Large‐Scale Crustal Deformation, Slip‐Rate Variation, and Strain Distribution Along the Kunlun Fault (Tibet) From Sentinel‐1 InSAR Observations (2015–2020)

Isolating seasonal deformation from Interferometric Synthetic Aperture Radar (InSAR) time‐series is critical to quantitative understanding the freeze‐thaw processes in permafrost regions. Physics‐ or statistics‐based approaches have been developed to extract seasonal deformation, yet both constraining their evolution in time domain, and thus impeded the quantification of their amplitude variability especially over large scales. By applying Independent Component Analysis (ICA) on Sentinel‐1 InSAR measurements during 2015–2019 on the central Qinghai‐Tibet Plateau, we reveal that the averaged seasonal deformation is increasing with a linear trend of around 0.17 cm/year. The growing seasonal amplitude is attributed to an 8 cm increase of the Equivalent Water Thickness in the active layer. The results demonstrate the capability of ICA‐based decomposition on isolating freeze‐thaw‐related deformation from other components. The large‐scale spatial distribution of varied seasonal deformation can provide new insight into quantifying the water mass balance in vast permafrost regions.

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“…(2021); D. Zhao et al. (2022). The cluster‐like ground subsidence may be attributed to the thawing of ice‐rich permafrost (J. Chen et al., 2022).…”

Section: Resultsmentioning

confidence: 99%

Increased Water Content in the Active Layer Revealed by Regional‐Scale InSAR and Independent Component Analysis on the Central Qinghai‐Tibet Plateau

Chen

Liu

et al. 2022

Geophysical Research Letters

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“…For InSAR data sets in Zhao et al. (2022a), the postseismic deformation during the InSAR observation period excited by the 2001 Mw7.8 Kokoxili earthquake has been corrected using the combined afterslip and viscoelastic relaxation model in Zhao et al. (2021), which is constrained by the postseismic observations during 2001–2010.…”

Section: Methodsmentioning

confidence: 99%

“…Before further including InSAR data of the Xianshuihe fault, we need to separate the transient deformation using earthquake-cycle models, which is beyond our scope in this study. The InSAR data sets from Zhao et al (2022a) and Ou et al (2022) comprise the mean velocity field along both descending and ascending tracks, while the InSAR measurements from Fang et al (2022) are the decomposed east-west component from descending and ascending observations (see the detailed method in Fang et al, 2022). All InSAR data sets span 2015-2020 or 2015-2021, which do not contain the deformation from the most recent large earthquake in the region, for example, the 2021 Mw7.4 Maduo earthquake (e.g., Fang et al, 2022;Yue et al, 2022).…”

Section: Insar Velocity Measurementsmentioning

confidence: 99%

“…The involvement of the Kunlun Pass fault in the 2001 Kokoxili earthquake motivates us to include this large subsidiary fault of the Kunlun fault to examine the fault coupling over our observation period (e.g., Lasserre et al., 2005). In the interior of the plateau, for instance, the Kunlun fault, the lateral resolution of coupling is limited mainly by sparse GPS data (e.g., Zhu et al., 2021), whereas this problem can be overcome by adding spatially dense InSAR measurements (e.g., Zhao et al., 2022a). Different from previous widely‐used elastic block models (e.g., McCaffrey et al., 2002; Meade & Hager, 2005; Meade & Loveless, 2009), we adopt a physical constraint based on a stress‐constrained inversion method, with a new consideration of stress interactions between each isolated faults (e.g., Bürgmann et al., 2005; Johnson & Fukuda, 2010; Lindsey et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

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An Updated Fault Coupling Model Along Major Block‐Bounding Faults on the Eastern and Northeastern Tibetan Plateau From a Stress‐Constrained Inversion of GPS and InSAR Data

Zhao,

Qu,

Shan

et al. 2024

JGR Solid Earth

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Large block‐bounding faults on the Tibetan plateau are significant geological structures that accommodate tectonic movements and accumulate stress, leading to large earthquakes. Quantifying the interseismic slip deficit rate helps to better assess the earthquake potential. We combine available InSAR (2015–2020) and interseismic GPS data to determine fault coupling along 14 major block‐bounding faults. Spatially dense InSAR measurements remarkably improve the resolution of the coupling model. Combined with a GPS‐constrained block model, we examine the performance of the inversion approach with the stress constraint and the common Laplacian smoothing based on both synthetic tests and real data. We suggest that, for continental strike‐slip faults, adding the stress constraint can mitigate unphysical coupling distributions due to unreasonable assumptions or modeling artifacts, reducing the model uncertainty and improving the accuracy of the coupling model. This is particularly useful for segments featured by a highly heterogeneous distribution of coupling along the transition zone from locking to creeping region, partially‐coupling segment, and junction zone between main and subsidiary faults. We present a large‐scale fault coupling map along the major block‐bounding faults on the northeastern and eastern Tibetan plateau, highlighting the distinct degrees of fault coupling and lateral variations. The collage of coupling maps along different faults demonstrates the kinematic features over a broad time scale during earthquake cycles ranging from early to late interseismic phases, such as the segments ruptured during the 2001 Kokoxili earthquake and the 1920 Haiyuan earthquake.

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“…Due to the nearly east-west trend of the Xidatan fault, the dominant contribution to the resultant fault-parallel velocities is from east-west displacements generated by the left-lateral strike-slip motion of the fault. Red (Liu et al, 2019) and blue (Wang and Shen, 2020) Zhao et al, 2022), the estimates of fault coupling ratio likely provide a lower bound in Zhu et al (2021). Some narrow stripes of low coupling from top to bottom around the Xidatan fault in (a-c) are not kinematically reliable due to the sparse GPS data constraints on the surface.…”

Section: Text S4 Insar Reference Frame Transformation and 3-d Displac...mentioning

confidence: 99%

Transient fault creep on the Xidatan (Tibet) fault driven by viscoelastic relaxation following the 2001 Kokoxili earthquake

Zhao

Shan

et al. 2022

Geology

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Recent geodetic observations of shallow fault creep have illuminated increasingly complex, time-dependent slip behaviors, including quasi-steady creep and temporary accelerations, termed slow-slip events. We documented two decades of deformation on the Xidatan fault on the Tibetan Plateau measured by radar interferometry during 2003–2010 and 2015–2020 CE, to probe the temporal evolution of shallow creep and illuminate the underlying mechanisms. The geodetic observations reveal an ~80-km-long fault section with temporally decaying creep along the Xidatan fault, one of the current seismic gaps along the Kunlun fault. The transient creep is likely driven by postseismic deformation processes, dominated by viscoelastic relaxation after the 2001 Kokoxili earthquake, rather than triggered by the coseismic rupture. The transient creep behavior, indicating rate-strengthening frictional properties of the fault, contradicts the inference of locking along the Xidatan fault, based on geodetic imaging before the Kokoxili earthquake and on historical ruptures. We propose that, during the interseismic period, the frictionally unlocked shallow portions of the fault are located in the stress shadow cast by the deeper locked asperities, but they creep at resolvable rates when exposed to transient stress and stressing rate increases. We argue that stress interactions in the triple junction of the Kusai Hu, Xidatan, and Kunlun Pass faults promote complex slip behaviors throughout the earthquake cycle.

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Large‐Scale Crustal Deformation, Slip‐Rate Variation, and Strain Distribution Along the Kunlun Fault (Tibet) From Sentinel‐1 InSAR Observations (2015–2020)

Cited by 16 publications

References 71 publications

Increased Water Content in the Active Layer Revealed by Regional‐Scale InSAR and Independent Component Analysis on the Central Qinghai‐Tibet Plateau

Increased Water Content in the Active Layer Revealed by Regional‐Scale InSAR and Independent Component Analysis on the Central Qinghai‐Tibet Plateau

An Updated Fault Coupling Model Along Major Block‐Bounding Faults on the Eastern and Northeastern Tibetan Plateau From a Stress‐Constrained Inversion of GPS and InSAR Data

Transient fault creep on the Xidatan (Tibet) fault driven by viscoelastic relaxation following the 2001 Kokoxili earthquake

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