Effects of soil erosion on the floristic composition of plant communities on marl in northeast Spain

Joaquín Guerrero-Campo,

Corresponding Author

Joaquín Guerrero-Campo

Instituto Pirenaico de Ecología (C.S.I.C.) Aptdo. 202, 50080 Zaragoza, Spain

Corresponding author; Fax +34976575884; E-mail [email protected]Search for more papers by this author

Gabriel Montserrat-Martí,

Gabriel Montserrat-Martí

Instituto Pirenaico de Ecología (C.S.I.C.) Aptdo. 202, 50080 Zaragoza, Spain

Search for more papers by this author

Joaquín Guerrero-Campo,

Corresponding Author

Joaquín Guerrero-Campo

Instituto Pirenaico de Ecología (C.S.I.C.) Aptdo. 202, 50080 Zaragoza, Spain

Corresponding author; Fax +34976575884; E-mail [email protected]Search for more papers by this author

Gabriel Montserrat-Martí,

Gabriel Montserrat-Martí

Instituto Pirenaico de Ecología (C.S.I.C.) Aptdo. 202, 50080 Zaragoza, Spain

Search for more papers by this author

First published: 24 February 2000

https://doi.org/10.2307/3236625

Citations: 32

About

PDF

Tools

Share a link

Email
Facebook
Twitter
LinkedIn
Reddit
Wechat

Abstract

Abstract. This study explored the validity of three responses of vegetation to increased soil erosion: reduction of vegetation cover, number of species and reduced substitution of species.

201 relevés, including edaphic and geomorphological data, were surveyed in the intensely eroded Eocene marls of the Prepyrenees (NE Spain). Changes in plant species’ presence in relevés from different degradation stages were compared. The level of vegetation degradation was defined as the total phanerogam cover which, in the studied area, was correlated to the degree of soil erosion. The considered trends were validated. Reduction of phanerogam cover and species number were gradual from low to high-eroded areas. Vegetation degradation explained 48% of the species number variance. In the later stages of degradation a significant substitution of species was not observed, only a lower frequency of occurrence of several species that appeared in the whole set of relevés. Through the process of degradation, 47% of species displayed significantly reduced frequencies as degradation increased, none showed a significant increase in frequency.

It is concluded that there are no characteristic species in these plant communities that survive in the severely eroded marls. Among the few species that had increased in frequency, most only colonised favourable micro-environments.

References

Anon 1976. Conservation in arid and semi-arid zones. FAO Conservation Guide, 3. FAO, Rome .

Web of Science®Google Scholar
Anon 1980. Mapa Geológico de España 1: 200.000. Huesca n° 23. Instituto Geológico y Minero de España, Madrid .

Google Scholar
Anon 1991. Caracterización agroclimática de la provincia de Huesca. Ministerio de Agricultura, Pesca y Alimentación, Madrid .

Google Scholar
Allegrezza, M., Biondi, E., Brilli-Cattarini, A.J.B. & Gubellini, L. 1993. Emergenze floristiche e caratteristiche vegetazionali dei calanchi della Val Marecchia. Biogeographia 17: 25–49.

Google Scholar
Almorox, J., De Antonio, R., Saa, A., Cruz Díaz, M. & Gascó, J.M. 1994. Métodos de estimación de la erosión hídrica. Editorial Agrícola Española, Madrid .

Google Scholar
Bauer, E. 1991. Los montes de España en la historia. Ministerio de Agricultura, Pesca y Alimentación, Fundación Conde del Valle de Salazar, Madrid .

Google Scholar
Biondi, E., Allegrezza, M., Guitian, J. & Taffetani, F. 1988. La vegetazione dei calanchi di Sasso Simone e Simoncello (Appennino tosco-marchigiano). Braun-Blanquetia 2: 105–115.

Google Scholar
Biondi, E., Ballelli, S., Allegrezza, M. & Manzi, A. 1990. La vegetazione dei calanchi di Gessopalena (Abruzzo meridionale). Doc. Phytosociol. 12: 257–263.

Google Scholar
Biondi, E., Ballelli, S. & Taffetani, F. 1992. La vegetazione di alcuni territori calanchivi in Basilicata (Italia meridionale). Doc. Phytosociol. 14: 489–498.

Google Scholar
Braun-Blanquet, J. 1979. Fitosociologia. Bases para el estudio de las comunidades vegetales. J. H. Blume, Madrid .

Google Scholar
Brown, R.W. 1971. Distribution of plant communities in southeastern Montana badlands. Am. Midl. Nat. 85: 458–477.
10.2307/2423769
Web of Science®Google Scholar
Butler, J., Goetz, H. & Richardson, J.L. 1986. Vegetation and soil-landscape relationships in the North-Dakota badlands. Am. Midl. Nat. 116: 378–386.
10.2307/2425746
Web of Science®Google Scholar
S. Castroviejo et al., (eds.) 19861997. Flora Iberica. Real Jardín Botánico (C.S.I.C), Madrid .

Google Scholar
Cervera, M., Clotet, N., Guardia, R. & Sole-Sugrañes, L. 1991. Response to rainfall simulation from scarcely vegetated and non-vegetated badlands. Catena Suppl. 19: 39–56.

Web of Science®Google Scholar
Chiarucci, A., De Dominicis, V., Ristori, J. & Calzolari, C. 1995. Biancana badland vegetation in relation to morphology and soil in Orcia valley, central Italy. Phytocoenologia 6: 69–87.
10.1127/phyto/25/1995/69
Google Scholar
Dissmeyer, G.E. & Foster, G.R. 1981. Estimating the cover-management factor (C) in the universal soil loss equation for forest conditions. J. Soil Water Conserv. 235–240.

Web of Science®Google Scholar
Ferrari, C. & Gerdol, R. 1987. Numerical syntaxonomy of badland vegetation in the Apennines (Italy). Phytocoenologia 15: 21–37.
10.1127/phyto/15/1987/21
Google Scholar
García-Fayos, P., Recatalá, T.M., Cerdá, A. & Calvo, A. 1995. Seed population dynamics on badland slopes in southeastern Spain. J. Veg. Sci. 6: 691–696.
10.2307/3236439
Web of Science®Google Scholar
García-Ruiz, J.M. & Lasanta-Martínez, T. 1990. Land-use in the Spanish Pyrenees. Mountain Res. Developm. 50: 266–279.

Google Scholar
García-Ruiz, J.M. 1996. Marginación de tierras y erosión en áreas de montaña. In: T. Lasanta & J.M. García-Ruiz (eds.). Erosión y recuperación de tierras en áreas marginales pp. 33–50. Instituto de Estudios Riojanos. Sociedad Española de Geomorfología, Logroño .

Google Scholar
Grime, J.P. 1979. Plant strategies and vegetation processes. John Wiley, Chichester .

PubMedGoogle Scholar
Guardia, R. 1995. La colonització vegetal de les áreas erosionades de la conca de la Baells (Alt Llobregat). Ph.D. Thesis. Universitat de Barcelona.

Google Scholar
Guardia, R. & Ninot, J.M. 1992. Distribution of plant communities in the badlands of the upper Llobregat basin (Southeastern Pyrenees). Stud. Geobot. 12: 83–103.

Google Scholar
Guardia, R., Ninot, J.M. & Clotet, N. 1992. On the vegetation-topography relationship in the badlands of the upper Llobregat basin (Southeastern Pyrenees). Geooko Plus 3: 45–54.

Google Scholar
Guerra, D.A. & Monturiol, D.F. 1970. Mapas de suelos de las provincias de Zaragoza, Huesca y Logroño. Memoria explicativa. Consejo Superior de Investigaciones Científicas, Madrid .

Google Scholar
Guerrero-Campo, J. 1998. Respuestas de la vegetación y de la morfología de las plantas a la erosión del suelo. Valle del Ebro y Prepirineo Aragonés. Consejo de Protección de la Naturaleza de Aragón, Zaragoza .

Web of Science®Google Scholar
Guerrero-Campo, J. & Montserrat Martí, G. 1996. La vegetación de zonas erosionadas en la Depresión Media del Ebro y en el Prepirineo. Influencia de factores climáticos, topográficos y geomorfológicos en la composición florística de las comunidades vegetales. Cad. Lab. Xeol. Laxe 21: 749–761.

Google Scholar
Guerrero-Campo, J. & Montserrat Martí, G. 1997. Patrones de distribución de las plantas en relación con los procesos erosivos intensos de los yesos de la Depresión del Ebro y de las margas del Prepirineo. In: F. Puertas Tricas & M. Rivas (eds.) II Congreso Forestal Español. Irati 97. Vol. 2., pp. 373–378. Gobierno de Navarra, Pamplona .

Google Scholar
Kopecký, K. & Hejný, S. 1974. A new approach to the classification of anthropogenic plant communities. Vegetatio 29: 17–20.
10.1007/BF02390892
Google Scholar
Lázaro Suau, R. 1995. Relaciones entre vegetación y geomorfologia en el área acarcavada del Desierto de Tabernas. PhD Thesis. Universidad de Valencia.

Google Scholar
Montserrat Recorder, P., Gastón Nicolas, R., Gómez García, D., Montserrat Martí, G. & Villar Pérez, L. 1988. Enciclopedia Temática de Aragón. Tomo 6. Flora. Ediciones Moncayo, Zaragoza .

Google Scholar
Montserrat Martí, J. 1992. Evolución glaciar y postglaciar del clima y la vegetación en la vertiente sur del Pirineo: Estudio palinológico. Instituto Pirenaico de Ecología, Zaragoza .

Google Scholar
R.P.C. Morgan & R.J. Rickson, (eds.) 1995. Slope stabilization and erosion control: a bioengineering approach. E & FN Spon, London .
10.4324/9780203362136
Google Scholar
Morgan, R.P.C., Rickson, R.J. & Wright, E. 1990. Regeneration of degraded soils. In: J. Albaladejo, M. A. Stocking & E. Díaz (eds.) Degradación y regeneración del suelo en condiciones ambientales mediterráneas. Soil degradation and rehabilitation in mediterranean environmental conditions, pp. 69–86. Consejo Superior de Investigaciones Cientificas, Murcia .

Google Scholar
Puigdefábregas, J. 1996. El papel de la vegetación en la conservación del suelo en ambientes semiáridos. In: T. Lasanta & J.M. García-Ruiz (eds.) Erosión y recuperación de tierras en áreas marginales, pp. 79–87. Instituto de Estudios Riojanos. Sociedad Española de Geomorfología, Logroño .

Google Scholar
Siegel, S. 1975. Estadística no paramétrica. Editorial Trillas, México .

Google Scholar
Thornes, J.B. 1985. The ecology of erosion. Geography 70: 222–235.

Web of Science®Google Scholar
Thornes, J.B. 1990. The interaction of erosional and vegetational dynamics in land degradation: spatial outcomes. In: J.B. Thornes (ed.) Vegetation and erosion, pp. 41–53. John Wiley & Sons, Chichester .

Google Scholar
Thornes, J.B. & Brandt, J. 1994. Erosion-vegetation competition in a stochastic environment undergoing climatic change. In: A.C. Millington & K. Pye (eds.) Environmental change in drylands: biogeographical and geomorphological perspectives, pp. 305–320. John Wiley & Sons, Chichester .

Web of Science®Google Scholar
Tsuyuzaki, S. & Titus, J. 1996. Vegetation development patterns in erosive areas on the Pumice Plains of Mount St. Helens. Am. Midl. Nat. 135: 172–177.
10.2307/2426883
Web of Science®Google Scholar
Tsuyuzaki, S., Titus, J.H. & del Moral, R. 1997. Seedling establishment patterns on the Pumice Plain, Mount St. Helens, Washington. J. Veg. Sci. 8: 727–734.
10.2307/3237378
Web of Science®Google Scholar
T.G. Tutin et al., (eds.) 19641980. Flora Europaea. Cambridge University Press, Cambridge .

Web of Science®Google Scholar
Umbanhowar, C.E., Jr. 1995. Revegetation of earthen mounds along a topographic-productivity gradient in a northern mixed prairie. J. Veg. Sci. 6: 637–646.
10.2307/3236434
Web of Science®Google Scholar
Villar, L., Sesé, J.A. & Ferrández, J.V. 1997. Atlas de la flora del Pirineo Aragonés. Vol. I. Consejo de Protección de la Naturaleza de Aragón. Instituto de Estudios Altoaragoneses, Huesca .

Google Scholar
Zar, J.H. 1984. Biostatistical Analysis. Prentice-Hall, London .

Google Scholar

Citing Literature

Volume11, Issue3

June 2000

Pages 329-336

Effects of soil erosion on the floristic composition of plant communities on marl in northeast Spain

Abstract

References

Citing Literature

References

Information

About Wiley Online Library

Help & Support

Opportunities

Connect with Wiley

Effects of soil erosion on the floristic composition of plant communities on marl in northeast Spain

Abstract

References

Citing Literature

References

Related

Information