Reevaluation of the Late Pleistocene Slip Rate of the Haiyuan Fault Near Songshan, Gansu Province, China

Yao, Wenqian; Liu‐Zeng, Jing; Oskin, M. E.; Wang, Wei; Li, Zhanfei; Prush, Veronica; Zhang, Jinyu; Shao, Yuan; Yuan, Zhaode; Klinger, Yann

doi:10.1029/2018jb016907

Cited by 39 publications

(49 citation statements)

References 84 publications

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“…We found that the largest slip rate is 6.6 mm/year and the average slip rate is 2.25 ± 2.24 mm/year. Although with large uncertainties, our estimated slip rate is less than the shallow creep rate of~5 mm/year from InSAR observations (Jolivet et al, 2013) and geological rate of 5-9 mm/year (Yao et al, 2019).…”

Section: The Characteristics Of Repeating Earthquakes At the Laohushamentioning

confidence: 58%

Systematic Search for Repeating Earthquakes Along the Haiyuan Fault System in Northeastern Tibet

2020

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Repeating earthquakes have been found at many faults around the world. The Haiyuan fault is a major left‐lateral strike‐slip fault along the northeastern boundary of the Tibetan Plateau. Two great earthquakes (1920 Haiyuan and 1927 Gulang) have occurred on and round this fault system, but the section between the ruptures of the two earthquakes, also known as the Tianzhu seismic gap, remains unbroken. Shallow creep has been observed from geodetic data at the Laohushan section of the Haiyuan fault near the eastern end of the seismic gap. However, the driving mechanism and depth extent of shallow creep are not clear. Here we conduct a systematic search for repeating earthquakes in northeastern Tibet based on seismic data recorded by permanent stations in 10 years (2009–2018). Based on waveform cross‐correlations, we find several repeating earthquake clusters at the Laohushan section. This is consistent with the shallow creep inferred from the geodetic data, indicating repeating earthquakes can be driven by nearby aseismic slip. Approximately 300 repeaters were found within clusters of intense seismicity near the rupture zones of the 1927 M8.0 Gulang and 2016 M6.4 Menyuan earthquakes. Relocation of events in the cluster near the Gulang earthquake delineates two possible unmapped faults orthogonal to the Haiyuan fault. In addition, we also identify several repeating earthquakes generated by mining activities with different waveforms and occurrence patterns. Our study suggests that repeating earthquakes around the Haiyuan fault are likely driven by long‐term postseismic relaxation process associated with the 1920 Haiyuan and 1927 Gulang earthquakes.

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Section: The Characteristics Of Repeating Earthquakes At the Laohushamentioning

confidence: 58%

Systematic Search for Repeating Earthquakes Along the Haiyuan Fault System in Northeastern Tibet

2020

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“…Additionally, the fault planes of the two faults are steep (Li et al, 2013, 2017; Liu‐Zeng et al, 2007). The strain is then partitioned into left‐lateral shearing on the Qilian‐Haiyuan and Xiangshan‐Tianjingshan faults, and Qilian‐Haiyuan fault has a larger late Quaternary slip rate than Xiangshan‐Tianjianshan fault (Guo et al, 2017; Li et al, 2017; Yao et al, 2019; Zheng et al, 2013; Figure 17b).…”

Section: Discussionmentioning

confidence: 99%

A New Tectonic Model for the 1927M8.0 Gulang Earthquake on the NE Tibetan Plateau

et al. 2020

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The rupture patterns of large earthquakes in transpressional systems can provide important information for understanding oblique motion and strain partitioning between tectonic blocks. The 1927 M8.0 Gulang earthquake occurred on the transpressional boundary between the Tibetan and Gobi-Alashan blocks. Our results, combined with those of previous studies show that the Lenglongling fault (LLLF) and Southern Wuwei Basin fault (SWBF) have both ruptured during the Gulang earthquake, but they exhibited different motions. An~120-km-long surface rupture zone formed along the LLLF, with a left-lateral strike-slip motion and a coseismic horizontal offset of~2.4-7.5 m. Bending, bifurcation, and change of the slip sense occurs at both ends of the fault. An~42-km-long rupture zone formed along the SWBF, with a coseismic vertical offset of~0.6-2.8 m. Thus, the Gulang earthquake is a complex rupture event where strike-slip and thrust faults ruptured simultaneously. Analysis of deep and shallow structures and three-dimensional finite-element modeling reveal that the north dipping LLLF and the SWBF may converge downward to a low-angle décollement, accommodating the strike-slip and thrust motions during the earthquake, respectively. This pattern of deformation partitioning is similar to some other earthquakes where oblique block convergence is generally partitioned into strike-slip motion on steeply dipping faults and vertical motion on gently dipping faults. Our study also suggests that the strain partitioning pattern in the NE Tibetan Plateau may be controlled by changes of the regional principal compressive stress directions and fault geometry at depth. However, the length of the rupture zone on the HSF is not consistent with the magnitude of the earthquake and damage distribution (Figure 1; Gu, 1983). Ai et al. (2017) mapped the Southern Wuwei Basin fault ©2020. American Geophysical Union. All Rights Reserved.

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“…Along the Maomao Shan segment, Lasserre et al (1999) determined a slip rate of 12 ± 4 mm/yr, while Yuan et al (1998) estimated lower slip rates of 4.1-5.4 mm/yr. Yao et al (2019) recently reassessed the offsets and age control for sites of Lasserre et al (1999) and updated the slip rate here to 5-8.9 mm/yr over the late Pleistocene -Holocene. Further east, the Haiyuan segment, which ruptured in the 1920 Haiyuan earthquake, was assigned a slip rate of 8 ± 2 mm/yr by Zhang et al (1988b).…”

Section: Geologic Settingmentioning

confidence: 99%

Late Pleistocene slip rate of the central Haiyuan fault constrained from optically stimulated luminescence, 14C, and cosmogenic isotope dating and high-resolution topography

et al. 2020

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To better constrain the long-term millennial slip rate of the Haiyuan fault in its central part, we revisited the site of Daqing, where there are multiple paired offset terraces. We used 0.1-m-resolution terrestrial light detection and ranging (LiDAR) and uncrewed aerial vehicle imagery to survey the offset terraces, quantify their geomorphology, and map the fault trace. From these observations, we refined the geomorphological interpretation of the site, measured terrace riser offsets, and determined their relation to terrace formation. The well-constrained age of the highest terrace, T3, at 13.7 ± 1.5 ka, determined from a combination of surface and subsurface optically stimulated luminescence, 14C, and terrestrial in situ 10Be cosmogenic radionuclide dating, associated with an offset of 88 m, yields a late Pleistocene minimum slip rate of 6.4 ± 1.0 mm/yr. The less-well-constrained offset (72 ± 3 m) of the T3/T2 riser base and the age (>9.3 ± 0.6 ka) of terrace T2 yield a maximum slip rate of 7.7 ± 0.6 mm/yr. The smallest offset of a gully incised into T1 of 6.0 ± 0.5 m is potentially associated with the most recent slip event that occurred in the last millennia. Overall, these offsets and ages constrain a geological rate of 5−8 mm/yr (preferred rate >6.4 mm/yr), similar to geodetic estimates. Our collocated high-resolution topography and precise chronology make it possible to reveal the geomorphic complexities of terrace riser offsets and their postformational evolution, and to show how previously determined geological rates along the fault were both under- and overestimated.

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Reevaluation of the Late Pleistocene Slip Rate of the Haiyuan Fault Near Songshan, Gansu Province, China

Cited by 39 publications

References 84 publications

Systematic Search for Repeating Earthquakes Along the Haiyuan Fault System in Northeastern Tibet

Systematic Search for Repeating Earthquakes Along the Haiyuan Fault System in Northeastern Tibet

A New Tectonic Model for the 1927M8.0 Gulang Earthquake on the NE Tibetan Plateau

Late Pleistocene slip rate of the central Haiyuan fault constrained from optically stimulated luminescence, 14C, and cosmogenic isotope dating and high-resolution topography

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