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Increasing corn yield with no-till cropping systems: a case study in South Dakota

Published online by Cambridge University Press:  25 November 2015

Randy L. Anderson*
Affiliation:
USDA-ARS, Brookings South Dakota, 57006, USA.
*
*Corresponding author: [email protected]

Abstract

No-till practices have improved crop yields in the semiarid Great Plains. However, a recent assessment of research studies across the globe indicated that crop yields are often reduced by no-till. To understand this contrast, we examined corn yields across time in a no-till cropping system of one producer in central South Dakota to identify factors associated with increased yield. The producer started no-till in 1990; by 2013, corn yield increased 116%. In comparison, corn increased only 32% during this interval with a conventional, tillage-based system in a neighboring county. With no-till, corn yields increased in increments due to changes in management. For example, corn yield increased 52% when crop diversity in the rotation was expanded from 2 to 5 crops. A further 18% gain in yield occurred when dry pea was grown before corn in sequence. Nitrogen (N) requirement for corn is 25% lower in no-till compared with a tillage-based rotation. Furthermore, phosphorus (P) fertilizer input also has been reduced 30% after 20 yr of no-till, even with higher yields. Our case study shows that integrating no-till with crop diversity and soil microbial changes improves corn yield considerably. This integration also reduces need for inputs such as water, N and P.

Type
New Concepts and Case Studies
Creative Commons
This is a work of the U.S. Government and is not subject to copyright protection in the United States.
Copyright
Copyright © Cambridge University Press 2015

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References

Anderson, R.L. 2009. Rotation design: a critical factor for sustainable crop production in a semiarid climate. In Lichtfouse, E. (ed.). Organic Farming, Pest Control, and Remediation of Soil Pollutants. Sustainable Agriculture Reviews 5. Springer Publishing Company, New York, NY. pp. 107121.CrossRefGoogle Scholar
Anderson, R.L. 2011. Synergism: A rotational effect of improved growth efficiency. Advances in Agronomy 112:205226.CrossRefGoogle Scholar
Anderson, R.L. 2012. Possible causes of dry pea synergy to corn. Weed Technology 26:438442.Google Scholar
Artursson, V., Finlay, R.D., and Jansson, J.K. 2006. Interactions between arbuscular mycorrhizal fungi and bacteria and their potential for stimulating plant growth. Environmental Microbiology 8:110.Google Scholar
Auge, R.M. 2004. Arbuscular mycorrhizae and soil/plant water relations. Canadian Journal of Soil Science 84:373381.Google Scholar
Beck, D. 2015. Dryland Rotations through 2012. Dakota Lakes Research Farm. Available at Web site http://www.dakotalakes.com/publications (verified 8 September 2015).Google Scholar
Brussaard, L., de Ruiter, P.C., and Brown, G.C. 2007. Soil biodiversity for agricultural sustainability. Agriculture, Ecosystems and Environment 121:218230.CrossRefGoogle Scholar
Caeser-TonThat, T.C., Sainju, U.P., Wright, S.F., Shelver, W.L., Kolberg, R.L., and West, M. 2011. Long-term tillage and cropping effects on microbiological properties associated with aggregation in a semi-arid soil. Biology and Fertility of Soils 47:157165.CrossRefGoogle Scholar
Dobbelaere, S., Vanderleyden, J., and Okon, Y. 2003. Plant growth-promoting effects of diazotrophs in the rhizosphere. Critical Reviews in Plant Science 22:107149.CrossRefGoogle Scholar
Douds, D.D. Jr. and Millner, P.D. 1999. Biodiversity of arbuscular mycorrhizal fungi in agroecosystems. Agriculture, Ecosystems and Environment 74:7793.Google Scholar
Food and Agriculture Organization (FAO). 2015. What is Conservation Agriculture? FAO Conservation Agriculture. Available at Web site http://www.fao.org/ag/ca/1a.thml (verified 15 January 2015).Google Scholar
Gerwing, J. and Gelderman, R. 2005. Fertilizer Recommendation Guide. South Dakota State University Extension Bulletin EC750, Brookings, SD. 27 pages.Google Scholar
Halpern, M.T., Whalen, J.K., and Madramootoo, C.A. 2010. Long-term tillage and residue management influences soil carbon and nitrogen dynamics. Soil Science Society of America Journal 74:12111217.Google Scholar
Hamel, C. 2004. Impact of arbuscular mycorrhizal fungi on N and P cycling in the root zone. Canadian Journal of Soil Science 84:383395.Google Scholar
Helgason, B.L., Walley, F.L., and Germida, J.J. 2010. No-till soil management increases soil microbial biomass and alters community profiles in soil aggregates. Applied Soil Ecology 46:390397.Google Scholar
Holzwarth, R. 2015. Yield Proof Data, 1990–2013. On file, USDA-NRCS field office, Potter County, SD.Google Scholar
Hudson, B.D. 1994. Soil organic matter and available water capacity. Journal of Soil and Water Conservation 49:189194.Google Scholar
Kabir, Z. 2005. Tillage or no-tillage: Impact on mycorrhizae. Canadian Journal of Plant Science 85:2329.Google Scholar
Kirkegaard, J.A. and Ryan, M.R. 2014. Magnitude and mechanisms of persistent crop sequence effects on wheat. Field Crops Research 164:154165.Google Scholar
Krupinsky, J.M., Bailey, K.L., McMullen, M.P., Gossen, B.D., and Turkington, T.K. 2002. Managing plant diseases with diversified cropping systems. Agronomy Journal 94:1982009.Google Scholar
Lafond, G.P., Walley, F., May, W.E., and Holzapfel, C.B. 2011. Long term impact of no-till on soil properties and crop productivity on the Canadian prairies. Soil and Tillage Research 117:110123.CrossRefGoogle Scholar
Liebig, M.A., Tanaka, D.L., and Wienhold, B.J. 2004. Tillage and cropping effects on soil quality indicators in the northern Great Plains. Soil and Tillage Research 78:131141.Google Scholar
Lupwayi, N.Z., Clayton, G.W., Hanson, K.G., Rice, W.A., and Biederbeck, V.O. 2004. Endophytic rhizobia in barley, wheat and canola roots. Canadian Journal of Plant Science 84:3745.Google Scholar
Maader, P., Kaiser, F., Adholeya, A., Singh, R., Uppal, H.S., Sharma, A.K., Srivastava, R., Sahai, V., Aragno, M., Wiemken, A., Johri, B.N., and Fried, P.M. 2011. Inoculation of root microorganisms for sustainable wheat-rice and wheat-black gram rotations in India. Soil Biology and Biochemistry 43:609619.Google Scholar
Miller, M.H. 2000. Arbuscular mycorrhizae and the phosphorus nutrition of maize: A review of Guelph studies. Canadian Journal of Plant Science 80:4752.Google Scholar
National Agricultural Statistics Service (NASS). 2015. South Dakota web page. http://www.nass.usda.gov/statistics_by_state/South_Dakota/Publications/County_Estimates. Yield data, 1990–1993 and 2008–2013 (verified 15 January 2015).Google Scholar
Palm, C., Blanco-Canqui, H., DeClerk, F., and Gatere, L. 2014. Conservation agriculture and ecosystem services: An overview. Agriculture, Ecosystems and Environment 187:87105.Google Scholar
Peng, S., Biswas, J.C., Ladha, J.K., Cyaneshwar, P., and Chen, Y. 2002. Influence of rhizobial inoculation on photosynthesis and grain yield of rice. Agronomy Journal 94:925929.Google Scholar
Peterson, G.A., Westfall, D.G., and Cole, C.V. 1993. Agroecosystem approach to soil and crop management research. Soil Science Society of America Journal 57:13541360.Google Scholar
Peterson, G.A., Schlegel, A.L., Tanaka, D.L., and Jones, O.R. 1996. Precipitation use efficiency as affected by cropping and tillage system. Journal of Production Agriculture 9:180186.Google Scholar
Pittelkow, C.M., Lilan, X., Linquist, B.A., van Groenigen, K.J., Lee, J., Lundy, M.E., van Gestel, N., Six, J., Venterea, R.T., and van Kessel, C. 2015. Productivity limits and potentials of the principles of conservation agriculture. Nature 517:365368.Google Scholar
Richardson, A.E. and Simpson, R.J. 2011. Soil microorganisms mediating phosphorus availability. Plant Physiology 156:989996.CrossRefGoogle ScholarPubMed
Riggs, P.J., Chelius, M.K., Iniguez, A.L., Kaeppler, S.M., and Triplett, E.W. 2001. Enhanced maize productivity by inoculation with diazotrophic bacteria. Australian Journal of Plant Physiology 28:829836.Google Scholar
Rillig, M.C. 2004. Arbuscular mycorrhizae, glomalin, and soil aggregation. Canadian Journal of Soil Science 84:355363.Google Scholar
Seymour, M., Kirkegaard, J.A., Peoples, M.B., White, P.F., and French, R.J. 2012. Break-crop benefits to wheat in Western Australia – insights from over three decades of research. Crop and Pasture Science 63:116.Google Scholar
Shaver, T.M., Peterson, G.A., Ahuja, L.R., Westfall, D.G., Sherrod, L.A., and Dunn, G. 2002. Surface soil physical properties after twelve years of dryland no-till management. Soil Science Society of America Journal 66:12961303.Google Scholar
Shaxson, T.F. 2006. Re-thinking the conservation of carbon, water and soil: A different perspective. Agronomy for Sustainable Development 26:919.Google Scholar
Shennan, C. 2008. Biotic interactions, ecological knowledge, and agriculture. Philosophical Transactions of the Royal Society B – Biological Sciences 363:717739.Google Scholar
Sherrod, L.A., Peterson, G.A., Westfall, D.G., and Ahuja, L.R. 2005. Soil organic pools after 12 years in no-till dryland agroecosystems. Soil Science Society of America Journal 69:16001608.Google Scholar
Silva, A.P., Babujia, L.C., Franchini, J.C., Souza, R.A., and Hungria, M. 2010. Microbial biomass under various soil- and crop-management systems in short- and long-term experiments in Brazil. Field Crops Research 119:2026.Google Scholar
Smith, F.A. and Smith, S.E. 2011. What is the significance of the arbuscular mycorrhizal colonization of many economically important crop plants? Plant and Soil 348:6379.Google Scholar
Soon, Y.K. and Clayton, G.W. 2002. Eight years of crop rotation and tillage effects on crop production and N fertilizer use. Canadian Journal of Soil Science 82:165172.Google Scholar
Sweeney, D.W. and Moyer, J.L. 2004. In-season nitrogen uptake by grain sorghum following legume green manures in conservation tillage systems. Agronomy Journal 96:510515.Google Scholar
Triplett, G.B. Jr. and Dick, W.A. 2008. No-tillage crop production: A revolution in agriculture! Agronomy Journal (Supplement): S-153S-165.Google Scholar
van Noordwijk, M. and Brussaard, L. 2014. Minimizing the ecological footprint of food: Closing yield and efficiency gaps simultaneously? Current Opinion in Environmental Sustainability 8:6270.CrossRefGoogle Scholar
Welbaum, G.E., Sturz, A.V., Dong, Z., and Nowak, J. 2004. Managing soil microorganisms to improve productivity of agro-ecosystems. Critical Reviews in Plant Sciences 23:175193.Google Scholar