Cyclic liquefaction behavior of fiber-reinforced sand: the role of initial static shear stress
ID:7 View Protection:ATTENDEE Updated Time:2026-07-01 12:02:09 Hits:2 Oral Presentation

Start Time:Pending()

Duration:Pending

Session:No Session »

No files

Abstract
Initial static shear stress is commonly sustained in slopes, embankments, and backfills, where saturated soils are prone to severe liquefaction-induced damage under seismic loading. Although randomly distributed fibers have been widely used to improve the liquefaction resistance of sand, their effectiveness under varying initial stress states remains insufficiently understood. In this study, stress-controlled undrained cyclic triaxial tests were performed on unreinforced and fiber-reinforced loose sand under isotropic and anisotropic consolidation conditions. The results show that fiber inclusion suppresses excess pore pressure generation and delays axial strain accumulation, with the improvement becoming more pronounced as fiber content increases. Additionally, the reinforced specimens exhibit markedly higher cyclic resistance under initial compressional stress, whereas initial extensional stress promotes rapid strain accumulation and earlier failure. The initial static shear stress also governs the deformation and failure modes of unreinforced and fiber-reinforced sand, resulting in flow liquefaction, cyclic mobility, or residual deformation accumulation. These findings emphasize the need to consider in-situ initial stress states when assessing fiber reinforcement for seismic slope design.
Keywords
Liquefaction; Fiber-reinforced sand; Initial static shear stress; Peak axial strain
Speaker
Jiazhi Zhu
student Tongji University

Submission Author
Jiazhi Zhu Tongji University
Jiayi Liu Tongji University
Bin Ye Tongji University
Submit Comment
Verify Code Change Another
All Comments
Important Date
  • Conference Date

    Aug 09

    2026

    to

    Aug 12

    2026

  • Aug 09 2026

    Draft paper submission deadline

  • Aug 12 2026

    Registration deadline

Sponsored By
International Consortium on Geo-disaster Reduction (ICGdR)
UNESCO Chair on Geoenvironmental Disaster Reduction
Organized By
The Hong Kong Polytechnic University