# Mechanical behavior of reservoir bank slope–pile–sheet structures under reservoir operation: Field monitoring and numerical simulation analysis

**Authors:** Zhiwei Cai, Tongqing Wu, Lei Nie, Yue Wu, Zhao Xiang, Zhijie Yang, Nianchun Xu, Fei Qi

PMC · DOI: 10.1371/journal.pone.0339875 · PLOS One · 2026-01-02

## TL;DR

This study examines how changes in reservoir water levels affect the stability of bank slope support structures using field data and simulations.

## Contribution

The research identifies a three-stage response mechanism and provides insights into pile design optimization for reservoir bank slopes.

## Key findings

- Slope displacement correlates strongly with water-level fluctuations in a three-stage process.
- Pile bending moments show an S-shaped profile with a maximum at the rock-soil interface.
- Numerical simulations closely match field data, confirming hydro-mechanical coupling effects.

## Abstract

Long-term fluctuations in reservoir water levels can lead to the deterioration of bank slope materials, representing a key trigger of instability. This study investigated the behavior of a slope–pile–sheet support structure at a site in Chongqing’s “Two Rivers and Four Banks” area through an integrated program of field monitoring and numerical simulation. The results demonstrated a strong correlation between slope displacement/settlement and water-level fluctuations, exhibiting a characteristic three-stage process. Rapid drawdown triggered substantial horizontal displacement with a one-month response lag, while settlement primarily occurred during water-level rise. Earth pressure behind the piles exhibited a non-linear R-shaped distribution, with a delayed response in shallow layers and a pronounced local pressure drop at 8 m depth indicative of seepage erosion. The pile bending moment showed a distinct S-shaped profile, with a maximum positive moment (1978.44 kN·m) at the rock-soil interface (13 m) and a negative moment zone below 21 m. The bending moment response also exhibited a one-month lag and was particularly sensitive to rapid drawdown. The identified contraflexure point at 21 m depth provides a basis for pile length optimization. The close agreement between numerical simulations and field data validates the strong hydro-mechanical coupling in the system. This research provides theoretical and practical support for the design and optimization of similar support structures in reservoir bank environments.

## Full-text entities

- **Diseases:** deformations (MESH:D009140)
- **Chemicals:** water (MESH:D014867)

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/PMC12758723/full.md

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Source: https://tomesphere.com/paper/PMC12758723