J. Nábělek scite author profile

We studied the formation of the Himalayan mountain range and the Tibetan Plateau by investigating their lithospheric structure. Using an 800-kilometer-long, densely spaced seismic array, we have constructed an image of the crust and upper mantle beneath the Himalayas and the southern Tibetan Plateau. The image reveals in a continuous fashion the Main Himalayan thrust fault as it extends from a shallow depth under Nepal to the mid-crust under southern Tibet. Indian crust can be traced to 31 degrees N. The crust/mantle interface beneath Tibet is anisotropic, indicating shearing during its formation. The dipping mantle fabric suggests that the Indian mantle is subducting in a diffuse fashion along several evolving subparallel structures.

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Partially Molten Middle Crust Beneath Southern Tibet: Synthesis of Project INDEPTH Results

Nelson

Zhao

Brown

et al. 1996

Science

1,115

736

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INDEPTH geophysical and geological observations imply that a partially molten midcrustal layer exists beneath southern Tibet. This partially molten layer has been produced by crustal thickening and behaves as a fluid on the time scale of Himalayan deformation. It is confined on the south by the structurally imbricated Indian crust underlying the Tethyan and High Himalaya and is underlain, apparently, by a stiff Indian mantle lid. The results suggest that during Neogene time the underthrusting Indian crust has acted as a plunger, displacing the molten middle crust to the north while at the same time contributing to this layer by melting and ductile flow. Viewed broadly, the Neogene evolution of the Himalaya is essentially a record of the southward extrusion of the partially molten middle crust underlying southern Tibet.

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Role of Fault Bends in the Initiation and Termination of Earthquake Rupture

King

Nábělek

1985

Science

465

240

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Rupture in individual earthquakes apparently is limited to regions between bends in faults. This is illustrated for eight events that have occurred since 1966. A model based on geometric concepts describes why this is so and clarifies earlier ideas of "asperities" and "barriers" used to explain earthquake initiation and termination processes. Because of their importance in the rupture process, bend zones should be monitored for precursory effects.

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A focused look at the Alpine fault, New Zealand: Seismicity, focal mechanisms, and stress observations

Leitner¹,

Eberhart‐Phillips²,

Anderson³

et al. 2001

J. Geophys. Res.

161

202

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Density distribution of the India plate beneath the Tibetan plateau: Geophysical and petrological constraints on the kinetics of lower-crustal eclogitization

Hetényi

Cattin²,

Brunet³

et al. 2007

Earth and Planetary Science Letters

177

202

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J. Nábělek

Underplating in the Himalaya-Tibet Collision Zone Revealed by the Hi-CLIMB Experiment

Partially Molten Middle Crust Beneath Southern Tibet: Synthesis of Project INDEPTH Results

Role of Fault Bends in the Initiation and Termination of Earthquake Rupture

A focused look at the Alpine fault, New Zealand: Seismicity, focal mechanisms, and stress observations

Density distribution of the India plate beneath the Tibetan plateau: Geophysical and petrological constraints on the kinetics of lower-crustal eclogitization

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