# Multi-parameter coupling effects of root reinforcement on disintegration and swelling behavior of expansive soil: A response surface methodology approach

**Authors:** Yonggang Huang, Hongri Zhang, Xinzhong Wang, Yuexing Wu, Xianliang Tan

PMC · DOI: 10.1371/journal.pone.0335349 · PLOS One · 2025-11-13

## TL;DR

This study shows how root characteristics like diameter and arrangement affect soil stability and swelling, using a statistical method to find optimal root configurations for soil reinforcement.

## Contribution

The paper introduces a novel experimental framework combining RSM with hybrid design to quantify root-soil interactions in expansive soils.

## Key findings

- Root diameter and quantity have the strongest effect on reducing soil disintegration.
- Composite root distribution reduces disintegration by 3.2g compared to horizontal or inclined patterns.
- Optimized root systems can reduce swelling rate to 3.8% through multi-axial confinement.

## Abstract

This study employs response surface methodology (RSM) integrated with a hybrid Box-Behnken and D-optimal experimental design to unravel the multi-parameter coupling effects of root reinforcement on the hydro-mechanical behavior of expansive soils. The experimental framework systematically investigated root diameter (1–5 mm), length (30–50 mm), quantity (3–5 roots), and distribution patterns (horizontal, inclined, composite), with quantitative assessments of disintegration amount (DA), swelling force (SF), and swelling rate (SR). Key findings reveal that root diameter (X1) and quantity (X4) dominate disintegration control, exhibiting significant main effects (Fx1 = 173.8, Fx2 = 112.9, p < 0.0001), while the synergistic interaction between diameter and length (X1X2, β=0.5, p = 0.0012) further enhances stabilization through mechanical interlocking. Composite root distribution (D3) outperformed horizontal (D1) and inclined (D2) patterns, reducing DA by3.2 g (p < 0.0001) via its 3D interwoven structure, which constrains particle displacement and pore connectivity Quadratic polynomial models effectively predicted SF (R2 = 0.901) and rate (R2 = 0.822), with composite distribution suppressing SF by 41% under optimized parameters (X1 = 5 mm, X4 = 5 roots) through multi-axial confinement. A strong positive correlation (r = 0.92 for SF, r= = 0.90 for SR, p < 0.01) links DA to swelling behavior, where disintegration amplifies swelling via clay mineral activation and cementation breakdown, quantified as Y2 = 0.074Y12 + 0.305Y1 + 3.977. The results establish composite-root systems with high root density (X4 = 5 roots) and large diameter (X1 = 5 mm) as optimal for minimizing disintegration (predicted DA = 5.6g) and swelling (SR = 3.8%), providing a quantitative framework for eco-engineering slope stabilization in expansive soils through morphology-driven root-soil synergy.

## Full-text entities

- **Diseases:** SR (MESH:C536766), SF (MESH:D004487)
- **Chemicals:** iron (MESH:D007501), DA (-), feldspar (MESH:C016447), Water (MESH:D014867), montmorillonite (MESH:D001546), carbonate (MESH:D002254), oxygen (MESH:D010100), kaolinite (MESH:D007616), iron oxide (MESH:C000499)
- **Species:** Chrysopogon zizanioides (cuscus grass, species) [taxon 167337]

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12614509/full.md

## References

20 references — full list in the complete paper: https://tomesphere.com/paper/PMC12614509/full.md

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Source: https://tomesphere.com/paper/PMC12614509