Modelling increased soil cohesion due to roots with EUROSEM

Concentrated flow erosion; Erosion resistance; Root architecture; Root density; Soil reinforcement; Adhesion; Erosion; Pile foundations; Reinforcement; Shear strength; Silt; Geologic models

Abstract :

[en] As organic root exudates cause soil particles to adhere firmly to root surfaces, roots significantly increase soil strength and therefore also increase the resistance of the topsoil to erosion by concentrated flow. This paper aims at contributing to a better prediction of the root effects on soil erosion rates in the EUROSEM model, as the input values accounting for roots, presented in the user manual, do not account for differences in root density or root architecture. Recent research indicates that small changes in root density or differences in root architecture considerably influence soil erosion rates during concentrated flow. The approach for incorporating the root effects into this model is based on a comparison of measured soil detachment rates for bare and for root-permeated topsoil samples with predicted erosion rates under the same flow conditions using the erosion equation of EUROSEM. Through backwards calculation, transport capacity efficiencies and corresponding soil cohesion values can be assessed for bare and root-permeated topsoils respectively. The results are promising and present soil cohesion values that are in accordance with reported values in the literature for the same soil type (silt loam). The results show that grass roots provide a larger increase in soil cohesion as compared with tap-rooted species and that the increase in soil cohesion is not significantly different under wet and dry soil conditions, either for fibrous root systems or for tap root systems. Power and exponential relationships are established between measured root density values and the corresponding calculated soil cohesion values, reflecting the effects of roots on the resistance of the topsoil to concentrated flow incision. These relationships enable one to incorporate the root effect into the soil erosion model EUROSEM, through adapting the soil cohesion input value. A scenario analysis shows that the contribution of roots to soil cohesion is very important for preventing soil loss and reducing runoff volume. The increase in soil shear strength due to the binding effect of roots on soil particles is two orders of magnitude lower as compared with soil reinforcement achieved when roots mobilize their tensile strength during soil shearing and root breakage. Copyright © 2008 John Wiley & Sons, Ltd.

Disciplines :

Environmental sciences & ecology

Author, co-author :

De Baets, S.; Physical and Regional Geography Research Group, K.U. Leuven, Celestijnenlaan 200E, B-3001 Heverlee, Belgium

Torri, D.; Consiglio Nazionale Delle Ricerche, Istituto Di Ricera Per La Protezione Idrogeologica (CNR-IRPI), Sesto Fiorentino, Italy

Poesen, J.; Physical and Regional Geography Research Group, K.U. Leuven, Celestijnenlaan 200E, B-3001 Heverlee, Belgium

Salvador, M. P.; Consiglio Nazionale Delle Ricerche, Istituto Di Ricera Per La Protezione Idrogeologica (CNR-IRPI), Sesto Fiorentino, Italy

Meersmans, Jeroen ; Université de Liège - ULiège > Département GxABT > Analyse des risques environnementaux

Language :

English

Title :

Modelling increased soil cohesion due to roots with EUROSEM

Publication date :

2008

Journal title :

Earth Surface Processes and Landforms

ISSN :

0197-9337

eISSN :

1096-9837

Publisher :

Wiley, Hoboken, United States - New Jersey

Volume :

Issue :

Pages :

1948-1963

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 08 November 2021

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Bibliography

De Baets S, Poesen J, Galindo-Morales P, Knapen A. 2007. Impact of root architecture on the erosion-reducing potential of roots during concentrated flow. Earth Surface Processes and Landforms 23: 1323 -1345.
De Baets S, Poesen J, Gyssels G, Knapen A. 2006. Effects of grass roots on the erodibility of topsoils during concentrated flow. Geomorphology 76: 54-67.
De Baets S, Poesen J, Reubens B, Wemans K, De Baerdemaeker J, Muys B. In press. Root tensile strength and root distribution of typical Mediterranean plant species and their contribution to soil shear strength. Plant and Soil.
De Roo APJ, van Dijk PM, Ritsema CJ, Cremers NHDT, Stolte J, Offermans RJE, Kwaad FJPM, Verzandvoort MA. 1995. Rapport 364.1. DLO, Staringcentrum: Wageningen (in Dutch).
de Willigen P, van Noordwijk M. 1989. Roots, Plant Production and Nutrient Use Efficiency, PhD thesis. Institute for Soil Fertility: Haren, the Netherlands.
Donley HE. 1991. The drag force on a sphere. UMAP Journal 12: 47-80.
Flanagan DC, Nearing MA. 1995. USDA-Water Erosion Prediction Project (WEPP): Hillslope Profile and Watershed Model Documentation. National Soil Erosion Research Laboratory: West Lafayette, IN.
Govers G. 1987. Spatial and temporal variation in rill development processes at the Huldenberg experimental site. In Rill Erosion: Processes and Significance, Bryan R (ed.). Catena Supplement 8: 17-34.
Govers G. 1990. Empirical relationships on the transporting capacity of overland flow. International Association of Hydrological Sciences 189: 45-63.
Govers G. 1991. Time-dependency of runoff velocity and erosion: the effect of the initial soil moisture profile. Earth Surface Processes and Landforms 16: 713-729.
Govers G, Everaert W, Poesen J, Rauws G, De Ploey J, Lautridou JP. 1990. A long flume study of the dynamic factors affecting the resistance of a loamy soil to concentrated flow erosion. Earth Surface Processes and Landforms 15: 313-328.
Govers G, Loch RJ. 1993. Effects of initial water content and soil mechanical strength on the runoff erosion resistance of clay soils. Australian Journal of Soil Research 31: 549-566.
Gray DH, Leiser AT. 1982. Biotechnical Slope Protection and Erosion Control. Van Nostrand Reinhold: New York.
Gray DH, Sotir RB. 1996. Biotechnical and Soil Bioengineering Slope Stabilization: a Practical Guide for Erosion Control. Wiley: Toronto.
Greenway DR. 1987. Vegetation and slope stability. In Slope Stability: Geotechnical Engineering and Geomorphology, Anderson MG, Richards KS (eds). Wiley: Chichester; 187-230.
Gyssels G, Poesen J, Liu G, Van Dessel W, Knapen A, De Baets S. 2006. Effects of cereal roots on detachment rates of single- and double drilled topsoils during concentrated flow. European Journal of Soil Science 57: 381-391.
Harker FR, Stec MGH, Hallett IC, Bennett CL. 1997. Texture of parenchymatous plant tissue: a comparison between tensile and other instrumental and sensory measurements of tissue strength and juiciness. Postharvest Biology and Technology 11: 63-72.
Knapen A, Poesen J, De Baets S. 2007. Seasonal variations in soil resistance during concentrated flow for a loess-derived soil under two contrasting tillage practices. Soil and Tillage Research 94: 425-440.
Mamo M, Bubenzer GD. 2001a. Detachment rate, soil erodibility and soil strength as influenced by living plant roots, Part I: Laboratory study. American Society of Agricultural Engineers 44: 1167-1174.
Mamo M, Bubenzer GD. 2001b. Detachment rate, soil erodibility and soil strength as influenced by living plant roots, Part II: Field study. American Society of Agricultural Engineers 44: 1175-1181.
Mattia C, Bischetti GB, Gentile F. 2005. Biotechnical characteristics of root systems of typical Mediterranean species. Plant and Soil 278: 23-32.
McIntyre DS, Stirk GB. 1954. A method for determination of apparent density of soil aggregates. Austalian Journal of Agricultural Research 5: 291-296.
Morgan RPC. 2005. Soil Erosion and Conservation, 3rd edn. Blackwell: Oxford.
Morgan RPC, Quinton JN, Smith RE, Govers G, Poesen JWA, Auerswald K, Chisi G, Torri D, Styczen E. 1998a. The European soil erosion model (EUROSEM): a dynamic approach for predicting sediment transport from fields and small catchments. Earth Surface Processes and Landforms 23: 527-544.
Morgan RPC, Quinton JN, Smith RE, Govers G, Poesen JWA, Auerswald K, Chisi G, Torri D, Styczen E. 1998b. The European Soil Erosion Model (EUROSEM): Documentation and User Guide. Silsoe College, Cranfield University.
Norris JE. 2005. Root reinforcement by hawthorn and oak roots on a highway cut-slope in Southern England. Plant and Soil 278: 43-53.
Operstein V, Frydman S. 2000. The influence of vegetation on soil strength. Ground Improvement 4: 81-89.
Poesen J. 1992. Mechanics of overland-flow generation and sediment production on loamy and sandy soils with and without rock fragments: Part I. In Overland Flow Hydraulics and Erosion Mechanics, Parsons AJ, Abrahams AD (eds). UCL Press: London; 275-305.
Poesen J, De Luna E, Franca A, Nachtergaele J, Govers G. 1999. Concentrated flow erosion rates as affected by rock fragments cover and initial soil moisture content. Catena 36: 315-329.
Pollen N, Simon A. 2005. Estimating the mechanical effects of riparian vegetation on stream bank stability using a fiber bundle model. Water Resources Research 41: 1-11.
Rauws G, Govers G. 1988. Hydraulic and soil mechanical aspects of rill generation on agricultural soils. Journal of Soil Science 39: 111-124.
Renard KG, Foster GR, Weesies DK, McCool DK, Yoder DC. 1997. Predicting Soil Erosion by Water; a Guide to Conservation Planning with the Revised Universal Soil Loss Equation (RUSLE). US Department of Agriculture: Washington, DC.
Rose CW, Williams JR, Sander GC, Barry DA. 1983. A mathematical model of soil erosion and deposition processes. 1. Theory for a plane element. Soil Science Society of American Journal 47: 991-995.
Styczen M, Nielsen SA. 1989. A view of soil erosion theory, process-research and model building: possible interactions and future developments. Quaderni di Scienza del Suolo 2: 27-45.
Tengbeh GT. 1993. The effect of grass roots on shear strength variations with moisture content. Soil Technology 6: 287-295.
Waldron LJ. 1977. The shear resistance or root-permeated homogeneous and stratified soil. Soil Science Society of America Journal 41: 843-849.
Waldron LJ, Dakessian S. 1981. Soil reinforcement by roots: calculation of increased soil shear resistance from root properties. Soil Science 132: 427-435.
Waldron LJ, Dakessian S. 1982. Effect of grass, legume and tree roots on soil shearing resistance. Soil Science Society of America Journal 46: 894-899.
Wu TH, McKinnell WP III, Swanston DN. 1979. Strength of tree roots and landslides on Prince of Wales Island, Alaska. Canadian Geotechnical Journal 16: 19-33.
Wynn T, Mostaghimi S. 2006. The effects of vegetation and soil type on streambank erosion, southwestern Virginia, USA. Journal of American Water Resources Association 42: 69-82.
Yavorsky BM, Pinsky AA. 1974. Fundamentals of Physics. MIR: Moscow.
Ziemer RR. 1981. Roots and stability of forested slopes. International Association of Hydrological Science Publications 132: 343-361.
Zhou ZC, Shangguan ZP. 2007. The effects of ryegrass roots and shoots on loess erosion under simulated rainfall. Catena 71: 350-355.