Rock mechanics constraints on mid-crustal low-viscosity flow beneath Tibet

E. H. Rutter; J. Mecklenburgh; K. H. Brodie

doi:10.1144/SP360.19

Rock mechanics constraints on mid-crustal low-viscosity flow beneath Tibet

E. H. Rutter, J. Mecklenburgh, K. H. Brodie

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

It has been inferred from various types of geophysical data that the Tibetan middle and upper crust is detached from the underlying lower crust and mantle by a weak, mid-crustal zone involving partial melting at about 30-35 km depth. Previous modelling of the flow has used an arbitrary mid-crustal rheology to match the constraints imposed by the overall flow regime. Here we show that extrapolation of experimental rock mechanics data for solid-state flow of a quartz-dominated Tibetan middle and upper crust, plus flow of partially molten synthetic 'granitoid', are consistent with the geophysical constraints and provide an experimentally constrained basis for the modelling of crustal rheology involving partially molten rocks. © The Geological Society of London 2011.

Original language	English
Title of host publication	Geological Society Special Publication\|Geol. Soc. Spec. Publ.
Subtitle of host publication	Microstructures, Mechanics and Anisotropy
Place of Publication	Bath (UK)
Publisher	Geological Society
Pages	329-336
Number of pages	7
Volume	360
DOIs	https://doi.org/10.1144/SP360.19
Publication status	Published - 2011

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title = "Rock mechanics constraints on mid-crustal low-viscosity flow beneath Tibet",

abstract = "It has been inferred from various types of geophysical data that the Tibetan middle and upper crust is detached from the underlying lower crust and mantle by a weak, mid-crustal zone involving partial melting at about 30-35 km depth. Previous modelling of the flow has used an arbitrary mid-crustal rheology to match the constraints imposed by the overall flow regime. Here we show that extrapolation of experimental rock mechanics data for solid-state flow of a quartz-dominated Tibetan middle and upper crust, plus flow of partially molten synthetic 'granitoid', are consistent with the geophysical constraints and provide an experimentally constrained basis for the modelling of crustal rheology involving partially molten rocks. {\textcopyright} The Geological Society of London 2011.",

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AU - Rutter, E. H.

AU - Mecklenburgh, J.

AU - Brodie, K. H.

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N2 - It has been inferred from various types of geophysical data that the Tibetan middle and upper crust is detached from the underlying lower crust and mantle by a weak, mid-crustal zone involving partial melting at about 30-35 km depth. Previous modelling of the flow has used an arbitrary mid-crustal rheology to match the constraints imposed by the overall flow regime. Here we show that extrapolation of experimental rock mechanics data for solid-state flow of a quartz-dominated Tibetan middle and upper crust, plus flow of partially molten synthetic 'granitoid', are consistent with the geophysical constraints and provide an experimentally constrained basis for the modelling of crustal rheology involving partially molten rocks. © The Geological Society of London 2011.

AB - It has been inferred from various types of geophysical data that the Tibetan middle and upper crust is detached from the underlying lower crust and mantle by a weak, mid-crustal zone involving partial melting at about 30-35 km depth. Previous modelling of the flow has used an arbitrary mid-crustal rheology to match the constraints imposed by the overall flow regime. Here we show that extrapolation of experimental rock mechanics data for solid-state flow of a quartz-dominated Tibetan middle and upper crust, plus flow of partially molten synthetic 'granitoid', are consistent with the geophysical constraints and provide an experimentally constrained basis for the modelling of crustal rheology involving partially molten rocks. © The Geological Society of London 2011.

U2 - 10.1144/SP360.19

DO - 10.1144/SP360.19

M3 - Chapter

VL - 360

SP - 329

EP - 336

BT - Geological Society Special Publication|Geol. Soc. Spec. Publ.

PB - Geological Society

CY - Bath (UK)

ER -

Rock mechanics constraints on mid-crustal low-viscosity flow beneath Tibet

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