Modeling soil-plant-water interaction

Purpose The purpose of this paper is to numerically investigate the combined effects of canopy (leaf area index [LAI]) and root properties (root distribution function [Rdf] and root area index [RAI]) on a suction induced in soil-root composite under three different scenarios. Design/methodology/appr...

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Bibliographic Details
Published in:Engineering computations 2018-05, Vol.35 (3), p.1543-1566
Main Authors: Gadi, Vinay, Singh, Shivam, Singhariya, Manish, Garg, Ankit, S, Sreedeep, K, Ravi
Format: Article
Language:English
Subjects:
Boundary conditions
Conductivity
Constitutive models
Design engineering
Distribution functions
Finite element method
Friction
Green infrastructure
Hydraulics
Influence
Infrastructure
Investigations
Leaf area index
Mathematical models
Numerical analysis
Properties (attributes)
Researchers
Retention
Shear strength
Slope stability
Soil conditions
Soil investigations
Soil suction
Soil water
Studies
Transpiration
Vegetation
Water
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Summary:Purpose The purpose of this paper is to numerically investigate the combined effects of canopy (leaf area index [LAI]) and root properties (root distribution function [Rdf] and root area index [RAI]) on a suction induced in soil-root composite under three different scenarios. Design/methodology/approach Richards equation coupled with sink term was solved using a commercial finite element package “HYDRUS” to investigate suction induced in soil-root composite. Findings Scenario 1 unveiled that soil-root composite induces 1 to 20 per cent higher suction than bare soil under the absence of transpiration. From Scenario 2, value of suction at depth of maximum RAI in case of linearly decreasing Rdf was found to be higher than that of other Rdfs. However, depth of suction influence zone (SIZ) for uniform Rdf and non-linear Rdf was found to be 10 and 11 per cent higher than that of linearly decreasing Rdf. Depth of evaporation dominant zone (EDZ) for uniformly decreasing Rdf and non-linear Rdf was found to be 1.08 to 3 times higher than that of linearly decreasing Rdf. From Scenario 3, influence of LAI on depth of SIZ is minimal. Depth of EDZ was found to decrease with the increase in LAI. Based on simple calculation on infinite slope stability, influence of variation in root and shoot properties was found to be significant on its factor of safety. Research limitations/implications Numerical constitutive model has limitations that it does not consider aging of plant. This model is only applicable for a particular set of soil conditions. A long-term study is required in this field to further quantify parameters for improving calibration and modeling performance. Practical implications Following are the practical implication: consideration of vegetation properties into engineered design of green infrastructure (slopes in this case) and selection of vegetation with appropriate characteristics in design for enhancement of stability of green infrastructure. Originality/value Contents of this paper are original, and they have not been submitted to any other journal.
ISSN:0264-4401
1758-7077
DOI:10.1108/EC-07-2017-0280