Analyzing key factors of roots and soil contributing to tree anchorage of Pinus species
FOURCAUD, Thierry
Botanique et Modélisation de l'Architecture des Plantes et des Végétations [UMR AMAP]
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Botanique et Modélisation de l'Architecture des Plantes et des Végétations [UMR AMAP]
Langue
en
Article de revue
Ce document a été publié dans
Trees - Structure and Function. 2018, vol. 32, n° 3, p. 703-712
Springer Verlag
Résumé en anglais
Tree anchorage is a primary function for plant survival which may reach its limit under extreme conditions such as windstorms. To better understand the processes and influential factors underlying tree anchorage, we analyzed ...Lire la suite >
Tree anchorage is a primary function for plant survival which may reach its limit under extreme conditions such as windstorms. To better understand the processes and influential factors underlying tree anchorage, we analyzed the mechanical effects of root morphology and the material properties of roots and soil on the tree-overturning process with the recently developed finite element model RootAnchor. The root system was represented by a simplified 3D root pattern derived from an ensemble average of seven measured root systems of 19-year-old Pinus pinaster grown in sandy spodosol. Soil properties were measured by direct shear tests. Taguchi orthogonal arrays were used to examine the sensitivity of the geometric and material factors of roots and soil to tree anchorage. Tree anchorage was characterized by anchorage strength TMc and anchorage stiffness K0. Using a small number of numerical experiments, the sensitivity analysis prioritized only two key factors contributing to tree anchorage among the 34 factors considered. The results showed root morphological traits that played a dominant role in the material properties of roots and soil in tree anchorage. Taproot depth, the dimensions of the Zone of Rapid Taper (ZRT) and basal diameter of the windward shallow roots were the key factors contributing to TMc (variations > 8%). The dimensions of the taproot, root and soil stiffness, and the basal diameter of the leeward shallow roots were the most active factors for K0 (variations > 10%). These results provide insight into simplified tree anchorage expressions for the prediction of wind-induced uprooting.< Réduire
Mots clés
tempête
ancrage racinaire
dégât dû au vent
arbre forestier
Mots clés en anglais
tree anchorage
sensitivity analysis
taguchi orthogonal arrays
finite element method
pinus pinaster
root architecture
thunderstorm
wind damage
forest tree
Origine
Importé de halUnités de recherche