Abstract
Soil aggregate stability, organic matter content, pH, bulk density, strength, and macropore attributes were assessed in order to evaluate the influence of grass root growth in a field sward. The amount of grass grown was varied by varying the quantity of applied nitrogen fertilizer: following one year with a uniform application rate, nitrogen fertilizer was applied over the subsequent three years to a compact soil at zero (N0), moderate (N1) and high (N2) rates. Differences in herbage production were evident in the three years of the contrasting nitrogen treatments. An index of soil aggregate stability increased in response to the increased grass growth promoted by heavier applications of nitrogen, but both bulk density and vane shear strength were unchanged. Binary images of the soil solid and pore space showed that for each treatment the largest volume of macropores occurred close to the surface, particularly in N0 where there was more pore space than in either N1 or N2. Analysis of the pore structure attributes of the binary images revealed further differences between treatments, in particular, at 40–80 mm depth, the soil in treatment N0 had fewer and smaller pores, and greater distance between pores, than the soil in the N1 and N2 treatments. The larger macropore volume in N1 and N2 constituted a major portion of the air-filled porosity when the soil was relatively wet. It was concluded that the root growth in the intensively cropped grassland was conducive to maintenance of a relatively stable and porous soil structure. An attendant increase in soil acidity close to the soil surface was a disadvantage of the larger nitrogen inputs.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barley K P 1954 Effects of root growth and decay on the permeability of a synthetic sandy loam. Soil Sci. 78, 205–210.
Campbell D J, Dickson J W, Ball B C and Hunter R 1986 Controlled seedbed traffic after ploughing or direct drilling under winter barley in Scotland, 1980–1984. Soil Tillage Res. 8, 3–28.
Dexter A R 1991 Amelioration of soil by natural processes. Soil Tillage Res. 22, 87–100.
Delesse M A 1847 Procédé mécanique pour déterminer la composition des roches. CR Hebd Séanc Acad Sci 25, 544–545.
Douglas J T 1992 Responses of perennial forage crops to soil compaction. In Soil Compaction in Crop Production. Eds. BDSoane and CvanOuwerkerk. Elsevier, Amsterdam (In press).
Douglas J T and Crawford C E 1989 The response of ryegrass to soil compaction and applied nitrogen, 1988. Scottish Centre of Agricultural Engineering, Departmental Note 21. 23 p.
Douglas J T and Crawford C E 1991 Wheel-induced soil compaction effects on ryegrass production and nitrogen uptake. Grass Forage Science.
Douglas J T and Goss M J 1982 Stability and organic matter content of surface soil aggregates under different methods of cultivation and in grassland. Soil Tillage Res. 2, 155–175.
Elkins C B, Haarland R L and Hoveland C S 1977 Grass roots as a tool for penetrating soil hardpans and increasing crop yields. Proceedings of the 34th Southern Pasture And Forage Crop Improvement Conference, Auburn AL., pp 21–26.
Frede H-G 1987 The importance of pore volume and pore geometry to soil aeration. In Soil Compaction and Regeneration. Eds GMonnier and M JGoss. pp 25–29. AA Balkema, Rotterdam.
Goss M J 1987 The specific effect of roots on the regeneration of soil structure. In Soil Compaction and Regeneration. Eds GMonnier and M JGoss. pp 145–155. AA Balkema, Rotterdam.
Gradwell M W 1965 Soil physical conditions of winter and the growth of ryegrass plants. N.Z.J. Agric. Res. 8, 238–269.
Greacen E L, Farrell D A and Cockroft B 1968 Soil resistance to metal probes and plant roots. Transactions of the 9th International Society of Soil Science Congress 1, 769–779.
Gregory P J 1988 Growth and functioning of plant roots. In Russell's Soil Conditions and Plant Growth. Ed. A.Wild. p 113–167. Longman Scientific & Technical, London.
McBratney A B and Moran C J 1990 A rapid method of analysis for soil macropore structure. II. Stereological model, statistical analysis, and interpretation. Soil Sci. Soc. Am. J. 54, 509–515.
Moran C J, McBratney A B and Koppi A J 1989 A rapid method for analysis of soil macropore structure. I Specimen preparation and digital binary image production. Soil Sci. Soc. Am. J. 53, 921–928.
Moran C J, McBratney A B and Koppi A J 1990 The SOLICON soil imaging system: A description of the software. CSIRO Division of Soils, Divisional Report No. 110, Glen Osmond, South Australia. 134 p.
Ragg J M and Futty D W 1967 The soils of the country round Haddington and Eyemouth: Memoirs of the Soil Survey of Great Britain. Her Majesty's Stationary Office, London.
Ripley B D 1981 Spatial Statistics. Wiley, New York.
Russell E W 1961 Soil Conditions and Plant Growth. Ninth Edition. Longmans, London.
Russell R S 1977 Plant Root Systems: Their Function and Interaction with the Soil. McGraw-Hill (UK) Ltd, London.
Scottish Agricultural Colleges 1983 Fertilizer recommendations for grassland. Publication No. 108.
Stengel P, Douglas J T, Guérif J, Goss M J, Monnier G and Cannell R Q 1984 Factors influencing the variation of some properties of soils in relation to their suitability for direct drilling. Soil Tillage Res. 4, 35–53.
Thomas R and Evans C 1975 Field experience on grassland soils. In Soil Physical Conditions and Crop Production, Ministry of Agriculture, Fisheries and Food Technical Bulletin No. 29, pp 112–124. Her Majesty's Stationary Office, London.
Tinsley J 1950 The determination of organic carbon in soils by dichromate mixtures. Transactions of the 4th International Society of Soil Science Congress, 1, 161–164.
Whitehead D C 1970 The Role of Nitrogen in Grassland Productivity. Bulletin 48. Commonwealth Bureau of Pastures and Field Crops. Commonwealth Agriculture Bureau, Farnham Royal.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Douglas, J.T., Koppi, A.J. & Moran, C.J. Alteration of the structural attributes of a compact clay loam soil by growth of a perennial grass crop. Plant Soil 139, 195–202 (1992). https://doi.org/10.1007/BF00009310
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00009310