Heat Generation Due to Friction in Shear Zones of the Crust as a Factor of Metamorphism and Anatexis: Results of Computer Modeling

The effect of heat generation due to friction in faults under the conditions of shear and thrust was evaluated by computer modeling, and 3D and 2D thermomechanical numerical models were developed. The equations of solid mechanics in a coupled formulation were solved: the equations of mechanical equi...

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Published inDoklady earth sciences Vol. 486; no. 2; pp. 706 - 710
Main Authors Babichev, A. V., Reverdatto, V. V., Polyansky, O. P., Likhanov, I. I., Semenov, A. N.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.06.2019
Springer
Springer Nature B.V
Subjects
Analysis
Coefficient of friction
Computer simulation
Computer-generated environments
Earth and Environmental Science
Earth Sciences
Friction
Geochemistry
Geological faults
Heat generation
Heating
Mathematical models
Mechanics
Metamorphism
Metamorphism (Geology)
Modelling
Numerical models
Rocks, Metamorphic
Shear zone
Solid mechanics
Thermal conductivity
Thermomechanical analysis
Three dimensional models
Two dimensional models
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Summary:The effect of heat generation due to friction in faults under the conditions of shear and thrust was evaluated by computer modeling, and 3D and 2D thermomechanical numerical models were developed. The equations of solid mechanics in a coupled formulation were solved: the equations of mechanical equilibrium and the equation of thermal conductivity. The model of an elastic–plastic material with the Drucker–Prager and Huber–Mises yield function is applied. In the 3D shear model, heating was 100–110°C for the friction coefficient of 0.3; 180–190°C, for the friction coefficient of 0.5; and ~300°C, for the friction coefficient of 0.65. In the horizontal thrust, the heating at the contact zone was 120–130°C at a shear plane depth of 20 km and 150–160°C at a shear plane depth of 30 km, for the friction coefficient of 0.3. The results obtained may be considered as a lower estimate for the value of thermomechanical heating of rocks of the Yenisei collision–shear zone.
ISSN:1028-334X
1531-8354
DOI:10.1134/S1028334X19060230