Power-law viscoelastic flow of the lower accretionary prism in the Makran subduction zone following the 2013 Baluchistan Earthquake

Guo Cheng; William D. Barnhart; Shaoyang Li

doi:10.1029/2022JB024493

Power-law viscoelastic flow of the lower accretionary prism in the Makran subduction zone following the 2013 Baluchistan Earthquake

JGR Solid Earth

By: Guo Cheng, William D. Barnhart, and Shaoyang Li

https://doi.org/10.1029/2022JB024493

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Abstract

Subduction zone accretionary prisms are commonly modeled as elastic structures where permanent deformation is accommodated by faulting and folding of otherwise elastic materials, yet accretionary prisms may exhibit other deformation styles over relatively short time scales. In this study, we use 6.5-year (2014–2021) Sentinel-1 interferometric synthetic aperture radar (InSAR) time-series of post-seismic deformation in the Makran accretionary prism of southeast Pakistan to characterize non-linear viscoelastic deformation within an active accretionary prism on short timescales (months to years). We constructed a series of 3-D finite-element models of the Makran subduction zone, including an accretionary prism, and constrained the elastic thickness of the upper wedge and the flow-law parameters (power-law exponent, activation enthalpy, and pre-exponential constant) of the lower wedge through forward model fits to the InSAR time-series. Our results show that the prism is elastically thin (8–12 km) and the non-linear viscoelastic relaxation of the deep portions of the prism alone can sufficiently explain the post-seismic surface deformation. Our best fitting flow-law parameters (n = 3.76 ± 0.39, Q = 82.2 ± 37.73 kJ mol⁻¹, and A = 10^{−3.36±4.69}) are consistent with triggering of low temperature dislocation creep within fluid-saturated siliciclastic rocks. We believe that the fluids necessary for this weakening originate from sedimentary underplating and/or the presence the hydrocarbons. The presence of power-law rheology within the lower wedge impacts the estimated plate coupling and the stress state in the subduction system, with respect to the conventional elastic wedge model, and hence should to be considered in future earthquake cycle models.

Suggested Citation

Cheng, G., Barnhart, W.D., and Li, S., 2022, Power-law viscoelastic flow of the lower accretionary prism in the Makran subduction zone following the 2013 Baluchistan Earthquake: JGR Solid Earth, v. 127, no. 11, e2022JB024493, 17 p., https://doi.org/10.1029/2022JB024493.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Power-law viscoelastic flow of the lower accretionary prism in the Makran subduction zone following the 2013 Baluchistan Earthquake
Series title	JGR Solid Earth
DOI	10.1029/2022JB024493
Volume	127
Issue	11
Publication Date	November 12, 2022
Year Published	2022
Language	English
Publisher	American Geophysical Union
Contributing office(s)	Earthquake Hazards Program
Description	e2022JB024493, 17 p.
Country	Iran. Pakistan
Other Geospatial	Makran accretionary prism