Effects of vegetation growth on soil microstructure and hydro-mechanical behaviour

Fraccica Alessandro, Romero Enrique, Fourcaud Thierry. 2024. Effects of vegetation growth on soil microstructure and hydro-mechanical behaviour. Géotechnique, 15 p.

https://doi.org/10.1680/jgeot.23.00163

Article de revue ; Article de recherche ; Article de revue à facteur d'impact

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Résumé : Literature studies are presenting counterposed effects of vegetation on soil hydraulic behaviour. Besides, root impacts at the micro-scale are rarely correlated to phenomenological observations due to the complexity of adopting up-scaling factors. In this study, the microstructural causes behind observed changes in vegetated compacted clayey sand's hydraulic and volume change behaviour were explored. Laboratory experiments were carried out on compacted samples seeded with Cynodon dactylon. Significant changes in soil water-saturated permeability, water retention and shrinkage upon drying were observed after root growth. Laboratory measurements were complemented by the quantification of root morphological features and observations at the micro-scale for different soil hydraulic states. X-ray scans and mercury intrusion porosimetry allowed to cover seven orders of magnitude of pore sizes, shedding light on soil fabric changes at the soil–root interface and the clay aggregate scale. The effects of roots on the soil pore size distribution consisted of Multiphysics phenomena: fissure generation, void clogging and soil aggregation due to roots' chemical interaction. Furthermore, a good correlation was found between the normalised volume of roots and the micro-pores volume. This new expression was included in a framework to predict soil water retention behaviour considering the aggregated structure and soil–root hydro-chemical interactions.

Mots-clés Agrovoc : trait morphologique du sol, Cynodon dactylon, eau du sol, racine, propriété physicochimique, retrait, légume racine, système poral du sol, perméabilité du sol, enracinement, Cynodon