Present-day crustal deformation in the southeastern Tibetan Plateau: Insights from three-dimensional finite-element modeling

Quantifying the present-day kinematics of southeastern Tibet is important for understanding the tectonic evolution of the Tibetan Plateau. In this study, we established a three-dimensional finite element model to estimate fault slip and strain rates in the southeastern Tibetan Plateau based on Global Navigation Satellite Systems (GNSS) observations. Our model yields an overall good fit to the GNSS velocity field with residuals of 0.83 mm/ yr and 0.85 mm/yr for the east and north components, respectively, comparable to the uncertainties of 0.67 mm/ yr and 0.61 mm/yr. The model-derived strike-slip rates of the Xiaojiang fault, Nanhua-Chuxiong fault, Qujiang fault, central segment of Red River fault, southeastern segment of Red River fault and Dien Bien Phu fault are 13.7 & PLUSMN; 0.7 mm/yr, 1.9 & PLUSMN; 0.6 mm/yr, 3.4 & PLUSMN; 1.1 mm/yr, 1.5 & PLUSMN; 0.5 mm/yr, 1.2 & PLUSMN; 0.4 mm/yr and 1.6 & PLUSMN; 0.4 mm/ yr, respectively, which are consistent with previous geological results, implying that the short-term fault motions estimated from GNSS data can reflect the long-term fault slip in the southeastern Tibetan Plateau. The shear strain rate is localized along the Xiaojiang fault, which agrees with predictions of the tectonic extrusion model (i. e., the lateral extrusion of internally rigid blocks along strike-slip faults). Strain orientations in the western part of southeastern Tibetan Plateau are characterized by clockwise rotation. Comparison of the surface strain rates, crustal stress, and seismic anisotropy reveals general consistency between deformation of the surface and upper crust. The eastern part of southeastern Tibetan Plateau has small residuals, and the present-day crustal deformation can be explained by rigid block motion. However, the western part of the study area has relatively large residuals, implying that other processes, such as gravitational spreading, may influence deformation in the area. We propose a hybrid model that combines rigid block motion with continuum deformation to explain the contemporary crustal deformation of southeastern Tibetan Plateau.