaluation

Şeber

Barazangi

Tadili

et al. 1993

Geophysical Research Letters

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Digital data from a telemetered, short‐period seismic network in Morocco provide a new perspective for understanding the cause of severe shaking and macroseismic reports in Morocco produced by large, offshore earthquakes located along the Azores‐Gibraltar seismic zone. Even though the earthquake epicenters are 500–1000 km away from the Moroccan coast, historical records show that such events are capable of producing considerable damage in inland areas. We analyze 15 earthquakes that occurred in this region. The records show multiple S phases with varying frequencies and amplitudes. The S phase with the largest amplitude, usually misinterpreted as Sn, has a phase velocity of 4.2–4.4 km s−1. We show that these S arrivals can best be explained as Sn to Sg converted phases. Calculated locations of the conversion points for these phases exhibit two distinct zones almost parallel to the Atlantic coastline: one is located along the passive continental margin and the other is located about 100 km inland from the coastline. We interpret these two zones to be regions where a sudden change in crustal thickness occurs. Such zones act to focus and magnify the amplitudes of seismic phases. This interpretation explains the unusually strong felt reports within Morocco from such distant offshore events, and it has a significant effect on earthquake hazard evaluation and mitigation studies.

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B. Tadili

Three‐dimensional upper mantle structure beneath the intraplate Atlas and interplate Rif mountains of Morocco

A Catalog of Main Moroccan Earthquakes from 1045 to 2005

Duration Magnitude Scale and Site Residuals for Northern Morocco

Seismicity of Morocco for the Period 1987?1994

Sn to Sg conversion and focusing along the Atlantic Margin, Morocco: Implications for earthquake hazard evaluation

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