Abstract
In view of the important role played by roots against shallow landslides, root tensile force was evaluated for two widespread temperate tree species within the Caspian Hyrcanian Ecoregion, i.e., Fagus orientalis L. and Carpinus betulus L. Fine roots (0.02 to 7.99 mm) were collected from five trees of each species at three different elevations (400, 950, and 1350 m a.s.l.), across three diameter at breast height (DBH) classes (small = 7.5–32.5 cm, medium = 32.6–57.5 cm, and large =57.6–82.5 cm), and at two slope positions relative to the tree stem (up- and down-slope). In the laboratory, maximum tensile force (N) required to break the root was determined for 2016 roots (56 roots per each of two species x three sites x three DBH classes x two slope positions). ANCOVA was used to test the effects of slope position, DBH, and study site on root tensile force. To obtain the power-law regression coefficients, a nonlinear least square method was used. We found that: 1) root tensile force strongly depends on root size, 2) F. orientalis roots are stronger than C. betulus ones in the large DBH class, although they are weaker in the medium and small DBH classes, 3) root mechanical resistance is higher upslope than downslope, 4) roots of the trees with larger DBH were the most resistant roots in tension in compare with roots of the medium or small DBH classes, and 5) the root tensile force for both species is notably different from one site to another site. Overall, our findings provide a fundamental contribution to the quantification of the protective effects of forests in the temperate region.
Highlights
Worldwide, 24 billion tons of fertile soil are estimated to be lost every year due to erosion and mass wasting [1]
Regardless of site, F values indicate that tensile force was influenced more by root diameter (F=4892) than by species or diameter at breast height (DBH), and the effect of slope position had the least effect on tensile strength (F=23) (Table 3)
This study provides a comprehensive analysis of root tensile force variation of two common species, Carpinus betulus and Fagus orientalis, across differing DBH classifications, slope positions, and study site elevations within a temperate deciduous forest
Summary
24 billion tons of fertile soil are estimated to be lost every year due to erosion and mass wasting [1]. For trees, roots are known to reinforce soil through three mechanisms [4,5,6,7]: basal root reinforcement, lateral root reinforcement, and increasing the stiffness of the root–soil composite material In all of these mechanisms, the contribution of roots is defined by their mechanical properties (strength and elasticity) [4,5,8,9,10] and their density and spatial distribution [4,6,9,11], species, environment, root diameter, root branching order, age of the trees, root architecture, and forest structure are known to influence root reinforcement variability [12,13,14]. A few authors indicated that roots of a size up to 20 mm in diameter contribute the most slope stability [18], in rare cases, roots with diameter up to 40 mm are said to play an important role in slope stability [19]
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