Abstract
Deformation microstructures of peak metamorphic conditions in ultrahigh-pressure (UHP) metamorphic rocks constrain the rheological behavior of deeply subducted crustal material within a subduction channel. However, studies of such rocks are limited by the overprinting effects of retrograde metamorphism during exhumation. Here, we present the deformation microstructures and crystallographic-preferred orientation data of minerals in UHP rocks from the Dabie–Shan to study the rheological behavior of deeply subducted continental material under UHP conditions. The studied samples preserve deformation microstructures that formed under UHP conditions and can be distinguished into two types: high-strain mafic–ultramafic samples (eclogite and garnet-clinopyroxenite) and low-strain felsic samples (jadeite quartzite). This distinction suggests that felsic rocks are less strained than mafic–ultramafic rocks under UHP conditions. We argue that the phase transition from quartz to coesite in the felsic rocks may explain the microstructural differences between the studied mafic–ultramafic and felsic rock samples. The presence of coesite, which has a higher strength than quartz, may result in an increase in the bulk strength of felsic rocks, leading to strain localization in nearby mafic–ultramafic rocks. The formation of shear zones associated with strain localization under HP/UHP conditions can induce the detachment of subducted crustal material from subducting lithosphere, which is a prerequisite for the exhumation of UHP rocks. These findings suggest that coesite has an important influence on the rheological behavior of crustal material that is subducted to coesite-stable depths.
Highlights
Since the discovery of coesite and micro-diamond in metamorphic rocks [1,2,3], the exhumation of deeply subducted continental material has been recognized as a common occurrence in continental collision zones
Most previous studies of UHP rocks have relied on petrological, mineralogical, and geochemical investigations, with relatively few having focused on microstructural and rheological aspects, the study of deformation microstructures should constrain the rheological behavior of deeply subducted crustal material under UHP conditions
Garnet is optically isotropic owing to its cubic structure, indicating that measurements of its CPO cannot be conducted by using a U-stage [39]
Summary
Since the discovery of coesite and micro-diamond in metamorphic rocks [1,2,3], the exhumation of deeply subducted continental material has been recognized as a common occurrence in continental collision zones. Most previous studies of UHP rocks have relied on petrological, mineralogical, and geochemical investigations, with relatively few having focused on microstructural and rheological aspects, the study of deformation microstructures should constrain the rheological behavior of deeply subducted crustal material under UHP conditions. The Dabie–Sulu orogenic belt is a continental collision zone in eastern China that contains the world’s largest UHP metamorphic belt (>30,000 km2 ) [4,5]. The Dabie–Sulu orogenic belt is a continental collision zone in eastern China that. Dabie–Shan region to underunderstand the rheological behavior of deeply subducted continental material under stand the rheological behavior of deeply subducted continental material under conditions by measuring deformation microstructures and crystallographic fabrics.conditions by measuring deformation microstructures and crystallographic fabrics
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