Hostname: page-component-848d4c4894-cjp7w Total loading time: 0 Render date: 2024-06-21T09:04:13.388Z Has data issue: false hasContentIssue false
  • English
  • Français

Winter legume cover-crop root decomposition and N release dynamics under disking and roller-crimping termination approaches

Published online by Cambridge University Press:  20 May 2015

Arun D. Jani ,
Julie Grossman ,
Thomas J. Smyth  and
Shuijin Hu
Arun D. Jani*
Affiliation:
Department of Soil Science, North Carolina State University, PO Box 7619, Raleigh, NC 27695, USA.
Julie Grossman
Affiliation:
Department of Horticultural Science, University of Minnesota, 1970 Folwell Avenue, St. Paul, MN 55108, USA.
Thomas J. Smyth
Affiliation:
Department of Soil Science, North Carolina State University, PO Box 7619, Raleigh, NC 27695, USA.
Shuijin Hu
Affiliation:
Department of Plant Pathology, North Carolina State University, PO Box 7616, Raleigh, NC 27695, USA.
*
*Corresponding author:ajani@ncsu.edu
Get access Rights & Permissions [Opens in a new window]

Abstract

Several approaches can be used to terminate legume cover crops in the spring prior to planting summer crops, but the effect that these methods have on decomposition and nitrogen (N) release dynamics of legume cover-crop roots is poorly understood. The main objectives of this study were to: (i) quantify decomposition and N release of roots from pea (Pisum sativum), clover (Trifolium incarnatum) and vetch (Vicia villosa Roth); (ii) determine if roots decompose and release N faster when cover crops are terminated by disking compared with roller-crimping; and (iii) determine if roots decompose and release N faster under higher soil inorganic N levels. Two field experiments were conducted in Goldsboro and Kinston, North Carolina in the summer of 2012. Cover crops at these sites were terminated in spring by disking or roller-crimping and planted to unirrigated corn. Air-dried roots placed in litterbags were buried in their corresponding cover-crop plots and in plots where cover crops had not been grown that had either synthetic N fertilizer added at burial or had no fertilizer addition. Root litterbags were collected over 16 weeks at both sites. Cover-crop plots terminated by disking had up to 117 and 49% higher soil inorganic N than roller-crimped plots in Goldsboro and Kinston, respectively. However, roots did not appear to contribute significantly to these increases, as measured root decomposition and N release was not affected by termination approach at either site. Roots decomposed rapidly at both sites, losing up to 65% of their original biomass within 4 weeks after burial. Root N release was also rapid at both sites, with vetch generally releasing N fastest and clover slowest. It was estimated that cover-crop roots supplied 47–62 and 19–33 kg N ha−1 during the corn cycle in Goldsboro and Kinston, respectively. Our results indicate that under the warm, humid summer conditions of the Southeastern USA, legume cover-crop roots decompose and release N rapidly.

Keywords

legume cover cropsrootsroller-crimpingdiskingdecompositionsoil nitrogen
Type
Research Papers
Information
Renewable Agriculture and Food Systems , Volume 31 , Issue 3 , June 2016 , pp. 214 - 229
Check for updates
Copyright
Copyright © Cambridge University Press 2015 

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

Ashford, D.L. and Reeves, D. 2003. Use of a mechanical roller-crimper as an alternative kill method for cover crops. American Journal of Alternative Agriculture 18(1):3745.CrossRefGoogle Scholar
Berg, B. and McClaugherty, C. 2008. Plant Litter: Decomposition, Humus Formation, Carbon Sequestration. 2nd ed. Springer, Berlin, Germany.Google Scholar
Berg, B., Muller, M., and Wessen, B. 1987. Decomposition of red-clover (Trifolium pratense) roots. Soil Biology and Biochemistry 19:589593.Google Scholar
Bocock, K.L. and Gilbert, O.J.W. 1957. The disappearance of leaf litter under different woodland conditions. Plant and Soil 9:179185.Google Scholar
Bolger, T.P., Angus, J.F., and Peoples, M.B. 2003. Comparison of nitrogen mineralization patterns from root residues of Trifolium subterraneum and Medicago sativa . Biology and Fertility of Soils 38:296300.Google Scholar
Buchanan, M. and King, L. 1993. Carbon and phosphorus losses from decomposing crop residues in no-till and conventional till agroecosystems. Agronomy Journal 85(3):631638.Google Scholar
Campiglia, E., Mancinelli, R., Radicetti, E., and Marinari, S. 2011. Legume cover crops and mulches: Effects on nitrate leaching and nitrogen input in a pepper crop (Capsicum annuum L.). Nutrient Cycling in Agroecosystems 89(3):399412.CrossRefGoogle Scholar
Coppens, F., Garnier, P., Findeling, A., Merckx, R., and Recous, S. 2007. Decomposition of mulched versus incorporated crop residues: Modelling with PASTIS clarifies interactions between residue quality and location. Soil Biology and Biochemistry 39:23392350.CrossRefGoogle Scholar
Davis, A.S. 2010. Cover-crop roller-crimper contributes to weed management in no-till soybean. Weed Science 58(3):300309.Google Scholar
Dungait, J.A.J., Hopkins, D.W., Gregory, A.S., and Whitmore, A.P. 2012. Soil organic matter turnover is governed by accessibility not recalcitrance. Global Change Biology 18(6):17811796.Google Scholar
Fog, K. 1988. The effect of added nitrogen on the rate of decomposition of organic matter. Biological Reviews 63:433462.Google Scholar
Gijsman, A., Alarcon, H., and Thomas, R. 1997. Root decomposition in tropical grasses and legumes, as affected by soil texture and season. Soil Biology and Biochemistry 29:14431450.Google Scholar
Gunnarsson, S. and Marstorp, H. 2002. Carbohydrate composition of plant materials determines N mineralisation. Nutrient Cycling in Agroecosystems 62(2):175183.Google Scholar
Hoagland, D.R. and Arnon, D.I. 1950. The water-culture method for growing plants without soil. California Agricultural Experiment Station Circular 347:132.Google Scholar
Jones, C.A. 1985. C4 Grasses and Cereals: Growth, Development, and Stress Response. John Wiley & Sons, Inc., New York.Google Scholar
Kong, A.Y.Y. and Six, J. 2010. Tracing root vs. residue carbon into soils from conventional and alternative cropping systems. Soil Science Society of America Journal 74:12011210.Google Scholar
Kornecki, T., Price, A., Raper, R., and Arriaga, F. 2009. New roller crimper concepts for mechanical termination of cover crops in conservation agriculture. Renewable Agriculture and Food Systems 24(3):165173.Google Scholar
Lawson, A., Fortuna, A.M., Cogger, C., Bary, A., and Stubbs, T. 2012. Nitrogen contribution of rye-hairy vetch cover crop mixtures to organically grown sweet corn. Renewable Agriculture and Food Systems 28(1):111.Google Scholar
Liang, S., Grossman, J., and Shi, W. 2014. Microbial response to winter cover cropping management during transition to organic farming. European Journal of Soil Biology 65:1522.Google Scholar
Lopp, K.L. and Guillard, K. 2004. Decomposition rates and nitrogen release of turf grass clippings. Plant Science Presentations and Proceedings #3. University of Connecticut.Google Scholar
Luna-Orea, P., Wagger, M.G., and Gumpertz, M.L. 1996. Decomposition and nutrient release dynamics of two tropical legume cover crops. Agronomy Journal 88:758764.Google Scholar
Magdoff, F. 1991. Understanding the Magdoff pre-sidedress nitrate test for corn. Journal of Production Agriculture 4:297305.Google Scholar
Mary, B., Recous, S., Darwis, D., and Robin, D. 1996. Interactions between decomposition of plant residues and nitrogen cycling in soil. Plant and Soil 181:7182.Google Scholar
Mirsky, S., Curran, W., Mortensen, D., Ryan, M., and Shumway, D. 2009. Control of cereal rye with a Roller/Crimper as influenced by cover crop phenology. Agronomy Journal 101(6):15891596.Google Scholar
Mirsky, S., Curran, W., Mortensen, D., Ryan, M., and Shumway, D. 2011. Timing of cover crop management effects on weed suppression in no-till planted soybean using a roller-crimper. Weed Science 59:380389.Google Scholar
Moller, K. and Reents, H.R. 2009. Effects of various cover crops after peas on nitrate leaching and nitrogen supply to succeeding winter wheat or potato crops. Journal of Plant Nutrition and Soil Science 172(2):277287.Google Scholar
Mosier, A.R., Doran, J.W., and Freney, J.R. 2002. Managing soil denitrification. Journal of Soil and Water Conservation 57(6):505513.Google Scholar
Parr, M., Grossman, J.M., Reberg-Horton, S.C., Brinton, C., and Crozier, C. 2011. Nitrogen delivery from legume cover crops in no-till organic corn production. Agronomy Journal 103(6):15781590.Google Scholar
Parr, M., Grossman, J.M., Reberg-Horton, S.C., Brinton, C., and Crozier, C. 2014. Roller-crimper termination for legume cover crops in North Carolina: Impacts on nutrient availability to a succeeding corn crop. Communications in Soil Science and Plant Analysis 45:11061119.Google Scholar
Paul, E.A. and Clark, F.E. 2007. Soil Microbiology and Biochemistry. 3rd ed. Academic Press, New York.Google Scholar
Puget, P. and Drinkwater, L. 2001. Short-term dynamics of root- and shoot-derived carbon from a leguminous green manure. Soil Science Society of America Journal 65(3):771779.Google Scholar
Ranells, N.N. 1992. Nitrogen release from crimson clover in relation to plant growth stage and composition. Agronomy Journal 84:424430.Google Scholar
Rasse, D.P., Smucker, A.J.M., and Schabenberger, O. 1999. Modifications of soil N pools in response to alfalfa root systems and shoot mulch. Agronomy Journal 91:471477.CrossRefGoogle Scholar
Sainju, U.M., Whitehead, W.F., and Singh, B.P. 2005. Biculture legume–cereal cover crops for enhanced biomass yield and carbon and nitrogen. Agronomy Journal 97:14031412.Google Scholar
Sarrantonio, M. and Scott, T.W. 1988. Tillage effects on availability of nitrogen to corn following a winter green manure crop. Soil Science Society of America Journal 52:16611668.Google Scholar
Schmidt, M.W.I., Torn, M.S., Abiven, S., Dittmar, T., Guggenberger, G., Janssens, I.A., Kleber, M., Kögel-Knabner, I., Lehmann, J., Manning, D.A.C., Nannipieri, P., Rasse, D.P., Weiner, S., and Trumbore, S.E. 2011. Persistence of soil organic matter as an ecosystem property. Nature 478:4956.Google Scholar
Soriano, M.A., Àlvarez, S., Landa, B.B., and Gómez, J.A. 2012. Soil properties in organic olive orchards following different weed management in a rolling landscape of Andalusia, Spain. Renewable Agriculture and Food Systems 29(1):8391.Google Scholar
Soto, G., Luna-Orea, P., Wagger, M., Smyth, T., and Alvarado, A. 2005. Foliage residue decomposition and nutrient release in peach palm (Bactris gasipaes kunth) plantations for heart-of-palm production in Costa Rica. Agronomy Journal 97:13961402.CrossRefGoogle Scholar
State Climate Office of North Carolina, NC State University. 2014. CRONOS [internet database] available at Web site http://www.nc-climate.ncsu.edu/cronos/ (verified January 9, 2014.Google Scholar
Stute, J.K. and Posner, J.L. 1995. Synchrony between legume nitrogen release and corn demand in the Upper Midwest. Agronomy Journal 87:10631069.Google Scholar
Utomo, M., Frye, W.W., and Blevins, R.L. 1990. Sustaining soil nitrogen for corn using hairy vetch cover crop. Agronomy Journal 82:979983.Google Scholar
Varco, J.J., Frye, W.W., Smith, M.S., and MacKown, C.T. 1989. Tillage effects on nitrogen recovery by corn from a nitrogen-15 labeled legume cover crop. Soil Science Society of America Journal 53:822827.Google Scholar
Varco, J.J., Frye, W.W., Smith, M.S., and MacKown, C.T. 1993. Tillage effects on legume decomposition and transformation of legume and fertilizer nitrogen-15. Soil Science Society of America Journal 57:750756.Google Scholar
Vasileva, V. 2015. Aboveground to root biomass ratios in pea and vetch after treatment with organic fertilizer. Global Journal of Environmental Science and Management 1(2):145148.Google Scholar
Wagger, M., Cabrera, M., and Ranells, N.N. 1998. Nitrogen and carbon cycling in relation to cover crop residue quality. Journal of Soil and Water Conservation 53:214218.Google Scholar
Wang, H., Liu, S., and Mo, J. 2010. Correlation between leaf litter and fine root decomposition among subtropical tree species. Plant and Soil 335:289298.Google Scholar
Williams, M.A., Myrold, D.D., and Bottomley, P.J. 2006. Distribution and fate of 13C-labeled root and straw residues from ryegrass and crimson clover in soil under western Oregon field conditions. Biology and Fertility of Soils 42:523531.Google Scholar
Wilson, D.O. and Hargrove, W.L. 1986. Release of nitrogen from crimson clover residue under two tillage systems. Soil Science Society of America Journal 50:12511254.CrossRefGoogle Scholar
Yaduvanshi, N.P.S. and Sharma, D.R. 2008. Tillage and residual manures/chemical amendment effects on soil organic matter and yield of wheat under sodic water irrigation. Soil and Tillage Research 98(1):1116.Google Scholar