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Soil-plant nitrogen dynamics following incorporation of a mature rye cover crop in a lettuce production system

Published online by Cambridge University Press:  27 March 2009

L. J. Wyland ,
L. E. Jackson  and
K. F. Schulbach
L. J. Wyland
Affiliation:
Department of Vegetable Crops, University of California, Davis, CA 95616, USA
L. E. Jackson
Affiliation:
Department of Vegetable Crops, University of California, Davis, CA 95616, USA
K. F. Schulbach
Affiliation:
Department of Vegetable Crops, University of California, Davis, CA 95616, USA
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Summary

Winter non-leguminous cover crops are included in crop rotations to decrease nitrate (NO3-N) leaching and increase soil organic matter. This study examined the effect of incorporating a mature cover crop on subsequent N transformations. A field trial containing a winter cover crop of Merced rye and a fallow control was established in December 1991 in Salinas, California. The rye was grown for 16 weeks, so that plants had headed and were senescing, resulting in residue which was difficult to incorporate and slow to decompose. Frequent sampling of the surface soil (0–15 cm) showed that net mineralizable N (anaerobic incubation) rapidly increased, then decreased shortly after tillage in both treatments, but that sustained increases in net mineralizable N and microbial biomass N in the cover-cropped soils did not occur until after irrigation, 20 days after incorporation. Soil NO3-N was significantly reduced compared to winter-fallow soil at that time. A 15N experiment examined the fate of N fertilizer, applied in cylinders at a rate of 12 kg 15N/ha at lettuce planting, and measured in the soil, microbial biomass and lettuce plants after 32 days. In the cover-cropped soil, 59% of the 15N was recovered in the microbial biomass, compared to 21% in the winter-bare soil. The dry weight, total N and 15N content of the lettuce in the cover-cropped cylinders were significantly lower; 28 v. 39% of applied 15N was recovered in the lettuce in the cover-cropped and winter-bare soils, respectively. At harvest, the N content of the lettuce in the cover-cropped soil remained lower, and microbial biomass N was higher than in winter-bare soils. These data indicate that delayed cover crop incorporation resulted in net microbial immobilization which extended into the period of high crop demand and reduced N availability to the crop.

Type
Crops and Soils
Information
The Journal of Agricultural Science , Volume 124 , Issue 1 , February 1995 , pp. 17 - 25
Copyright
Copyright © Cambridge University Press 1995

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References

Amato, M. & Ladd, J. N. (1980). Studies of nitrogen immobilization and mineralization in calcareous soils. V. Formation and distribution of isotope-labelled biomass during decomposition of 14C- and 15N-labelled plant material. Soil Biology and Biochemistry 12, 405411.CrossRefGoogle Scholar
Aulakh, M. S., Doran, J. W. & Mosier, A. R. (1992). Soil denitrification - significance, measurement, and effects of management. Advances in Soil Science 18, 157.Google Scholar
Azam, F., Simmons, F. W. & Mulvaney, R. L. (1993). Immobilization of ammonium and nitrate and their interaction with native N in three Illinois Mollisols. Biology and Fertility of Soils 15, 5054.CrossRefGoogle Scholar
Beare, M. H., Parmelee, R. W., Hendrix, P. F., Cheng, W., Coleman, D. C. & Crossley, D. A. (1992). Microbial and faunal interactions and effects on litter nitrogen and decomposition in agroecosystems. Ecological Monographs 62, 569591.CrossRefGoogle Scholar
Bristow, A. W., Ryden, J. C. & Whitehead, D. C. (1987). The fate at several time intervals of 15N-labelled ammonium nitrate applied to an established grass sward. Journal of Soil Science 38, 245254.CrossRefGoogle Scholar
Brookes, P. C., Landman, A., Pruden, G. & Jenkinson, D. S. (1985). Chloroform fumigation and the release of soil nitrogen: a rapid direct extraction method to measure microbial biomass nitrogen in soil. Soil Biology and Biochemistry 17, 837842.CrossRefGoogle Scholar
Brooks, P. D., Stark, J. M., McInteer, B. B. & Preston, T. (1989). Diffusion method to prepare soil extracts for automated nitrogen-15 analysis. Soil Science Society of America Journal 53, 17071711.CrossRefGoogle Scholar
Carlson, R. M. (1978). Automated separation and conductimetric determination of ammonia and dissolved carbon dioxide. Analytical Chemistry 50, 15281532.CrossRefGoogle Scholar
Carlson, R. M. (1986). Continuous flow reduction of nitrate to ammonium with granular zinc. Analytical Chemistry 58, 15901591.CrossRefGoogle Scholar
Doran, J. W. (1980). Soil microbial and biochemical changes associated with reduced tillage. Soil Science Society of America Journal 44, 765771.CrossRefGoogle Scholar
Doran, J. W. (1987). Microbial biomass and mineralizable nitrogen distributions in no-tillage and plowed soils. Biology and Fertility of Soils 5, 6875.CrossRefGoogle Scholar
Drury, C. F., Voroney, R. P. & Beauchamp, E. G. (1991). Availability of NH4-N to microorganisms and the soil internal N cycle. Soil Biology and Biochemistry 23, 165169.CrossRefGoogle Scholar
Follett, R. F. & Schimel, D. S. (1989). Effect of tillage practices on microbial biomass dynamics. Soil Science Society of America Journal 53, 10911096.CrossRefGoogle Scholar
Francis, G. S., Haynes, R. J., Sparling, G. P., Ross, D. J. & Williams, P. H. (1992). Nitrogen mineralization, nitrate leaching and crop growth following cultivation of a temporary leguminous pasture in autumn and winter. Fertilizer Research 33, 5970.CrossRefGoogle Scholar
Griffin, D. M. (1972). Ecology of Soil Fungi. Syracuse, NY: Syracuse University Press.Google Scholar
Hauck, R. D. (1982). Nitrogen - isotope-ratio analysis. In Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties (Eds Page, A. L., Miller, R. H. & Keeney, D. R.), pp. 735779. Madison, WI: ASA-CSSA-SSSA.Google Scholar
Haynes, R. J. (1986). The decomposition process: mineralization, immobilization, humus formation, and degradation. In Mineral Nitrogen in the Plant Soil System (Ed. Haynes, R. J.), pp. 52126. New York: Academic Press.Google Scholar
Hendrix, P. F., Parmelee, R. W., Crossley, A., Coleman, D. C., Odum, E. P. & Groffman, P. M. (1986). Detritus food webs in conventional and no-tillage agroecosystems. BioScience 36, 374380.CrossRefGoogle Scholar
Herman, W. A., McGill, W. B. & Dormaar, J. F. (1977). Effect of initial chemical composition on decomposition of roots of three grass species. Canadian Journal of Soil Science 57, 205215.CrossRefGoogle Scholar
Holland, E. A. & Coleman, D. C. (1987). Litter placement effects on microbial and organic matter dynamics in an agroecosystem. Ecology 68, 425433.CrossRefGoogle Scholar
Jackson, L. E., Schimel, J. P. & Firestone, M. K. (1989). Short-term partitioning of ammonium and nitrate between plants and microbes in an annual grassland. Soil Biology and Biochemistry 21, 409415.CrossRefGoogle Scholar
Jackson, L. E., Wyland, L. J. & Stivers, L. J. (1993). Winter cover crops to minimize nitrate losses in intensive lettuce production. Journal of Agricultural Science, Cambridge 121, 5562.CrossRefGoogle Scholar
Jackson, L. E., Stivers, L. J., Warden, B. T. & Tanji, K. (1994). Crop nitrogen utilization and soil nitrate loss in a lettuce field. Fertilizer Research 37, 93105.CrossRefGoogle Scholar
Jager, G. & Bruins, E. H. (1975). Effect of repeated drying at different temperatures on soil organic matter decomposition and characteristics, and on the soil microflora. Soil Biology and Biochemistry 7, 153159.CrossRefGoogle Scholar
Jones, J. M. & Richards, B. N. (1977). Effect of reforestation on turnover of 15N-labelled nitrate and ammonium in relation to changes in soil microflora. Soil Biology and Biochemistry 9, 383392.CrossRefGoogle Scholar
Linn, D. M. & Doran, J. W. (1984). Effect of water-filled pore space on carbon dioxide and nitrous oxide production in tilled and nontilled soils. Soil Science Society of America Journal 48, 12671272.CrossRefGoogle Scholar
Monterey County (1992). Crop Notes: CIMIS Weather Station Data. University of California Agricultural Experiment Station, June 1992.Google Scholar
Myrold, D. D. (1987). Relationship between microbial biomass nitrogen and a nitrogen availability index. Soil Science Society of America Journal 51, 10471049.CrossRefGoogle Scholar
Ocio, J. A., Brookes, P. C. & Jenkinson, D. S. (1991) Field incorporation of straw and its effects on soil microbial biomass and soil inorganic N. Soil Biology and Biochemistry 23, 171176.CrossRefGoogle Scholar
Orchard, V. A. & Cook, F. J. (1983). Relationship between soil respiration and soil moisture. Soil Biology and Biochemistry 15, 447453.CrossRefGoogle Scholar
Paul, E. A. & Juma, N. G. (1981). Mineralization and immobilization of soil nitrogen by microorganisms. In Terrestrial Nitrogen Cycles: Processes, Ecosystem Strategies and Management Impacts (Eds Clark, F. E. & Rosswall, T.), pp. 179195. Stockholm: Swedish Natural Science Research Council.Google Scholar
Powlson, D. S., Jenkinson, D. S., Pruden, G. & Johnston, A. E. (1985). The effect of straw incorporation on the uptake of nitrogen by winter wheat. Journal of the Science of Food and Agriculture 36, 2630.CrossRefGoogle Scholar
Sas Institute (1985). SAS User's Guide: Statistics, 5th edn. Cary, NC: SAS Institute.Google Scholar
Schimel, J. P., Jackson, L. E. & Firestone, M. K. (1989). Spatial and temporal effects on plant-microbial competition for inorganic nitrogen in a California annual grassland. Soil Biology and Biochemistry 21, 10591066.CrossRefGoogle Scholar
Shen, S. M., Pruden, G. & Jenkinson, D. S. (1984). Mineralization and immobilization of nitrogen in fumigated soil and the measurement of microbial biomass nitrogen. Soil Biology and Biochemistry 16, 437444.CrossRefGoogle Scholar
Van Gestel, M., Ladd, J. N. & Amato, M. (1991). Carbon and nitrogen mineralization from two soils of contrasting texture and microaggregate stability: influence of sequential fumigation, drying and storage. Soil Biology and Biochemistry 23, 313322.CrossRefGoogle Scholar
van Veen, J. A., Ladd, J. N. & Amato, M. (1985). Turnover of carbon and nitrogen through the microbial biomass in a sandy loam and a clay soil incubated with [14C(U)]glucose and [15N](NH4)2SO4 under different moisture regimes. Soil Biology and Biochemistry 17, 747756.CrossRefGoogle Scholar
Vogtmann, H., Temperli, A. T., Künsch, U., Eichenberger, M. & Ott, P. (1984). Accumulation of nitrates in leafy vegetables grown under contrasting agricultural systems. Biological Agriculture and Horticulture 2, 5168.CrossRefGoogle Scholar
Vos, G. J. M., Duquet, B., Vedy, J. C. & Neyroud, J. A. (1993). The course of 15N-ammonium nitrate in a spring barley cropping system. Plant and Soil 150, 167175.CrossRefGoogle Scholar
Wagenet, R. J. (1986). Water and solute flux. In Methods of Soil Analysis, Part I. Physical and Mineralogical Methods (Ed. Klute, A.), pp. 10551088. Madison, WI: American Society of Agronomy.Google Scholar
Wagger, M. G., Kissel, D. E. & Smith, S. J. (1985). Mineralization of nitrogen from nitrogen-15 labeled crop residues under field conditions. Soil Science Society of America Journal 49, 12201226.CrossRefGoogle Scholar
Waring, S. A. & Bremner, J. M. (1964). Ammonium production in soil under waterlogged conditions as an index of nitrogen availability. Nature (London) 201, 951952.CrossRefGoogle Scholar
Wyland, L. J., Jackson, L. E. & Brooks, P. D. (1994). Eliminating nitrate interference during Kjeldahl digestion of soil extracts for microbial biomass determination. Soil Science Society of America Journal 58, 357360.CrossRefGoogle Scholar