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1. The Influence of Fault Geometrical Complexity on Surface Rupture Length.

2. Surface ruptures of the 2022 Guanshan-Chihshang earthquakes in central Longitudinal Valley area, eastern Taiwan

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3. Surface ruptures of the 2022 Guanshan-Chihshang earthquakes in central Longitudinal Valley area, eastern Taiwan.

4. Surface Rupture of the 2008 Mw 6.6 Nura Earthquake: Triggered Flexural‐Slip Faulting in the Pamir‐Tien Shan Collision Zone.

5. Determining the surface fault-rupture hazard zone for the Pazarcık segment of the East Anatolian fault zone through comprehensive analysis of surface rupture from the February 6, 2023, Earthquake (Mw 7.7).

6. Reappraisal of the 2012 magnitude (MW) 6.7 Negros Oriental (Philippines) earthquake intensity and ShakeMap generation by using ESI-2007 environmental effects

7. The Influence of Fault Geometrical Complexity on Surface Rupture Length

8. Impacts of a Moderate-Sized Earthquake: The 2023 Magnitude (M w) 4.7 Leyte, Leyte Earthquake, Philippines.

9. Holocene activity and seismic surface rupture zone of the Abuduo fault eastern Tibetan Plateau.

10. Tepehan Rockslide: A large-scale earthquake-induced geological structure formed by Mw: 7.8 Kahramanmaraş (Pazarcık) earthquake, Türkiye.

11. Surface rupture during the 6th of February 2023 Mw 7.6 Elbistan-Ekinözü (Kahramanmaraş) earthquake: implications for fault rupture dynamics along the northern branch of East Anatolian Fault Zone.

12. Fault Surface Rupture Modeling Using Particle Image Velocimetry Analysis of Analog Sandbox Model.

13. Fault Orientation Trumps Fault Maturity in Controlling Coseismic Rupture Characteristics of the 2021 Maduo Earthquake

14. Holocene activity and seismic surface rupture zone of the Abuduo fault eastern Tibetan Plateau

15. THE KURA ACTIVE FAULT - POTENTIAL SOURCE OF SIGNIFICANT HAZARD.

16. Managing Active Fault Surface Rupture Risk through Land Use Planning: barriers and opportunities.

17. 2023 年 2 月 6 日土耳其 M7.8 级地震 地表破裂带初步调查.

18. The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay)

19. Typical Fine Structure and Seismogenic Mechanism Analysis of the Surface Rupture of the 2022 Menyuan Mw 6.7 Earthquake.

20. Deformation response and mechanical analysis of the Wangjiashan landslide in Baihetan Hydropower Station, China, during initial impoundment.

23. Surface Ruptures Along the Kita-Amagi Fault Zone

25. Surface Ruptures of the Shirahata–Oike Section

27. Double rupture event in the Tianshan Mountains: A case study of the 2021 Mw 5.3 Baicheng earthquake, NW China

28. Tectonic geomorphology and Quaternary fault slip rates in the Tsambagarav Massif, Mongolian Altai.

29. Impacts of Water and Stress Transfers from Ground Surface on the Shallow Earthquake of 11 November 2019 at Le Teil (France).

30. Substantial Upper Plate Faulting Above a Shallow Subduction Megathrust Earthquake: Mechanics and Implications of the Surface Faulting During the 2016 Kaikoura, New Zealand, Earthquake.

31. Impacts of a Moderate-Sized Earthquake: The 2023 Magnitude (Mw) 4.7 Leyte, Leyte Earthquake, Philippines

32. A Web-GIS hazards information system of the 2008 Wenchuan Earthquake in China

34. Evidence for surface rupture of the 1939 Erzincan earthquake based on field data and paleoseismology on the Ezinepazari Fault (North Anatolian Fault Zone, Central Anatolia).

35. The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay).

36. Kinematic and dynamic fault slip analyses: Implications from the surface rupture of the 2023 Elbistan (Kahramanmaraş) (Mw7.6) earthquake, Türkiye.

37. Predictive Simulation for Surface Fault Occurrence Using High-Performance Computing

38. Thirty years of paleoseismic research in metropolitan France

39. Sand liquefaction during the 2021 M 7.4 Maduo earthquake, China.

40. Fault associated with the 1967 M 6.3 Koyna earthquake, India: A review of recent studies and perspectives for further probing

41. Typical Fine Structure and Seismogenic Mechanism Analysis of the Surface Rupture of the 2022 Menyuan Mw 6.7 Earthquake

42. 综合遥感解译 2022 年 Mw 6.7 青海门源 地震地表破裂带.

43. Geological and geomorphological evidence of holocene activity along the maisu fault in the northern Sichuan–Yunnan block, Tibetan Plateau

44. Impacts of Water and Stress Transfers from Ground Surface on the Shallow Earthquake of 11 November 2019 at Le Teil (France)

45. Rapid response to the M$_{\protect \rm w}$ 4.9 earthquake of November 11, 2019 in Le Teil, Lower Rhône Valley, France

48. Repeated triggered ruptures on a distributed secondary fault system: an example from the 2016 Kumamoto earthquake, southwest Japan

49. The physical simulation test on formation mechanism of new surface rupture—taking the Xiaoyudong surface rupture in China as an example.

50. Re-evaluation of Surface Ruptures Produced by the 1609 M 7.3 Hongyazi Earthquake in the Northern Qilian Shan, China.