Using Three-dimensional Plant Root Architecture in Models of Shallow-slope Stability

doi:10.1093/aob/mcm199

AOBPreview originally published online on August 31, 2007
Annals of Botany 2008 101(8):1281-1293; doi:10.1093/aob/mcm199

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Using Three-dimensional Plant Root Architecture in Models of Shallow-slope Stability

Frédéric Danjon¹^,*, David H. Barker²^,, Michael Drexhage³ and Alexia Stokes⁴

¹ INRA, UR1263 EPHYSE, 69 route d'Arcachon, F-33612 Cestas, France
² Warnell School of Forest Resources, University of Georgia, Athens, GA 30602, USA
³ INRA Nancy, LERFOB, 54280 Champenoux, France
⁴ INRA, AMAP, 34398 Montpellier Cedex 5, France

^* For correspondence. E-mail fred{at}pierroton.inra.fr

Received: 22 March 2007 Returned for revision: 27 April 2007 Accepted: 28 June 2007 Published electronically: 31 August 2007

Background: The contribution of vegetation to shallow-slope stability isof major importance in landslide-prone regions. However, existingslope stability models use only limited plant root architecturalparameters. This study aims to provide a chain of tools usefulfor determining the contribution of tree roots to soil reinforcement.

Methods: Three-dimensional digitizing in situ was used to obtain accurateroot system architecture data for mature Quercus alba in twoforest stands. These data were used as input to tools developed,which analyse the spatial position of roots, topology and geometry.The contribution of roots to soil reinforcement was determinedby calculating additional soil cohesion using the limit equilibriummodel, and the factor of safety (FOS) using an existing slopestability model, Slip4Ex.

Key Results: Existing models may incorrectly estimate the additional soilcohesion provided by roots, as the spatial position of rootscrossing the potential slip surface is usually not taken intoaccount. However, most soil reinforcement by roots occurs closeto the tree stem and is negligible at a distance >1·0m from the tree, and therefore global values of FOS for a slopedo not take into account local slippage along the slope.

Conclusions: Within a forest stand on a landslide-prone slope, soil fixationby roots can be minimal between uniform rows of trees, leadingto local soil slippage. Therefore, staggered rows of trees wouldimprove overall slope stability, as trees would arrest the downwardmovement of soil. The chain of tools consisting of both software(free for non-commercial use) and functions available from thefirst author will enable a more accurate description and useof root architectural parameters in standard slope stabilityanalyses.

Key words: Landslide, root area ratio, slope stability, 3D digitizing, Quercus alba, soil cohesion, soil internal friction angle

Present address: Prima Subur Sdn Bhd, Kuala Lumpur, Malaysia.

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