Author
Listed:
- Feng Shi
(China University of Geosciences
The University of Chicago)
- Yanbin Wang
(The University of Chicago)
- Tony Yu
(The University of Chicago)
- Lupei Zhu
(Saint Louis University)
- Junfeng Zhang
(China University of Geosciences)
- Jianguo Wen
(Argonne National Laboratory)
- Julien Gasc
(École Normale Supérieure PSL Research University)
- Sarah Incel
(École Normale Supérieure PSL Research University)
- Alexandre Schubnel
(École Normale Supérieure PSL Research University)
- Ziyu Li
(Saint Louis University)
- Tao Chen
(China University of Geosciences)
- Wenlong Liu
(China University of Geosciences)
- Vitali Prakapenka
(The University of Chicago)
- Zhenmin Jin
(China University of Geosciences)
Abstract
Southern Tibet is the most active orogenic region on Earth where the Indian Plate thrusts under Eurasia, pushing the seismic discontinuity between the crust and the mantle to an unusual depth of ~80 km. Numerous earthquakes occur in the lower portion of this thickened continental crust, but the triggering mechanisms remain enigmatic. Here we show that dry granulite rocks, the dominant constituent of the subducted Indian crust, become brittle when deformed under conditions corresponding to the eclogite stability field. Microfractures propagate dynamically, producing acoustic emission, a laboratory analog of earthquakes, leading to macroscopic faults. Failed specimens are characterized by weak reaction bands consisting of nanometric products of the metamorphic reaction. Assisted by brittle intra-granular ruptures, the reaction bands develop into shear bands which self-organize to form macroscopic Riedel-like fault zones. These results provide a viable mechanism for deep seismicity with additional constraints on orogenic processes in Tibet.
Suggested Citation
Feng Shi & Yanbin Wang & Tony Yu & Lupei Zhu & Junfeng Zhang & Jianguo Wen & Julien Gasc & Sarah Incel & Alexandre Schubnel & Ziyu Li & Tao Chen & Wenlong Liu & Vitali Prakapenka & Zhenmin Jin, 2018.
"Lower-crustal earthquakes in southern Tibet are linked to eclogitization of dry metastable granulite,"
Nature Communications, Nature, vol. 9(1), pages 1-13, December.
Handle:
RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-05964-1
DOI: 10.1038/s41467-018-05964-1
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