Abstract
BackgroundTo quantitatively evaluate the contribution of plant roots to soil shear strength, the generalized equivalent confining pressure (GECP), which is the difference in confining pressure between the reinforced and un-reinforced soil specimens at the same shear strength, was proposed and considered in terms of the function of plant roots in soil reinforcement.MethodsIn this paper, silt loam soil was selected as the test soil, and the roots of Indigofera amblyantha were chosen as the reinforcing material. Different drainage conditions (consolidation drained (CD), consolidation undrained (CU), and unconsolidated undrained (UU)) were used to analyse the influences of different root distribution patterns (horizontal root (HR), vertical root (VR), and complex root (CR)) and root contents (0.25%, 0.50%, and 0.75%) on the shear strength of soil-root composites.ResultsThe cohesion (c) values of the soil-root composites varied under different drainage conditions and root contents, while the internal friction angle (φ ) values remain basically stable under different drainage conditions. Under the same root content and drainage conditions, the shear strength indexes ranked in order of lower to higher were HR, VR and CR. The GECP of the soil-root composites with a 0.75% root content was 1.5–2.0 times that with a 0.50% root content and more than 5 times that with a 0.25% root content under the CD and CU conditions. The GECP in reinforced soil followed the sequence of CD > CU > UU. The GECP of the plant roots increased as confining pressure increased under CD and CU conditions while showed a complex change to the confining pressure under the UU condition.ConclusionIt was concluded that the evaluation of plant root reinforcing soil based on GECP can be used to measure effectively the influences of roots on soil under different drainage conditions and root distribution patterns.
Highlights
Plant roots play an important role in improving the overall stability of the superficial slope soil and increasing the safety coefficient of the slope (Zegeye et al, 2018; Zhou & Wang, 2019)
The c values varied under different drainage conditions and root contents, while the φ values remain basically stable under different drainage conditions due to the root content, which is different to the results of the un-reinforced soil
Under the same root content and drainage conditions, the c values ranked in order of lower to higher were HR, VR and CR, suggesting the CR is the best at enhancing the soil shear strength
Summary
Plant roots play an important role in improving the overall stability of the superficial slope soil and increasing the safety coefficient of the slope (Zegeye et al, 2018; Zhou & Wang, 2019). The effect of root reinforcement on slope stability can be evaluated directly in terms of the additional shear strength provided by plant roots in reinforced soil. To analyse the effect of plant roots on slope stability, many in situ and laboratory tests have been carried out on vegetated soil (Wu & Watson, 1998; Operstein & Frydman, 2000), and corresponding analytical models for soil-root composites have been developed (Waldron, 1977; Waldron & Dakessian, 1981; Wu et al, 1988). It was concluded that the evaluation of plant root reinforcing soil based on GECP can be used to measure effectively the influences of roots on soil under different drainage conditions and root distribution patterns
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