Abstract
For nearly a decade, there has been an increased awareness toward food quality, health standards, and global environmental issues in our communities. In that context, adoption of organic production practices has been increasing rapidly in vegetable production. Organic farming is grounded in a holistic view of agriculture that aims to reflect a profound interrelationship between on-farm living biota, farm production, and the overall environment. Organic agriculture has emerged as a powerful tool in re-establishing production practices that are self-sufficient, promote biodiversity, and support practices that conserve soil, water, and the environment. Organic production systems utilize practices such as composting, crop rotation, and use of cover crops , all of which have a positive impact on soil physical, chemical, and biological properties. Although these practices are widely used, there is still uncertainty among growers when it comes to the actual process of composting , compost nutrient concentration and availability, use of compost in transplant mixes, and application rates. Similarly, other areas that need attention are crop rotation , sequence of crops within a rotation, and integration of cover crops in these rotations. Cover crops have an important role in reducing soil erosion, suppressing weeds, improving soil structure and water holding capacity, and increasing soil organic matter. This chapter will highlight the role of composting, use of compost, crop rotation, and cover crops in organic vegetable production systems. This chapter will discuss in detail the composting process, raw materials used, composting methods, quality assessment of compost, and potential avenues where compost can be used in organic vegetable production . The crop rotation portion of this chapter will highlight various crop rotation plans and strategies that growers could utilize to improve soil quality, break pest and disease cycles, and increase yields. The chapter will also provide information on cover crop types, their planting, management, benefits, and challenges in organic vegetable cropping systems. Organic production systems are complex and dynamic. Understanding techniques and practices that directly influence soil is critical in building a production system that is self-sustaining, strong, and resilient. A better understanding of such practices is of paramount importance to build, strengthen, and support organic vegetable production.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Allison E (1965) Organic carbon. In: Black CA et al (eds) Methods of soil analysis, Part 2. American Society Agronomy, Madison, pp 1367–1378
Altieri MA (1995) Agroecology. Westview Press, Boulder, CO
Andow DA (1991) Vegetational diversity and arthropod response. Annu Rev Entomol 36:561–586
Bhardwaj KKR (1995) Improvements in microbial compost technology: a special reference to microbiology of composting. In: Khawna S, Mohan K (eds) Wealth from waste. Tata Energy Research Institute, New Delhi, pp 115–135
Birkhofer K, Fließbach A, Wise DH, Scheu S et al (2008) Generalist predators in organically and conventionally managed grassclover fields: implications for conservation biological control. Ann Appl Biol 153:271–280
Bischoff J, Werner H (1999) Salt/salinity tolerance of common horticultural crops in South Dakota. South Dakota Extension, Fact Sheet 904
Bullock DG (1992) Crop rotation. Crit Rev Plant Sci 11:309–326
Bulluck LR III, Brosius M, Evanylo GK, Ristaino JB et al (2002) Organic and synthetic fertility amendments influence soil microbial, physical and chemical properties on organic and conventional farms. Appl Soil Ecol 19:147–160
Carpenter-Boggs L, Kennedy AC, Reganold JP et al (2000) Organic and biodynamic management effects on soil biology. Soil Sci Soc Am J 64:1651–1659
Carrera LM, Buyer JS, Vinyard B et al (2007) Effects of cover crops, compost, and manure amendments on soil microbial community structure in tomato production systems. Appl Soil Ecol 37:247–255
Chaplin-Kramer R, O’Rourke ME, Blitzer EJ, Kremen C et al (2011) A meta-analysis of crop pest and natural enemy response to landscape complexity. Ecol Lett 14:922–932
Chase, C. 2006. Iowa Vegetable Production Budgets. PM 2017. Extension Communications, Iowa State University, Ames, IA
Chase C, Delate K, Liebman M, Leibold K et al (2008) Economic analysis of three Iowa rotations. PMR 1001. Iowa State University, Ames
Cherr CM, Scholberg JMS, McSorley R et al (2006) Green manure approaches to crop production: A synthesis. Agron J 98:302–319
Clark A (2007) Managing cover crops profitably, 3rd edn. Sustainable Agriculture Network, Beltsville
Clark MS, Horwath WR, Shennan C, Scow K et al (1998) Changes in soil chemical properties resulting from organic and low-input farming practices. Agron J 90:662–671
Cooperband L (2002) The art and science of composting. Center for Integrated Agricultural Systems, University of Wisconsin, Madison, Wisconsin. http://www.cias.wisc.edu/wp-content/uploads/2008/07/artofcompost.pdf. Accessed on 21 July 2015
Coyne MS, Thompson JA (2006) Math for soil scientists. Thomson Delmar Learning, Clifton Park, New York, pp 176–190 and 199–208
Creamer NG, Bennett MA (1997) Evaluation of cover crop mixtures for use in vegetable production systems. HortScience 32:866–870
Delate K, Cambardella C (2004) Agroecosystem performance during transition to certified organic grain production. Agron J 96:1288–1298
Delate K, Cambardella C, McKern A et al (2008) Effects of organic fertilization and cover crops on an organic pepper system. HortTechnology 18:215–226
Delate K, Cambardella C, Chase C, Johanns A, Turnbull R et al (2013) The long-term agroecological research (LTAR) experiment supports organic yields, soil quality, and economic performance in Iowa. Crop Manag. doi:10.1094/CM-2013-0429-02-RS
Delate K, Cambardella C, Chase C, Turnbull R et al (2008) Beneficial system outcomes in organic fields at the long-term agroecological research (LTAR) site, Greenfield, Iowa, USA. Organic E-prints: http://www.orgprints.org/12441/. Accessed 17 June 2015
Delate K, Cwach D, Chase C et al (2012) Organic no–till system effects on soybean, corn and irrigated tomato production and economic performance in Iowa, USA. Renew Agric Food Syst 27(1):49–59. doi:10.1017/S1742170511000524
Delate K, Duffy M, Chase C et al (2003a) An economic comparison of organic and conventional grain crops in a long-term agroecological research (LTAR) site in Iowa. Am J Altern Agric 18:1–11
Delate K, Friedrich H, Lawson V et al (2003b) Organic pepper production systems using compost and cover crops. Biol Agric Hortic 21:131–150
Delate K, Hartzler R (2003) Weed Management for Organic Farmers. PM 1883. Extension Communications, Iowa State University, Ames, IA
Des Moines Register. 2015. Des Moines Water Quality Suit Slated for Trial in 2016. http://www.desmoinesregister.com/story/money/agriculture/2015/07/15/des-moines-water-works-lawsuit-buena-vista-calhoun-sac-counties-water-quality/30191169. Accessed 11 August 2015
Drinkwater LE, Letourneau DK, Workneh F, VanBruggen AHC, Shennan C et al (1995) Fundamental differences between conventional and organic tomato agroecosystems in California. Ecol Appl 5:1098–1112
Drinkwater LE, Wagoner P, Sarrantonio M et al (1998) Legume-based cropping systems have reduced carbon and nitrogen losses. Nature 396: 262–265
Evanylo G, Sherony C, Spargo J, Starner D, Brosius M, Haering K (2008) Soil and water environmental effects of fertilizer, manure, and compost-based fertility practices in an organic vegetable cropping system. Agric Ecosyst Environ 127:50–58
Gantzer CJ, Anderson SH, Thompson AL, Brown JR et al (1991) Evaluation of soil loss after 100 years of soil and crop management. Agron J 83:74–77
Garcia C, Hernandez T, Costa F, Pascual J et al (1992) Phytotoxicity due to the agricultural use of urban wastes: germination experiments. J Sci Food Agric 59:313–319
Gerhardt RA (1997) A comparative analysis of the effects of organic and conventional farming systems on soil structure. Biol Agric Hort 14:139–157
Goolsby EA, Battaglin WA, Lawrence GB, Artz RS, Aulenbach BT, Hooper RP, Keeney DR, Stensland FJ et al (1999) Flux and sources of nutrients in the Mississippi-Atchafalaya river basin: Topic 3 Report for the Integrated Assessment of Hypoxia in the Gulf of Mexico
Hamoda MF, Abu Qdais HA, Newham J et al (1998) Evaluation of municipal solid waste composting kinetics. Resour Conserv Recycl 23:209–223
Haug RT (1993) The practical handbook of compost engineering. Lewis Publishers, Boca Raton, p 717
He XT, Logan TJ, Traina SJ et al (1995) Physical and chemical characteristics of selected U.S. municipal solid waste compost. J Environ Qual 24:543–552
He Z, Yang Z, Kahn BA, Stoffella PJ, Calvert DV et al (2001) Plant nutrition benefits of phosphorous, calcium, magnesium, and micronutrients from compost utilization. In: Stoffella PJ, Kahn BA (eds) Compost utilization in horticultural cropping systems. CRC Press LLC, Florida, pp 307–320
Hepperly P, Lotter D, Ziegler UC, Seidel R, Reider C et al (2009) Compost, manure and synthetic fertilizer influences crop yields, soil properties, nitrate leaching and crop nutrient content. Compost Sci Utilization 17:117–126
Jaynes DB, Hatfield JL, Meek DW et al (1999) Water quality in Walnut Creek watershed: Herbicides and nitrate in surface waters. J Environ Qual 28:45–59
Jokela D, Nair A (2014) Effects of reduced tillage and split fertilizer application in organic broccoli and pepper production systems. ISRF 14–36. http://farms.ag.iastate.edu/sites/default/files/EffectsReducedTillage.pdf
Karlen DL, Mausbach MJ, Doran JW, Kline RG, Harris RF, Schuman GE et al (1997) Soil quality, a concept, definition, and framework for evaluation. Soil Sci Soc Am J 61:4–10
Kramer SB, Reganold JP, Glover JD, Bohannan BJM, Mooney, HA et al (2006) Reduced nitrate leaching and enhanced denitrifier activity and efficiency in organically fertilized soils. PNAS 103:4522–4527
Kuepper G (2015) Market Farming with Rotations and Cover Crops: An Organic Bio-Extensive System. Kerr Center for Sustainable Agriculture, Poteau, OK. http://kerrcenter.com/wp-content/uploads/2015/02/Bioextensive-Model-report-2015-small.pdf. Accessed on 11 August 2015
Lal R, Mahboubi AA, Fausey NR et al (1994) Long-term tillage and rotation effects on properties of a central Ohio soil. Soil Sci Soc Am J 58:517–552
Lammerts van Bueren ET, Jones SS, Tamm L, Murphy KM, Myers JR, Leifert C, Messmer MM (2010) The need to breed crop varieties suitable for organic farming, using wheat, tomato and broccoli as examples: a review. J. Life Sci. NJAS-Wageningen. doi:10.1016/j.njas.2010.04.001
Leege PB, Thompson WH (1997) Test methods for the examinations of composting and compost. www.edaphos.com. Accessed on 24 July 2015
Liebig M, Doran JW (1999) Impact of organic production practices on soil quality indicators. J Environ Qual 28:1601–1609
Liebman M, Dyck E (1993) Crop rotation and intercropping strategies for weed management. Ecol Appl 3:92–122
Liebman M, Drummond FA, Corson S, Zhang J et al (1996) Tillage and rotation crop effects on weed dynamics in potato production systems. Agron J 88:18–26
Liebman M, Mohler CL, Staver CP et al (2001) Ecological management of agricultural weeds, Cambridge University Press, Cambridge
Lockeretz W, Shearer G, Klepper R, Sweeney S et al (1978) Field crop production on organic farms in the Midwest. J Soil Water Conserv 33:130–134
Lockeretz W, Shearer G, Kohl D et al (1981) Organic farming in the Corn Belt. Science 211:540–547
Lynch NJ, Cherry RS (1996) Winter composting using the passively aerated windrow system. Compost Sci Utilization 4:44–52
Marriot EM, Wander MM (2006) Total and labile soil organic matter in organic and conventional farming systems Soil Sci Soc Am J 70:950–959
Martini EA, Buyer JS, Bryant DC, Hartz TK, Denison RF et al (2004) Yield increases during the organic transition: improving soil quality or increasing experience? Field Crops Res 86:255–266
Maynard A, Hill D (2000) Cumulative effect of leaf compost on yield and size distribution in onions. Compost Sci Utilization 8:12–18
Mohler CL, Johnson SE (2009) Crop rotation on organic farms: a planning manual. NRAES 177, Ithaca
Nelson WA, Kahn BA, Roberts BW et al (1991) Screening cover crops for conservation tillage systems for vegetables following spring plowing. HortScience 6:860–862
Nair A, Carpenter B, Tillman J, Jokela D, Tester K (2013). ISRF 13–36. http://farms.ag.iastate.edu/sites/default/files/IntegratingCoverCrops.pdf. Accessed 26 July 2015
Nair A, Delate K, Artz G, Bregendahl C (2015a) Assessing nitrogen credits from clover cover crops and effects of seed inoculation. http://farms.ag.iastate.edu/sites/default/files/AssessingNitrogenCredits_0.pdf. Assessed 26 July 2015
Nair A, Jokela D, Tillman J (2014) Principles and practices of sustainable vegetable production systems. In: Nandwani D (ed) Sustainable horticultural systems. Springer, International Publishing, Switzerland, pp 51–78
Nair A, Kaspar T, Nonnecke G (2015b) Cover crops in vegetable production systems. HORT3026, Iowa State University. www.https://store.extension.iastate.edu/Product/Cover-Crops-in-Vegetable-Production-Systems. Accessed 26 July 2015
Nair A, Ngouajio M (2010) Integrating rowcovers and soil amendments for organic cucumber production: implications on crop growth, yield, and microclimate. HortScience 45:1–9
Nair A, Ngouajio M (2012) Soil microbial biomass, functional microbial diversity, and nematode community structure as affected by cover crops and compost in an organic vegetable production system. Appl Soil Ecol 58:45–55
Nair A, Ngouajio M, Biernbaum J et al (2011) Alfalfa-based organic amendment in peat-compost growing medium for organic tomato transplant production. HortScience 46:253–259
National Organic Program 5021 (2010) Draft Guidance: Compost and vermicompost in organic crop production. United States Department of Agriculture–Agricultural Marketing Service. http://www.ams.usda.gov/AMSv1.0/getfile?dDocName=STELPRDC5087122. Accessed 24 July 2015
Organic Trade Association (2015) Organic industry growth–2014. Organic Trade Association, Washington, D.C. http://ota.com/news/pressreleases/18061
Ozores-Hampton M, Obreza TA, Hochmuth G et al (1998) Using composted wastes on Florida vegetable crops. HortTechnology 8:130–137
Peigné J, Girardin P (2004) Environmental impacts of farm-scale composting practices. Water Air Soil Pollut 153:45–68
Pimentel D, Hepperly P, Hanson J, Douds D, Seidel R et al (2005) Environmental, energetic, and economic comparisons of organic and conventional farming systems. BioScience 55:573–582
Poincelet RP (1977) The biochemistry of composting. In: Composting of municipal sludges and wastes. Proceedings of the national conference. Rockville, Maryland, pp 33–39
Poudel DD, Horwath, WR, Lamini WT, Temple SR, van Bruggen AHC et al (2002) Comparison of soil N availability and leaching potential, crop yields and weeds in organic, low-input and conventional farming systems in northern California. Agric Ecosyst Environ 90:125–137
Pulleman MM, Bourma J, van Esssen EA, Meijles EW et al (2000) Soil organic matter content as a function of different land use history. Soil Sci Soc Am J 64:689–693
Rabalais NN, Wiseman WJ, Turner RE, SenGupta BK, Dortch Q et al (1996) Nutrient changes in the Mississippi River and system responses on the adjacent continental shelf. Estuaries 19:386–407
Reganold JP (1988) Comparison of soil properties as influenced by organic and conventional farming systems. Am J Alt Agric 3:144–155
Reganold JP, Elliott LF, Unger YL et al (1987) Long-term effects of organic and conventional farming on soil erosion. Nature 330:370–372
Reganold JP, Palmer AS, Lockhart JC, Macgregor AN et al (1993) Soil quality and financial performance of biodynamic and conventional farms in New Zealand. Science 260:344–349
Rosen CJ, Bierman PM (2005). Using manure and compost as nutrient sources for fruit and vegetable crops. http://www.extension.umn.edu/garden/fruit-vegetable/using-manure-and-compost/. Accessed 23 July 2015
Roe N, Cornforth G (1997) Yield effects and economic comparison of using fresh or composted dairy manure amendments on double-cropped vegetables. HortScience 32:462
Root RB (1973) Organization of a plant-arthropod association in simple and diverse habitats: the fauna of collards (Brassica oleracea). Ecol Monogr 43:95–124
Russelle MP, Franzluebbers AJ (2007) Introduction to symposium: Integrated crop-livestock systems for profit and sustainability. Agron J 99:323–324
Russo VM, Webber CL III et al (2007) Organic agricultural production in the United States: an old wheel being reinvented. Am J Plant Sci Biotech 1:29–35
Ryn R, Van de Kamp M, Wilson GB, Singley ME, Richard TL, Kolega JJ, Gouin FR, Laliberty L Jr, Kay D, Murphy DW, Hoitink HAJ, Brinton WF et al (1992) On-Farm composting handbook. In: Rynk R (ed) Northeast regional agricultural engineering service. Ithaca, New York, pp 6–13, 106–113
Schreiber MM (1992) Influence of tillage, crop rotation, and weed management on giant foxtail (Setaria faberi) population dynamics and corn yield. Weed Sci 40:645–653
Singerman A, Delate K, Chase C, Greene C, Livingston M, Lence S, Hart C et al (2011) Profitability of organic and conventional soybean production under ‘green payments’ in carbon offset programs. Renew Agric Food Syst 27:266–277
Schroder J (2005) Revisiting the agronomic benefits of manure: a correct assessment and exploitation of its fertilizer values spares the environment. Bioresour Technol 96:253–261
Snapp S, Swinton S, Labarta R et al (2005) Evaluating cover crops for benefits, costs and performance within cropping system niches. Agron J 97:322–332
Stoffella PJ, Kahn BA (2001) Compost utilization in horticultural cropping systems. Boca Raton, Florida, pp 95–120
Sullivan DM, Miller RO (2001) Compost quality attributes, measurements, and variability. In: Stoffella PJ, Kahn BA (eds) Compost utilization in horticultural cropping systems. Florida, Boca Raton, pp 95–120
Teasdale JR, Coffman CB, Mangum RW et al (2007) Potential long-term benefits of no-tillage and organic cropping systems for grain production and soil improvement. Agron J 99:1297–1305
Thompson W, Leege P, Milner P, Watson M et al (2002) Test methods for the examination of composts and composting. The U.S. Composting Council, Hauppauge, New York. http://www.compostingcouncil.org. Accessed 23 July 2015
Tuomela M, Vikman M, Hatakka A, Itävaara M et al (2000) Biodegradation of lignin in a compost environment: a review. Bioresour Technol 72:169–183
U.S. Department of Agriculture, Agricultural Marketing Service, National Organic Program (2010) http://www.ams.usda.gov/AMSv1.0/nop. Accessed 24 June 2015
U.S. Department of Agriculture (USDA)–National Agricultural Statistics Service (NASS). (2011). Crop Production–March 8, 2013
Worsham AD (1984) Crop residues kill weeds. Crops Soils Mag 37:18–20
Warman PR (1999) Evaluation of seed germination and growth tests for assessing compost maturity. Compost Sci Utilization 7:33–37
Woods End Research Laboratory (1999) Guide to Solvita® testing for compost maturity index. Woods End Research Laboratory Inc. Mt. Vernon, Maine. https://solvita.com/compost. Accessed 25 July 2015
Zucconi F, Forte M, Monaco A, deBertoldi M (1981) Biological evaluation of compost maturity. Biocycle 22:27–29
Acknowledgements
This work was supported by Iowa State University College of Agriculture and Life Sciences and the Leopold Center for Sustainable Agriculture.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2016 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Nair, A., Delate, K. (2016). Composting, Crop Rotation, and Cover Crop Practices in Organic Vegetable Production. In: Nandwani, D. (eds) Organic Farming for Sustainable Agriculture. Sustainable Development and Biodiversity, vol 9. Springer, Cham. https://doi.org/10.1007/978-3-319-26803-3_11
Download citation
DOI: https://doi.org/10.1007/978-3-319-26803-3_11
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-26801-9
Online ISBN: 978-3-319-26803-3
eBook Packages: Biomedical and Life SciencesBiomedical and Life Sciences (R0)