Friabilidad del suelo: métodos de estimación con énfasis en la determinación cuantitativa de la resistencia al rompimiento

Avila Pedraza, Edgar Alvaro

QRCode

Author

Avila Pedraza, Edgar Alvaro

Publisher

Universidad Nacional Abierta y a Distancia, UNAD

Bibliographic managers

Refworks

Zotero / EndNote / Mendeley

BibTeX

CiteULike

Metadata

Show full item record

Abstract

Entender el comportamiento de la friabilidad permite la toma de decisiones apropiadas para la reducción del consumo de energía, el manejo y la conservación de la calidad física del suelo. Este artículo sintetiza los métodos utilizados actualmente para la determinación de la friabilidad del suelo, con énfasis en el método de resistencia al rompimiento -RR-. La friabilidad puede ser determinada a partir de métodos cualitativos, semicuantitativos y cuantitativos. El análisis cualitativo se basa en el examen visual de la estructura y consistencia del suelo, mientras que el análisis semi-cuantitativo se centra en la cuantificación de la distribución de agregados o fragmentos producto del sometimiento del suelo a impacto por caída. Los métodos cuantitativos permiten determinar la friabilidad de forma directa mediante la resistencia del suelo, o de forma indirecta, por inferencia a partir del comportamiento de otras propiedades del suelo: curva de retención de agua, porosidad y funciones de pedotransferencia. El método cuantitativo de RR se realiza mediante la compresión de agregados naturales o remoldeados de suelo hasta lograr su fractura, y es uno de los más aceptados. Los métodos cualitativos se realizan directamente en campo, de manera fácil y rápida pero su resultado es menos confiable. Los métodos semicuantitativos, rompimiento del suelo por caída, pueden realizarse en campo o laboratorio pero no ofrecen información precisa sobre la resistencia del suelo. Los métodos cuantitativos, implican el transporte de las muestras al laboratorio, mayor tiempo de ejecución y equipos y personal especializado, pero sus resultados son más confiables y reproducibles.

College

http://hemeroteca.unad.edu.co/index.php/riaa/article/view/1840/2221
http://hemeroteca.unad.edu.co/index.php/riaa/article/view/1840/2059
/*ref*/Ball, B.C., Batey, T., and Munkholm, L.J. (2007). Field assessment of soil structural quality – a development of the Peerlkamp test. Soil Use Manage. 23, 329-337.
/*ref*/Barzegar, A.R., Murray, R.X., Churchman, G.J.; Rengasamy, P. (1994). The strength of remoulded soils as affected by exchangeable cations and dispersible clay. Aust. J. Soil Res. 32, 185-199.
/*ref*/Barzegar, A.R., Oades, J.M., Rengasamy, P., Murray, R.S. (1995). Tensile strength of dry, remoulded soils as affected by properties of the clay fraction. Geoderma 65, 93-108.
/*ref*/Blanco – Moure, N., Angurel, L.A., Moret-Fernández, D., López, M.V. (2012). Tensile strength and organic carbon of soil aggregates under long-term no tillage in semiarid Aragon (NE Spain). Geoderma 189-190, 423-430.
/*ref*/Braunack, M.V., Hewitt, J.S., and Dexter, A.R. (1979). Brittle fracture of soil aggregates and the compaction of aggregate beds. J. Soil Sci. 30, 653–667.
/*ref*/Dexter, A.R. (1988a). Advances in characterization of soil structure. Soil Till. Res. 11, 199–238.
/*ref*/Dexter, A.R. (1988b). Strength of soil aggregates and of aggregate beds. Catena Supplement 11, 35–52.
/*ref*/Dexter, A.R. (1997). Physical properties of tilled soil. Soil Till. Res. 43, 41-63.
/*ref*/Dexter, A.R. (2004a). Soil physical quality Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120, 201-214.
/*ref*/Dexter, A.R. (2004b). Soil physical quality: Part II. Friability, tillage, tilth and hard-setting. Geoderma 120, 215–225.
/*ref*/Dexter, A.R. & Kroesbergen, B. (1985). Methodology for determination of tensile strength of soil aggregates. J. Agr. Eng. Res. 31, 139–147.
/*ref*/Dexter, A.R. & Watts, C.W. (2001). Tensile strength and friability. In: Smith, K.A., Mullins, C.E. (Eds.), Soil and Environmental Analysis: Physical Methods. Segunda edición. Marcel Dekker Inc, New York, pp. 405–433.
/*ref*/Dexter, A.R. & Bird, N.R. (2001). Methods for predicting the optimum and the range of soil water contents for tillage based on the water retention curve. Soil Till. Res. 57, 203–212.
/*ref*/FAO - Organization of the United Nations Food and Agriculture. (2009). Guide for soil description. Fourth edition. Rome, pp. 49-52.
/*ref*/Guérif, J. 1990. Factors influencing compaction-induced increases in soil strength. Soil Till. Res. 16, 167–178.
/*ref*/Guimarães, R.M.L., Tormena, C.A., Alves, S.J., Fidalski, J. & Blainski, E. (2009). Tensile strength, friability and organic carbon in an oxisol under a crop-livestock system. Scientia Agricola. (Piracicaba, Brasil.), Vol.66, No4, 499-505.
/*ref*/Hadas, A. & Wolf, D. (1984). Refinement and re-evaluation of the drop-shatter soil fragmentation method. Soil Till. Res. 4, 237–249.
/*ref*/Hallett, P.D., Dexter, A.R. & Seville, J.P.K. (1995b). The application of fracture mechanics to crack propagation in dry soil. Eur. J. Soil Sci. 46, 591–599.
/*ref*/Imhoff, S., Da Silva, P.A. & Dexter, A.R. (2002). Factors contributing to the tensile strength and friability of Oxisols. Soil Sci. Soc. Am. J. 66, 1656-1661.
/*ref*/Karlen, D.L., Erbach, D.C., Kaspar, T.C., Colvin, T.S., Berry, E.C. & Timmons, D.R., (1990). Soil tilth: a review of past perceptions and future needs. Soil Sci. Soc. Am. J. 54, 153-161.
/*ref*/Kay, B.D. & Dexter, A.R. (1992). The influence of dispersible clay and wetting/drying cycles on the tensile strength of a red-brown earth. Aust. J. Soil Res. 30, 297-310.
/*ref*/Macks, S.P., Murphy, B.W., Cresswell, H.P. & Koen, T.B. (1996). Soil friability in relation to management history and suitability for direct drilling. Aust. J. Soil Res. 34, 343-360.
/*ref*/Marshall, T.J. & Quirk, J.P. (1950). Stability of structural aggregates of dry soil. Aust. J. Agr. Econ. 1, 266–275.
/*ref*/Mullins, C.E., MacLeod, D.A., Northcote, K.H., Tisdall, J.M. & Young, I.M. (1990). Hardsetting soils: Behaviour, occurrence and management. J. Adv. Soil Sci. 11, 37-108.
/*ref*/Munkholm, L. J. (2011). Soil friability: A review of the concept, assessment and effects of soil properties and management (Review). Geoderma 167-168, 236–246.
/*ref*/Munkholm, L.J. & Kay, B.D. (2002). Effect of water regime on aggregate-tensile strength, rupture energy, and friability. Soil Sci. Soc. Am. J. 66, 702-709.
/*ref*/Munkholm, L.J., Schjønning, P. & Kay, B.D. (2002a). Tensile strength of soil cores in relations to aggregate strength, soil fragmentation and pore characteristics. Soil Till. Res. 64, 125–135.
/*ref*/Munkholm, L.J., Schjønning, P., Debosz, K., Jensen, H.E. & Christensen, B.T. (2002b). Aggregate strength and mechanical behaviour of a sandy loam soil under long-term fertilization treatments. Eur. J. Soil Sci. 53, 129–137.
/*ref*/Munkholm, L.J., Heck, R.J. & Deen, B. (2012). Soil pore characteristics assessed from X-ray micro-CT derived images and correlations to soil friability. Geoderma 181-182, 22-29.
/*ref*/Peerlkamp, P.K. (1959). A visual method of soil structure evaluation. Meded. v.d. Landbouwhogeschool en pzoekingsstations van de Staat te Gent. XXIV No. 24, pp. 216–221.
/*ref*/Rahimi, H., Pazira, E. & Tajik, F. (2000). Effect of soil organic matter, electrical conductivity and sodium adsorption ratio on tensile strength of aggregates. Soil Till. Res. 54, 145-153.
/*ref*/Santos, G.G., da Silva, E., Marchao, R.B., da Silveira, P.M., Bruand, A., James, F. & Becquer, T. (2011). Analysis of physical quality of soil using the water retention curve: Validity of the S-index. C. R. Geoscience 343, 295-301.
/*ref*/Schjǿnning, P., Elmhot, S., Munkholm, L. J. & Debosz, K. (2002). Soil quality aspects of humid Sandy loams as influenced by organic and conventional long-term management. Agr. Ecosyst. Environ. 88, 195-214
/*ref*/Schjǿnning, P., De Jonge, L.W., Munkholm, L.J., Moldrup, P., Christensen, B.T. & Olesen, J.E. (2011). Clay dispersibility and soil friability-testing the soil clay-to-carbon saturation concept. Soil Science Society of America Journal. Special section: Soil Architecture and Function. Vadose Zone J. doi:10.2136/vzj2011.0067.
/*ref*/Seben, G. de F., Corá, J. E., Fernández, C. & Lal, R. (2013). Aggregate shape and tensile strength measurement. Technical Article. Soil Sci. 178 (6), 301-307.
/*ref*/Snyder, V.A., Vazquez, M.A., Martinez, G., Ramirez, L. & Hadas, A. (1995). Controlled displacement technique for measuring soil friability. Soil Sci. Soc. Am. J. 59, 44–52.
/*ref*/USDA. (1993). Soil Survey Manual. Soil Survey Division Staff. Handbook No 18, pp. 173-181.
/*ref*/USDA. (2002). Field Book for Describing and Sampling Soils. Versión 2.0. National Soil Survey Center. Natural Resources Conservation Service, pp. 2-42/2-60.
/*ref*/Utomo, W.H. & Dexter, A.R. (1981). Soil friability. J. Soil Sci. 32, 203–213.
/*ref*/Watts, C.W. & Dexter, A.R. (1998). Soil friability: theory, measurement and the effects of management and organic carbon content. Eur. J. Soil Sci. 49, 73–84.

Format

application/pdf
text/html

Type of digital resource

info:eu-repo/semantics/article
info:eu-repo/semantics/publishedVersion