Moho Beneath Tibet Based on a Joint Analysis of Gravity and Seismic Data

Moho Beneath Tibet Based on a Joint Analysis of Gravity and Seismic Data

We use the improved Parker‐Oldenburg's formulas that include a reference depth into the exponential term and employ the Gauss‐fast Fourier transform method to determine Moho depth beneath the Tibetan Plateau. The synthetic models demonstrate that the improved Parker's formula has high accu...

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Veröffentlicht in:Geochemistry, geophysics, geosystems : G3 geophysics, geosystems : G3, 2020-02, Vol.21 (2), p.n/a
Hauptverfasser: Zhao, Guangdong, Liu, Jianxin, Chen, Bo, Kaban, Mikhail.K., Zheng, Xuanyu
Format: Artikel
Sprache:eng
Schlagworte:
Depth
Fourier transforms
Geologic depressions
Gravitational fields
gravity anomalies
Gravity effects
Gravity field
Lithosphere
Moho
Parameters
Parker's formula
Plateaus
Plates
Seismic activity
Seismic data
Seismic tomography
Seismological data
Seismology
Tibetan Plateau
Tomography
Topographic effects
Uplift
Upper mantle
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Zusammenfassung:We use the improved Parker‐Oldenburg's formulas that include a reference depth into the exponential term and employ the Gauss‐fast Fourier transform method to determine Moho depth beneath the Tibetan Plateau. The synthetic models demonstrate that the improved Parker's formula has high accuracy with the maximum absolute error less than 0.25 mGal compared to the analytical solution. Two inversion parameters, that is, the reference depth and the density contrast, are essential for the Moho estimation based on the gravity field, and they need to be determined in advance to obtain correct results. Therefore, the Moho estimates derived from existing seismic studies are used to reduce the nonuniqueness of the gravity inversion and to determine these parameters by searching for the maximum correlation between the gravity‐inverted and seismic‐derived Moho depths. Another critical issue is to remove beforehand the gravity effects of other factors, which affect the observed gravity field besides Moho variations. In addition to the topography, the gravity effects of the sedimentary layer and crystalline crust are removed based on existing crustal models, while the upper mantle impact is determined based on the seismic tomography model. The inversion results show that the Moho structure under the Tibetan plateau is very complex with the depths varying from about 30–40 km in the surrounding basins (e.g., Ganges basin, Sichuan basin, and Tarim basin) to 60–80 km within the plateau. This considerable difference up to 40 km on the Moho depth reveals the substantial uplift and thickening of the crust in the Tibetan Plateau. Furthermore, two visible “Moho depression belts” are observed within the plateau with the maximum Moho deepening along the Indus‐Tsangpo Suture and along the northern margin of Tibet bounding the Tarim basin with the relatively shallow Moho in central Tibet between them. The southern “belt” is likely formed in compressional environment, where the Indian plate underthrusts northward beneath the Tibetan Plateau, while the northern one could be formed by the southward underthrust of the Asian lithosphere beneath Tibet. Key Points The improved Parker's formula guarantees high accuracy Gravity effect of the crustal and upper mantle density variations is removed New Moho beneath Tibet well corresponds to seismic data
ISSN:1525-2027
1525-2027
DOI:10.1029/2019GC008849