Rheology of continental lithosphere and seismic anisotropy

Rheology of continental lithosphere and seismic anisotropy

Rheology of rocks controls the deformation of the Earth at various space-time scales, which is crucial to understand the tectonic evolution of continental lithosphere. Researches of rock rheology are mainly conducted via high-pressure and high-temperature rheological experiments and multi-scale obse...

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Bibliographic Details
Published in:Science China. Earth sciences Vol. 67; no. 1; pp. 31 - 60
Main Authors: Sun, Shengsi, Dong, Yunpeng, Li, Yixi, Yang, Yihai, Cheng, Chao, Hui, Bo, Zhang, Bin, Zang, Rutao
Format: Journal Article
Language:English
Published: Beijing Science China Press 2024
Springer Nature B.V
Subjects:
Amphibolites
Anisotropy
Deformation
Earth and Environmental Science
Earth mantle
Earth Sciences
Eclogite
High pressure
High temperature
High temperature effects
Lithosphere
Mica
Olivine
Peridotite
Plagioclase
Plateaus
Review
Rheological properties
Rheology
Rock
Rocks
Seismic activity
Seismic properties
Seismic response
Seismic velocities
Tectonics
Seismic velocity
Mineral fabric
Rheology
Anisotropy
Lithosphere
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Summary:Rheology of rocks controls the deformation of the Earth at various space-time scales, which is crucial to understand the tectonic evolution of continental lithosphere. Researches of rock rheology are mainly conducted via high-pressure and high-temperature rheological experiments and multi-scale observations and measurements of naturally deformed rocks. At present, a large amount of data from such kinds of studies have been accumulated. This paper first provides an up-to-date comprehensive review of the rheological mechanisms, fabric types and seismic properties of the main rock-forming minerals at different depths of continental lithosphere, including olivine, orthopyroxene, clinopyroxene, amphibole, plagioclase, quartz and mica. Then, progress in high-pressure and high-temperature experiments and natural deformation observations is introduced, mainly regarding the rheological strength and behavior, seismic velocity and anisotropy of lithospheric mantle peridotite, eclogite, mafic granulite, amphibolite and felsic rocks. Finally, by taking the Tibetan Plateau as an example, the application of rock rheology for quantitative interpretation of seismic anisotropy data is discussed. The combination of mineral deformation fabrics and seismic anisotropy is expected to make an important breakthrough in understanding the rheological properties and structure of continental lithosphere.
ISSN:1674-7313
1869-1897
DOI:10.1007/s11430-022-1171-3