Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-20T02:46:28.621Z Has data issue: false hasContentIssue false
  • English
  • Français

Water flow in soil from organic dairy rotations

Published online by Cambridge University Press:  22 February 2017

M. LAMANDÉ ,
J. ERIKSEN ,
P. H. KROGH  and
O. H. JACOBSEN
M. LAMANDÉ*
Affiliation:
Faculty of Science and Technology, Department of Agroecology, Aarhus University, Research Centre Foulum, P.O. Box 50, DK-8830 Tjele, Denmark Faculty of Environmental Sciences and Natural Resource Management, Norwegian University of Life Sciences, P.O. Box 5003 NMBU, 1432 Ås, Norway
J. ERIKSEN
Affiliation:
Faculty of Science and Technology, Department of Agroecology, Aarhus University, Research Centre Foulum, P.O. Box 50, DK-8830 Tjele, Denmark
P. H. KROGH
Affiliation:
Faculty of Science and Technology, Department of Bioscience, Aarhus University, Vejlsøvej 25, Silkeborg, Denmark
O. H. JACOBSEN
Affiliation:
Faculty of Science and Technology, Department of Agroecology, Aarhus University, Research Centre Foulum, P.O. Box 50, DK-8830 Tjele, Denmark
*
*To whom all correspondence should be addressed. Email: [email protected]
Get access Rights & Permissions [Opens in a new window]

Summary

Managed grasslands are characterized by rotations of leys and arable crops. The regime of water flow evolves during the leys because of earthworm and root activity, climate and agricultural practices (fertilizer, cutting and cattle trampling). The effects of duration of the leys, cattle trampling and fertilizer practice on the movement of water through sandy loam soil profiles were investigated in managed grassland of a dairy operation. Experiments using tracer chemicals were performed, with or without cattle slurry application, with cutting or grazing, in the 1st and the 3rd year of ley, and in winter rye. Each plot was irrigated for an hour with 18·5 mm of water containing a conservative tracer, potassium bromide; 24 h after irrigation, macropores >1 mm were recorded visually on a horizontal plan of 0·7 m2 at five depths (10, 30, 40, 70 and 100 cm). The bromide (Br) concentration in soil was also analysed at these depths and the density of the different earthworm species were recorded. The density of macropores was not directly influenced by the factors investigated. The abundance of anecic earthworms was larger after 3 years of ley and was not affected by grazing (trampling or dung pat deposits) or fertilizer practice. The water infiltration estimated from the Br concentration was not influenced by fertilizer practice and was reduced after 3 years of ley due to settlement, but was greater than that for the arable phase of the rotation. As shown by Br concentration, preferential flow was induced by the grazing regime. Infiltrating water may bypass the soil matrix under similar or more extreme conditions than in the current experiment. Such hydraulic functioning in the grazing regime is expected to reduce the risk of leaching of nitrate contained in soil water.

Type
Crops and Soils Research Papers
Information
The Journal of Agricultural Science , Volume 155 , Issue 7 , September 2017 , pp. 1113 - 1123
Check for updates
Copyright
Copyright © Cambridge University Press 2017 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Afzal, M. & Adams, W. A. (1992). Heterogeneity of soil mineral nitrogen in pasture grazed by cattle. Soil Science Society of America Journal 56, 11601166.CrossRefGoogle Scholar
Arah, J. R. M. & Ball, B. C. (1994). A functional model of soil porosity used to interpret measurements of gas diffusion. European Journal of Soil Science 45, 135144.Google Scholar
Beven, K. & Germann, P. (2013). Macropores and water flow in soils revisited. Water Resources Research 49, 30713092.Google Scholar
Bouché, M. B. (1977). Stratégies lombriciennes. In Soil Organisms as Components of Ecosystems. Proceedings of the Sixth Int. Colloquium on Soil Zoology (Eds Lohm, U. & Persson, T.), pp. 122133. Ecological Bulletin no. 25. Stockholm, Sweden: Swedish Natural Science Research Council.Google Scholar
Caron, J., Banton, O., Angers, D. A. & Villeneuve, J. P. (1996). Preferential bromide transport through a clay loam under alfalfa and corn. Geoderma 69, 175191.CrossRefGoogle Scholar
Clay, D. E., Zheng, Z., Liu, Z., Clay, S. A. & Trooien, T. P. (2004). Bromide and nitrate movement through undisturbed soil columns. Journal of Environmental Quality 33, 338342.Google Scholar
Cluzeau, D., Binet, F., Vertès, F., Simon, J. C., Rivière, J.-M. & Tréhen, P. (1992). Effects of intensive cattle trampling on soil-plant-earthworms system in two grassland types. Soil Biology & Biochemistry 24, 16611665.Google Scholar
Curry, J. P. (2004). Factors affecting the abundance of earthworms in soils. In Earthworm Ecology (Ed. Edwards, C. A.), pp. 91114. Boca Raton, FL: CRC Press.Google Scholar
Curry, J. P., Doherty, P., Purvis, G. & Schmidt, O. (2008). Relationships between earthworm populations and management intensity in cattle-grazed pastures in Ireland. Applied Soil Ecology 39, 5864.Google Scholar
Cuttle, S. P. & Bourne, P. C. (1993). Uptake and leaching of nitrogen from artificial urine applied to grassland on different dates during the growing season. Plant & Soil 150, 7786.CrossRefGoogle Scholar
da Silva, A. P., Imhoff, S. & Corsi, M. (2003). Evaluation of soil compaction in an irrigated short-duration grazing system. Soil & Tillage Research 70, 8390.Google Scholar
Di, H. J. & Cameron, K. C. (2016). Inhibition of nitrification to mitigate nitrate leaching and nitrous oxide emissions in grazed grassland: a review. Journal of Soils and Sediments 16, 14011420.Google Scholar
Drees, L. R., Karathanasis, A. D., Wilding, L. P. & Blevins, R. L. (1994). Micro-morphological characteristics of long-term and no-till and conventionally tilled soils. Soil Science Society of America Journal 58, 508517.Google Scholar
Eriksen, J. & Høgh-Jensen, H. (1998). Variations in the natural abundance of 15N in ryegrass/white clover shoot material as influenced by cattle grazing. Plant & Soil 205, 6776.CrossRefGoogle Scholar
Eriksen, J., Askegaard, M. & Kristensen, K. (1999). Nitrate leaching in an organic dairy/crop rotation as affected by organic manure type, livestock density and crop. Soil Use & Management 15, 176182.Google Scholar
Eriksen, J., Vinther, F. P. & Søegaard, K. (2004 a). Nitrate leaching and N2-fixation in grasslands of different composition, age and management. Journal of Agricultural Science, Cambridge 142, 141151.Google Scholar
Eriksen, J., Askegaard, M. & Kristensen, K. (2004 b). Nitrate leaching from an organic dairy crop rotation; the effect of manure type, N-input and improved crop rotation. Soil Use & Management 20, 4854.Google Scholar
Eriksen, J., Askegaard, M. & Søegaard, K. (2014). Complementary effects of red clover inclusion in ryegrass-white clover swards for grazing and cutting. Grass & Forage Science 69, 241250.Google Scholar
Eriksen, J., Askegaard, M., Rasmussen, J. & Søegaard, K. (2015). Nitrate leaching and residual effect in dairy crop rotations with grass-clover leys as influenced by sward age, grazing, cutting and fertilizer regimes. Agriculture, Ecosystems and Environment 212, 7584.Google Scholar
Flury, M. & Papritz, A. (1993). Bromide in the natural environment: occurrence and toxicity. Journal of Environmental Quality 22, 747758.CrossRefGoogle Scholar
Frede, H.-G., Beisecker, R. & Gäth, S. (1994). Long-term impacts of tillage on the soil ecosystem. Zeitschrift für Pflanzenernährung und Bodenkunde (Journal of Plant Nutrition and Soil Science) 157, 197203.Google Scholar
Hangen, E., Buczko, U., Bens, O., Brunotte, J. & Huttl, R. F. (2002). Infiltration patterns into two soils under conventional and conservation tillage: influence of the spatial distribution of plant root structures and soil animal activity. Soil & Tillage Research 63, 181186.Google Scholar
Haynes, R. J. & Williams, P. H. (1993). Nutrient cycling and soil fertility in the grazed pasture ecosystem. Advances in Agronomy 49, 119199.Google Scholar
Heidmann, T. (1989). Startkarakterizering af Arealer til Systemforskning. II. Resultater fra Arealet ved Foulum. Tidsskrift for Plantavls (Journal of Plant Breeding) Special Report no. S 2007. Kongens Lyngby, Denmark: Statens Planteavlsforsøg.Google Scholar
Herbin, T., Hennessy, D., Richards, K. G., Piwowarczyk, A., Murphy, J. J. & Holden, N. M. (2011). The effects of dairy cow weight on selected soil physical properties indicative of compaction. Soil Use & Management 27, 3644.CrossRefGoogle Scholar
Humphreys, J., O'Connell, K. & Casey, I. A. (2008 a). Nitrogen flows and balances in four grassland-based systems of dairy production on a clay-loam soil in a moist temperate climate. Grass and Forage Science 63, 467480.Google Scholar
Humphreys, J., Casey, I. A., Darmody, P., O'Connell, K., Fenton, O. & Watson, C. J. (2008b). Quantities of mineral N in soil and concentrations of nitrate-N in groundwater in four grassland-based systems of dairy production on a clay-loam soil in a moist temperate climate. Grass and Forage Science 63, 481494.Google Scholar
Jacobsen, O. H. (1989). Unsaturated Hydraulic Conductivity for Some Danish Soils. Methods and Characterization of Soils. Tidsskrift for Plantavls (Journal of Plant Breeding) Special Report no. S2030. Kongens Lyngby, Denmark: Statens Planteavlsforsøg.Google Scholar
Jacobsen, O. H. & Iversen, B. V. (2004). Tracerforsøg med Sulforhodamin B og bromid til kortlægning af hydraulisk aktive strømningsveje. In Afprøvning af Undersøgelser med Henblik på Etablering af et Zoneringskoncept for Danske Lerjorde: Statusrapport (Ed. Ernstsen, V.), Annex 8, 4 pp. Tjele, Midtjylland, Denmark: Danmarks og Grønlands Geologiske Undersøgelse, Danmarks Jordbrugsforskning. (in Danish)Google Scholar
James, S. W., Porco, D., Decaëns, T., Richard, B., Rougerie, R. & Erséus, C. (2010). DNA barcoding reveals cryptic diversity in Lumbricus terrestris L., 1758 (Clitellata): resurrection of L. herculeus (Savigny, 1826). PLoS ONE 5, e15629. doi:10.1371/journal.pone.0015629 Google Scholar
Jarvis, N. J. (2007). A review of non-equilibrium water flow and solute transport in soil macropores: principles, controlling factors and consequences for water quality. European Journal of Soil Science 58, 523546.Google Scholar
Kooistra, M. J. & Tovey, N. K. (1994). Effects of compaction on soil microstructure. In Soil Compaction in Crop Production (Eds Soane, B. D. & van Ouwerkerk, C.), pp. 91111. Developments in Agricultural Engineering 11. Amsterdam, the Netherlands: Elsevier.CrossRefGoogle Scholar
Kramers, G., Richards, K. G. & Holden, M. N. (2009). Assessing the potential for the occurrence and character of preferential flow in three Irish grassland soils using image analysis. Geoderma 153, 362371.Google Scholar
Kulli, B., Gysi, M. & Flühler, H. (2003). Visualizing soil compaction based on flow pattern analysis. Soil & Tillage Research 70, 2940.Google Scholar
Kung, K.-J. S. (1990). Influence of plant uptake on the performance of Bromide tracer. Soil Science Society of America Journal 54, 975979.Google Scholar
Kurz, I., O'Reilly, C. D. & Tunney, H. (2006). Impact of cattle on soil physical properties and nutrient concentrations in overland flow from pasture in Ireland. Agriculture, Ecosystems & Environment 113, 378390.Google Scholar
Lamandé, M., Hallaire, V., Curmi, P., Pérès, G. & Cluzeau, D. (2003). Changes of pore morphology, infiltration and earthworm community in a loamy soil under different agricultural managements. Catena 54, 637649.Google Scholar
Lamandé, M., Labouriau, R., Holmstrup, M., Torp, S. B., Greve, M. H., Heckrath, G., Iversen, B. V., de Jonge, L. W., Moldrup, P. & Jacobsen, O. H. (2011). Density of macropores as related to soil and earthworm community parameters in cultivated grasslands. Geoderma 162, 319326.Google Scholar
Larsbo, M., Jarvis, N. (2003). Macro 5·0. A Model of Water Flow and Solute Transport in Macroporous Soil. Technical Description. Report: Emergo 2003: 6. Uppsala, Sweden: Swedish University of Agricultural Sciences, Dept. of Soil Science.Google Scholar
Larsson, M. H. & Jarvis, N. J. (1999). A dual-porosity model to quantify macropore flow effect on nitrate leaching. Journal of Environment Quality 28, 12981307.Google Scholar
Martinsson, S. & Erséus, C. (2017). Cryptic speciation and limited hybridization within Lumbricus earthworms (Clitellata: Lumbricidae). Molecular Phylogenetics and Evolution 106, 1827.Google Scholar
Mapfumo, E., Chanasyk, D. S., Naeth, M. A. & Baron, V. S. (1999). Soil compaction under grazing of annual and perennial forages. Canadian Journal of Soil Science 79, 191199.CrossRefGoogle Scholar
Maw, G. A. & Kempton, R. J. (1982). Bromine in soils and peats. Plant and Soil 65, 103109.Google Scholar
Mossadeghi-Björklund, M., Arvidsson, J., Keller, T., Koestel, J., Lamandé, M., Larsbo, M. & Jarvis, N. (2016). Effects of subsoil compaction on hydraulic properties and preferential flow in a Swedish clay soil. Soil & Tillage Research 156, 9198.Google Scholar
Mulholland, B. & Fullen, M. A. (1991). Cattle trampling and soil compaction on loamy sands. Soil Use and Management 7, 189193.Google Scholar
Murphy, B. W., Koen, T. B., Jones, B. A. & Huxedurp, L. M. (1993). Temporal variation of hydraulic properties for some soils with fragile structure. Australian Journal of Soil Research 31, 179197.Google Scholar
Nieminen, M., Ketoja, E., Mikola, J., Terhivuo, J., Siren, T. & Nuutinen, V. (2011). Local land use effects and regional environmental limits on earthworm communities in Finnish arable landscapes. Ecological Applications 21, 31623177.Google Scholar
Nimmo, J. R. (2012). Preferential flow occurs in unsaturated conditions. Hydrological Processes 26, 786789.Google Scholar
Or, D. & Ghezzehei, T. A. (2002). Modeling post-tillage soil structural dynamics: a review. Soil & Tillage Research 64, 4159.Google Scholar
Osunbitan, J. A., Oyedele, D. J. & Adekalu, K. O. (2005). Tillage effects on bulk density, hydraulic conductivity and strength of a loamy sand soil in southwestern Nigeria. Soil & Tillage Research 82, 5764.Google Scholar
Patra, A. K. & Rego, T. J. (1996). Movement of bromide as a tracer for nitrate in an Alfisol of the Indian Semi-Arid Tropics under rainfed condition. Fertilizer Research 45, 111116.CrossRefGoogle Scholar
Petersen, C. T., Hansen, S. & Jensen, H. E. (1997). Tillage-induced horizontal periodicity of preferential flow in the root zone. Soil Science Society of America Journal 61, 586594.Google Scholar
Phelan, P., Keogh, B., Casey, I. A., Necpalova, M. & Humphreys, J. (2013). The effects of treading by dairy cows on soil properties and herbage production for three white clover-based grazing systems on a clay loam soil. Grass and Forage Science 68, 548563.Google Scholar
Piearce, T. G. (1984). Earthworm populations in soils disturbed by trampling. Biological Conservation 29, 241252.Google Scholar
Pietola, L., Horn, R. & Yli-Halla, M. (2005). Effects of trampling by cattle on the hydraulic and mechanical properties of soil. Soil & Tillage Research 82, 99108.CrossRefGoogle Scholar
Pizl, V. (1992). Succession of earthworm populations in abandoned fields. Soil Biology & Biochemistry 24, 16231628.Google Scholar
Rodd, A. V., Papadoloulos, Y. A., Laflamne, L. F., McRae, K. B., Fillmore, S. A. E. & Wilson, R. W. (1999). Effect of rotational grazing on selected physical properties of a Gleyed Brunisolic Gray Luvisol loam in Nova Scotia. Canadian Journal of Soil Science 79, 117125.Google Scholar
SAS Institute Inc. (2004). SAS/STAT® 9·1 User's Guide. Cary, NC: SAS Institute Inc.Google Scholar
Schneider, C. A., Rasband, W. S. & Eliceiri, K. W. (2012). NIH image to imageJ: 25 years of image analysis. Nature Methods 9, 671675.Google Scholar
Schwen, A., Yang, Y., Walton, R. J. & Wendroth, O. (2012). A new experimental design reveals the impacts of land use and irrigation characteristics on bromide leaching. Vadose Zone Journal 11. https://doi.org/10.2136/vzj2012.0077 CrossRefGoogle Scholar
Silva, R. G., Cameron, K. C., Di, H. J. & Hendry, T. (1999). A lysimeter study of the impact of cow urine, dairy shed effluent and nitrogen fertilizer on drainage water quality. Australian Journal of Soil Research 37, 357369.Google Scholar
Silvertooth, J. C., Watson, J. E., Malcuit, J. E. & Doerge, T. A. (1992). Bromide and nitrate movement in an irrigated cotton production system. Soil Science Society of America Journal 56, 548555.Google Scholar
Sims, R. W. & Gerard, B. M. (1985). Earthworms. Keys and Notes to the Identification and Study of the Species. Synopsis of the British Fauna (New Series) no. 31. London, UK: Brill/Backhuys.CrossRefGoogle Scholar
Smith, S. J. & Davis, R. J. (1974). Relative movement of bromide and nitrate through soils. Journal of Environmental Quality 3, 152155.Google Scholar
Soil Survey Division Staff (1993). Soil Survey Manual. USDA Handbook 18. Washington, DC: USDA/SCS.Google Scholar
Somaratne, N. M. & Smettem, K. R. J. (1993). Effect of cultivation and raindrop impact on the surface hydraulic properties of an alfisol under wheat. Soil and Tillage Research 26, 115125.CrossRefGoogle Scholar
Tuohy, P., Fenton, O., Holden, N. M. & Humphreys, J. (2015). The effects of treading by two breeds of dairy cow with different live weights on soil physical properties, poaching damage and herbage production on a poorly drained clay-loam soil. Journal of Agricultural Science, Cambridge 153, 14241436.Google Scholar
van Grinsven, H. J. M., ten Berge, H. F. M., Dalgaard, T., Fraters, B., Durand, P., Hart, A., Hofman, G., Jacobsen, B. H., Lalor, S. T. J., Lesschen, J. P., Osterburg, B., Richards, K. G., Techen, A.-K., Vertès, F., Webb, J. & Willems, W. J. (2012). Management, regulation and environmental impacts of nitrogen fertilization in northwestern Europe under the Nitrates Directive; a benchmark study. Biogeosciences 9, 51435160.Google Scholar
Vertès, F., Hatch, D., Velthof, G., Taube, F., Laurent, F., Loiseau, P. & Recous, S. (2007). Short-term and cumulative effects of grassland cultivation on nitrogen and carbon cycling in ley-arable rotations. Grassland Science in Europe 12, 227246.Google Scholar
Warren, S. D., Nevill, M. B., Blackburn, W. H. & Garza, N. E. (1986). Soil response to trampling under intensive rotation grazing. Soil Science Society of America Journal 50, 13361341.Google Scholar
Yang, Y. & Wendroth, O. (2014). State-space approach to analyse field-scale bromide leaching. Geoderma 217–218, 161172.CrossRefGoogle Scholar