Methodological framework to select plant species for controlling rill and gully erosion: Application to a Mediterranean ecosystem

de Baets, S.; Poesen, J.; Reubens, B.; Muys, B.; de Baerdemaeker, J.; Meersmans, Jeroen

doi:10.1002/esp.1826

Article (Scientific journals)

Methodological framework to select plant species for controlling rill and gully erosion: Application to a Mediterranean ecosystem

de Baets, S.; Poesen, J.; Reubens, B. et al.

2009 • In Earth Surface Processes and Landforms, 34 (10), p. 1374-1392

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/264895

DOI
10.1002/esp.1826

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

De Baets et al 2009 ESPL.pdf

Publisher postprint (935.01 kB)

Request a copy

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Concentrated flow erosion; Desertification remediation; Plant traits; Root; Soil conservation; Above ground biomass; Concentrated flow; Erosion control; Gully erosion; Mass movement; Mediterranean ecosystem; Methodological frameworks; Modulus of elasticity; Moment of inertia; Multi Criteria Analysis; Organic debris; Plant species; Root area; Root density; Root diameters; Root tensile strength; Semi arid; Soil erosion rate; Stem density; Water flows; Biomass; Climatology; Debris; Drought; Knowledge based systems; Plants (botany); Pollution; Sedimentology; Slope stability; Soils; Stability criteria; Tensile strength; Erosion; Eurasia; Europe; Southern Europe; Spain; Lygeum spartum; Poaceae; Salsola genistoides; Stipa tenacissima

Abstract :

[en] Many studies attribute the effects of vegetation in reducing soil erosion rates to the effects of the above-ground biomass. The effects of roots on topsoil resistance against concentrated flow erosion are much less studied. However, in a Mediterranean context, where the above-ground biomass can temporarily disappear because of fire, drought or overgrazing, and when concentrated flow erosion occurs, roots can play an important role in controlling soil erosion rates. Unfortunately, information on Mediterranean plant characteristics, especially root characteristics, growing on semi-natural lands, and knowledge of their suitability for gully erosion control is often lacking. A methodological framework to evaluate plant traits for this purpose is absent as well. This paper presents a methodology to assess the suitability of plants for rill and gully erosion control and its application to 25 plant species, representative for a semi-arid Mediterranean landscape in southeast Spain. In this analysis determination of suitable plants for controlling concentrated flow erosion is based on a multi-criteria analysis. First, four main criteria were determined, i.e. (1) the potential of plants to prevent incision by concentrated flow erosion, (2) the potential of plants to improve slope stability, (3) the resistance of plants to bending by water flow and (4) the ability of plants to trap sediments and organic debris. Then, an indicator or a combination of two indicators was used to assess the scores for the four criteria. In total, five indicators were selected, i.e. additional root cohesion, plant stiffness, stem density, the erosion-reducing potential during concentrated flow and the sediment and organic debris obstruction potential. Both above-and below-ground plant traits were taken into account and measured to assess the scores for the five indicators, i.e. stem density, sediment and organic debris obstruction potential, modulus of elasticity of the stems, moment of inertia of the stems, root density, root diameter distribution, root area ratio and root tensile strength. The scores for the indicators were represented on amoeba diagrams, indicating the beneficial and the weak plant traits, regarding to erosion control. The grasses Stipa tenacissima L. and Lygeum spartum L. and the shrub Salsola genistoides Juss. Ex Poir. amongst others, were selected as very suitable plant species for rill and gully erosion control. Stipa tenacissima can be used to re-vegetate abandoned terraces as this species is adapted to drought and offers a good protection to concentrated flow erosion and shallow mass movements. Lygeum spartum can be used to vegetate concentrated flow zones or to obstruct sediment inflow to channels at gully outlets. Stipa tenacissima and Salsola genistoides can be used to stabilize steep south-facing slopes. The methodology developed in this study can be applied to other plant species in areas suffering from rill and gully erosion. © 2009 John Wiley & Sons, Ltd.

Disciplines :

Environmental sciences & ecology

Author, co-author :

de Baets, S.; Department of Earth and Environmental Sciences, Physical and Regional Geography Research Group, K.U. Leuven, Leuven, Belgium

Poesen, J.; Department of Earth and Environmental Sciences, Physical and Regional Geography Research Group, K.U. Leuven, Leuven, Belgium

Reubens, B.; Department of Earth and Environmental Sciences, Division Forest, Nature and Landscape, K.U. Leuven, Leuven, Belgium

Muys, B.; Department of Earth and Environmental Sciences, Division Forest, Nature and Landscape, K.U. Leuven, Leuven, Belgium

de Baerdemaeker, J.; Department of Biosystems, Division of Mechatronics, Biostatistics and Sensors, K.U. Leuven, Leuven, Belgium

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

Language :

English

Title :

Methodological framework to select plant species for controlling rill and gully erosion: Application to a Mediterranean ecosystem

Publication date :

2009

Journal title :

Earth Surface Processes and Landforms

ISSN :

0197-9337

eISSN :

1096-9837

Publisher :

Wiley, Hoboken, United States - New Jersey

Volume :

Issue :

Pages :

1374-1392

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 08 November 2021

Statistics

Number of views

41 (2 by ULiège)

Number of downloads

2 (2 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Albaladejo J, Castillo V, Roldan A. 1996. Rehabilitation of degraded soils by water erosion in semiarid environments. In Soil Degradation and Desertification on Mediterranean Environments, Rubio JL, Calvo A (eds). Geoforma Ediciones: Logroño; 265-278.
Alcaraz Ariza F, Botias Pelegrin M, Garcia Ruiz R, Rios Ruiz S, Rivera Nunez D, Robledo Miras A. 2002. Flora Basica de la region de Murcia. Novograf: Murcia.
Alegre J, Toledo JL, Martinez A, Mora O, De Andres EF. 1998. Rooting ability of Dorycnium spp. under different conditions. Scientia Horticulturae 76: 123-129.
Archer N, Hess T, Quinton J. 2002. Belowground relationships of soil texture, roots and hydraulic conductivity in two-phase mosaic vegetation in south-east Spain. Journal of Arid Environments 52: 535-553.
Béchet G, Nedjraoui D, Djebaili S. 1982. Valeur énergétique des principales espéces des hautes plaines steppiques de la Wilaya de Saida. Biocénoses, Bulleting d'écologie terrestre 1: 79-94.
Bochet E, García-Fayos P. 2004. Factors controlling vegetation establishment and water erosion on motorway slopes in Valencia, Spain. Restoration Ecology 12: 166-174.
Bochet E, Poesen J, Rubio JL. 1998. Relative efficiency of tree representative matorral species in reducing water erosion at the microscale in a semi-arid climate (Valencia, Spain). Geomorphology 23: 139-150.
Bochet E, Poesen J, Rubio JL. 2006. Runoff and soil loss under individual plants of a semi-arid Mediterranean shrubland: influence of plant morphology and rainfall intensity. Earth Surface Processes and Landforms 31: 536-549.
Bochet E, García-Fayos P, Alborch B, Tormo J. 2007. Soil water availability effects on seed germinations account for species segregation in semiarid roadslopes. Plant and Soil 295: 179-191.
Brindle FA. 2003. Use of native vegetation and biostimulants for controlling soil erosion on steep terrain. Journal of the Transportation Research Board, Eighth International Conference on Low-volume Roads 1: 203-209.
Brix H. 1997. Do macrophytes play a role in constructed treatment wetlands. Water Science Technolology 35: 11-17.
Buijs A. 2000. Statistiek om Mee Verder te Werken. Stenfert Kroese: Groningen.
Caravaca F, Alguacil MM, Vassileva M, Diaz G, Roldán A. 2004. AM fungi inoculation and addition of microbially-treated dry olive cakeenhanced afforestation of a desertified Mediterranean site. Land Degradation & Development 15: 153-161.
Cerda A. 1997. The effect of patchy distribution of Stipa tenacissima L. on runoff and erosion. Journal of Arid Environments 36: 37-51.
Cerda A. 1998. Soil aggregate stability under different Mediterranean vegetation types. Catena 32: 73-86.
Clary J, Save R, Biel C, De Herralde F. 2004. Water relations in competitive interactions of Mediterranean grasses and shrubs. Annals of Applied Botany 144: 149-155.
Clevering OA, Brix H, Lukavska J. 2001. Geographic variation in growth responses in Phragmites australis. Aquatic-Botany 69: 89-108.
Cohn JP. 2005. Tiff over Tamarisk: can a nuisance be nice, too? Bioscience 55: 648-654.
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, Knapen A, Galindo Morales P. 2007a. Impact of root architecture, soil characteristics and flow shear stress on the erosion-reducing potential of roots during concentrated flow. Earth Surface Processes and Landforms 32: 1323-1345.
De Baets S, Poesen J, Knapen A, Gonzáles Barberá G, Navarro JA. 2007b. Root characteristics of representative Mediterranean plant species and their erosion-reducing potential during concentrated runoff. Plant and Soil 294: 169-183.
De Baets S, Poesen J, Reubens B, Muys B, De Baerdemaecker J, Wemans K. 2008. Root tensile strength and root distribution of typical Mediterranean plant species and their implications for increasing soil shear strength. Earth Surface Processes and Landforms 305: 207-226.
De Luis M, Raventos J, Cortina J, Gonzales-Hidalgo JC, Sanchez JR. 2004. Fire and torrential rainfall: effects on the perennial grass Brachypodium retusum. Plant Ecology 173: 225-232.
DiTomaso JM. 1998. Impact, biology, and ecology of saltcedar (Tamarix spp.) in the southwestern United States. Weed-Technology 12: 326-336.
Dunn GH, Dabney SM. 1996. Modulus of elasticity and moment of inertia of grass hedge stems. Transactions of the American Society of Agricultural Engineers 39: 947-952.
El-Keblawy A, Shaltout KH, Lovett DJ, Ramadan A. 1997. Population dynamics of an Egyptian desert shrub Thymelaea hirsuta. Canadian Journal of Botany 75: 2027-2037.
FAO. 2005. New_LocClim software - local climate estimator, Environment and Natural Resources Working Paper No. 20. Environment and Natural Resources Service, FAO: Rome (CD-ROM).
Friederici P. 1995. The alien saltcedar. American Forests 101: 45-47.
Frietag H. 1971. Die naturlcihe vegetation des sudost-spanischen Trockengebietes. Botanik Jahrbuch 91: 11-310.
Garcia G, Faz A, Cunha M. 2004. Performance of Piptatherum miliaceum (Smilo grass) in edaphic Pb and Zn phytoremediation over a short growth period. International Biodeterioration & Bio-degradation 54: 245-250.
García-Fayos P, García-Ventoso B, Cerdà A. 2000. Limitations to plant establishment on eroded slopes in southeastern Spain. Journal of Vegetation Science 11: 77-86.
Gasque M, García-Fayos P. 2004. Interaction between Stipa tenacissima and Pinus halepensis: consequences for reforestation and the dynamics of grass steppes in semi-arid Mediterranean areas. Fores Ecology and Manangement 189: 251-261.
Gökbulak F. 2003. Comparision of growth performance of Lolium perenne L., Dactylis glomerata L. and Agropyron elongatum (Host.) P. Beauv. for erosion control in Turkey. Journal of Environmental Biology 24: 45-53.
González-Hildago JC, Raventos J, Echevarria MT. 1997. Comparison of sediment ratio curves for plants with different architectures. Catena 29: 333-340.
Goodman AM, Crook MJ, Ennos AR. 2001. Anchorage mechanics of the tap root system of winter-sown oilseed rape (Brassica napus L.). Annals of Botany 87: 397-404.
Gray DH, Sotir RB. 1996. Biotechnical and Soil Bioengineering Slope Stabilization: A Practical Guide for Erosion Control. John Wiley and Sons: Toronto.
Greenway DR. 1987. Vegetation and slope stability. In Slope Stability: Geotechnical Engineering and Geomorphology, Anderson MG, Richards KS (eds). John Wiley and Sons: Chichester; 187-230.
Gyssels G, Poesen J, Bochet E, Li Y. 2005. Impact of plant roots on the resistance of soils to erosion by water: a review. Progress in Physical Geography 29: 189-217.
Haase P, Pugnaire FI, Fernandez EM, Puigdefabregas J, Clark SC, Incoll LD. 1996. An investigation of rooting depth of the semiarid shrub Retama sphaerocarpa (L.) Boiss. By labelling of ground water with a chemical tracer. Journal of Hydrology 177: 23-31.
Hara T, Van der Toorn J, Hook JH. 1993. Growth dynamics and size structure of shoots of Phragmites australis, a clonal plant. Journal of Ecology 81: 47-60.
Haslam SM. 1972. Phragmites communis Trin. The Journal of Ecology 60: 585-610.
Herrera J. 1991. The reproductive-biology of a riparian Mediterranean shrub, Nerium oleander L (Apocynaceae). Botanical Journal of the Linnean Society 106: 147-172.
Hidalgo JCG, Raventos J, Echevarria MT. 1997. Comparison of sediment ratio curves for plants with different architectures. Catena 29: 333-340.
Hooke JM, Sandercock PJ, van Wesemael B, Meerkerk A, Torri D, Borselli L, Salvador MP, Castillo V, Barberá GG, Navarro-Cano JA, Cammeraat LH, Lesschen LP, Poesen J, De Baets S, Marchamalo M. The connectivity approach to sustainable land management and soil erosion reduction in Mediterranean lands. Landscape Ecology. Submitted for publication.
Isselin-Nondedeu F, Bédécarrats A. 2007. Influence of alpine plants growing on steep slopes on sediment trapping and transport by runoff. Catena 71: 330-339.
Kouwen N, Li R, Members A. 1980. Biomechanics of vegetative channel linings. Journal of the Hydraulics Division 106: 1085-1103.
Kouwen N, Li RM, Simons DB. 1981. Flow resistance in vegetated waterways. Transactions of the American Society of Agricultural Engineers 24: 684-698.
Lesschen JP, Kok K, Verburg PH, Cammeraat LH. 2007. Identification of vulnerable areas for gully erosion under different scenarios of land abandonment in southeast Spain. Catena 71: 110-121.
Lesschen JP, Cammeraat LH, Nieman T. 2008. Erosion and terrace failure due to agricultural land abandonment in a semi-arid environment. Earth Surface Processes and Landforms 33: 1574-1584.
Lopez-Bermudez F, Barbera GG, Alonso-Sarria F, Belmonte Serrato F. 2002. Natural resources in the Guadalentin basin (south-east Spain): water as a key factor. In Mediterranean Desertification, A Mosaic of Processes and Responses, Brandt CJ, Geeson NA, Thornes JB (eds). John Wiley and Sons: Chichester; 233-245.
Maestre FT, Cortina J. 2002. Spatial patterns of surface soil properties and vegetation in a Mediterranean semi-arid steppe. Plant and Soil 241: 279-291.
Mant J. 2002. Vegetation in Ephemeral Channels of Southeast Spain: Its Impact on and Response to Morphological Change, PhD Thesis, Department of Geography, University of Portsmouth; 259-281.
Martinez-Raya A, Duran Zuazo VH, Francia Martinez JR. 2006. Soil erosion and runoff response to plant-cover strips on semiarid slopes (SE Spain). Land Degradation and Development 17: 1-11.
Matsushita N, Matoh T. 1991. Characterization of Na+ exclusion mechanisms of salt tolerant reed plants in comparison with salt-sensitive rice plants. Plant Physiology 83: 170-176.
Mattia C, Bischetti GB, Gentile F. 2005. Biotechnical characteristics of root systems of typical Mediterranean species. Plant and Soil 278: 23-32.
Morgan RPC. 2005. Soil Erosion and Conservation, 3rd edition. Blackwell Science: Oxford.
Navarro-Cano JA. 2004. Plant Species and Vegetation in Channels and Gullies in Cárcavo Basin, Internal Report for RECONDES Project. University of Portsmouth: Portsmouth.
Poesen J, Nachtegaele J, Verstraeten G, Valentin C. 2003. Gully erosion and environmental change: importance and research needs. Catena 50: 91-133.
Pugnaire F, Haase P. 1996. Comparative physiology and growth of two perennial tussock grass species in a semi-arid environment. Annals of Botany 77: 81-86.
Pugnaire FI, Luque MT, Armas C, Gutiérrez L. 2006. Colonization processes in semi-arid Mediterranean old-fields. Journal of Arid Environments 65: 591-603.
Puigdefabregas J, Alonso JM, Delagro L, Domingo F, Cueto M, Gutiírrez L, Lázaro R, Nicolau JM, Sùanchez G, Solé A, Vidal S. 1996. The Rambla Honda field site; interactions of soil and vegetation along a catena in semi-arid southeast Spain. In Mediterranean Desertification and Land Use, Brandt J, Thornes JB (eds). John Wiley and Sons: Chichester.
Quinton JN, Morgan RPC, Archer NA, Hall GM, Green A. 2002. Bioengineering principles and desertification mitigation. In Mediterranean Desertification, A Mosaic of Processes and Responses, Brandt CJ, Geeson NA, Thornes JB (eds). John Wiley and Sons: Chichester; 93-105.
Reubens B, Poesen J, Danjon F, Geudens G, Muys B. 2007. The role of fine and coarse roots in shallow slope stability and soil erosion control with a focus on root system architecture: a review. Trees - Structure and Function 21: 385-402.
Rey F. 2003. Influence of vegetation distribution on sediment yield in forested marly gullies. Catena 50: 549-562.
Robledo A, Rios S, Correal E. 1990-1991. Estimación de biomasa en los matorrales de albaida (Anthyllis cytisoides) del Suresta de Espana. Pastos 20-21: 107-129 (in Spanish).
Sandercock PJ, Hooke JM. Vegetation zonation and conditions for growth of plant species in ephemeral stream channels in SE Spain. River Research and Applications. Submitted for publication. a.
Sandercock PJ, Hooke JM. Assessment of vegetation effects on hydraulics and of feedbacks on plant survival and zonation in ephemeral channels. Hydrological Processes. Submitted for publication. b.
Sandercock PJ, Hooke JM, Mant JM. 2007. Vegetation in dryland river channels and its interaction with fluvial processes. Progress in Physical Geography 31: 107-129.
Simon A, Collison A. 2001. Scientific Basis for Streambank Stabilization using Riparian Vegetation. Proceedings of the Seventh Federal Interagency Sedimentation Conference, 25-29 March, Reno, NV; 47-54.
Snogerup S. 1993. A revision of Juncus subgen. Juncus (Juncaceae). Willdenowia 23: 23-73.
Styczen ME, Morgan RPC. 1995. Engineering properties of vegetation. In Slope Stabilization and Erosion Control: A Bioengineering Approach, Morgan RPC, Rickson RJ (eds). E&FN Spon: London; 5-58.
Tong STY. 1990. Growth analysis of Aristida coerulescens and Helictotrichon filifolium seedlings under simulated temperature and nutrient conditions. Journal of Arid Environments 19: 161-167.
Wu TH, McKinnell III WP, Swanston DN. 1979. Strength of tree roots and landslides on Prince of Wales Island, Alaska. Canadian Geotechnical Journal 16: 19-33.