Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-27T12:00:42.110Z Has data issue: false hasContentIssue false

Buckwheat Species as Summer Cover Crops for Weed Suppression in No-Tillage Vegetable Cropping Systems

Published online by Cambridge University Press:  20 January 2017

Mary T. Saunders Bulan
Affiliation:
Graduate Student, Professor, and Professor, Department of Agronomy, University of Wisconsin–Madison, Madison, WI 53706
David E. Stoltenberg*
Affiliation:
Graduate Student, Professor, and Professor, Department of Agronomy, University of Wisconsin–Madison, Madison, WI 53706
Joshua L. Posner
Affiliation:
Graduate Student, Professor, and Professor, Department of Agronomy, University of Wisconsin–Madison, Madison, WI 53706
*
Corresponding author's E-mail: destolte@wisc.edu

Abstract

Buckwheat is a broadleaved annual species that is often used as a summer cover crop for its quick growth, weed suppressive ability, and ease of management. Tartary buckwheat is a species related to buckwheat, with many of the same traits valued in buckwheat as a cover crop. However, Tartary buckwheat has been reported to grow more vigorously than buckwheat, especially in cool conditions, which might fill a unique niche for vegetable farmers in Wisconsin and other northcentral states. Our research objectives were to determine the effectiveness of Tartary buckwheat relative to buckwheat for weed suppression, both during the cover-cropping phase and after cover-crop termination during cabbage production, and quantify weed suppression, soil compaction, soil nitrogen availability, and cabbage yield in no-tillage (roller-crimped or sickle-bar mowed) and conventional-tillage (rototilled) systems. Across three site-years, we found that buckwheat emerged earlier and produced 64% more shoot dry biomass than Tartary buckwheat. Pretermination weed shoot biomass (predominantly Amaranthus and Setaria spp.) in Tartary buckwheat treatments was approximately twice that of buckwheat, and did not differ from weed shoot biomass in a control fallow treatment. Cabbage yield did not differ between cover crop species nor did yield differ between conventional-tillage cover cropped and control fallow treatments. However, weed biomass was greater, and cabbage yield was reduced, in no-tillage compared to conventional-tillage treatments. We also found evidence of greater soil compaction and less nitrate–nitrogen (NO3–N) availability in no-tillage than conventional-tillage treatments. These results suggest that Tartary buckwheat is not a suitable summer cover crop alternative to buckwheat for weed suppression prior to cabbage production.

Type
Weed Management
Copyright
Copyright © Weed Science Society of America 

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.)

Footnotes

Current address: Assistant Professor, Sustainable Agriculture Enterprise, Center for Sustainability and Global Change, Unity College, Unity, ME 04988.

References

Literature Cited

Abdul-Baki, AA, Morse, RD, Devine, TE, Teasdale, JR (1997) Broccoli production in forage soybean and foxtail millet cover crop mulches. HortScience. 32:836839 Google Scholar
[ACT] African Conservation Tillage (2008) Linking Production, Livelihoods and Conservation. Proceedings of the Third World Congress on Conservation Agriculture, 37 October, 2005 Nairobi, Kenya African Conservation Tillage Network. 141 pGoogle Scholar
Altieri, MA, Lana, MA, Bittencourt, HV, Kieling, AS, Comin, JJ, Lovato, PE (2011) Enhancing crop productivity via weed suppression in organic no-till cropping systems in Santa Catarina, Brazil. J Sustain Agric. 35:855869 Google Scholar
Anderson, G, Pidgeon, JD, Spencer, HB, Parks, R (1980) A new hand-held recording penetrometer for soil studies. J Soil Sci. 31:279296 Google Scholar
Araj, S-E, Wratten, SD, Lister, A, Buckley, H (2009) Adding floral nectar resources to improve biological control: potential pitfalls of the fourth trophic level. Basic Appl Ecol. 10:554562 Google Scholar
Barberi, P (2002) Weed management in organic agriculture: Are we addressing the right issues? Weed Res. 42:177193 Google Scholar
Baty, F, Delignette-Muller, M-L (2013) nlstools: Tools for Nonlinear Regression Diagnostics. http://cran.r-project.org/web/packages/nlstools/. Accessed October 23, 2013Google Scholar
Bernstein, ER, Posner, JL, Stoltenberg, DE, Hedtcke, JL (2011) Organically managed no-tillage rye–soybean systems: agronomic, economic, and environmental assessment. Agron J. 103:11691179 Google Scholar
Bernstein, ER, Stoltenberg, DE, Posner, JL, Hedtcke, JL (2014) Weed community dynamics and suppression in tilled and no-tillage transitional organic winter rye–soybean systems. Weed Sci. 62:125137 Google Scholar
Bicksler, AJ, Masiunas, JB (2009) Canada thistle (Cirsium arvense) suppression with buckwheat or sudangrass cover crops and mowing. Weed Technol. 23:556563 Google Scholar
Bjorkman, T, Shail, JW (2010) Cornell cover crop guide for buckwheat. Ithaca, NY Cornell University. 2 pGoogle Scholar
Bjorkman, T, Shail, JW (2013) Using a buckwheat cover crop for maximum weed suppression after early vegetables. HortTechnology. 23:575580 Google Scholar
Borowy, A (2004) Effect of no-tillage and rye mulch on occurrence of weeds and aphids and on yields of cabbage, carrot and red beet. Acta Hortic. 638:147150 Google Scholar
Briggs, CJ, Campbell, C, Pierce, G, Jiang, P (2004) Bioflavonoid analysis and antioxidant properties of Tartary buckwheat accessions. Pages 593597 in Advances in Buckwheat Research: Proceedings of the 9th International Symposium on Buckwheat. Prague, Czech Republic Research Institute of Crop Production Google Scholar
Campbell, C (1997) Buckwheat. Fagopyrum esculentum Moench. Promoting the conservation and use of underutilized and neglected crops. No. 19. Rome, Italy Institute of Plant Genetics and Crop Plant Research, Gatersleben/International Plant Genetic Resources Institute. 95 pGoogle Scholar
Carr, PM, Mäder, P, Creamer, NG, Beeby, JS (2012) Editorial: Overview and comparison of conservation tillage practices and organic farming in Europe and North America. Renew Agric Food Syst. 27:26 Google Scholar
Clark, A (2008) Managing Cover Crops Profitably. 3rd ed. Beltsville, MD Sustainable Agriculture Research and Education Program. 244 pGoogle Scholar
Clark, MS, Horwath, WR, Shennan, C, Scow, KM, Lantni, WT, Ferris, H (1999) Nitrogen, weeds and water as yield-limiting factors in conventional, low-input, and organic tomato systems. Agric Ecosyst Environ. 73:257270 Google Scholar
Crawley, MJ (2007) The R Book. Chichester, England John Wiley and Sons. 942 pGoogle Scholar
Creamer, NG, Baldwin, KR (2000) An evaluation of summer cover crops for use in vegetable production systems in North Carolina. HortScience. 35:600603 Google Scholar
Creamer, NG, Dabney, S (2002) Killing cover crops mechanically: review of recent literature and assessment of new research results. Am J Altern Agric. 17:3240 Google Scholar
Deike, S, Pallutt, B, Melander, B, Strassemeyer, J, Christen, O (2008) Long-term productivity and environmental effects of arable farming as affected by crop rotation, soil tillage intensity and strategy of pesticide use: a case-study of two long-term field experiments in Germany and Denmark. Eur J Agron. 29:191199 Google Scholar
Delahaut, KA, Newenhouse, AC (1997) Growing broccoli, cauliflower, cabbage, and other cole crops in Wisconsin: A guide for fresh market growers. Extension Bulletin A3684. Madison, WI University of Wisconsin-Extension. 23 pGoogle Scholar
Dill, GM, CaJacob, CA, Padgette, SR (2008) Glyphosate-resistant crops: adoption, use and future considerations. Pest Manag Sci. 64:326331 Google Scholar
Edwardson, SE (1995) Using growing degree days to windrowing time in buckwheat. Pages 509514 in Current Advances in Buckwheat Research: Proceedings of the 6th International Symposium on Buckwheat. Shinshu, Japan Shinshu University Press Google Scholar
Fabjan, N, Rode, J, Košir, IJ, Wang, Z, Zhang, Z, Kreft, I (2003) Tartary buckwheat (Fagopyrum tataricum Gaertn.) as a source of dietary rutin and quercitrin. J Agric Food Chem. 51:64526455 Google Scholar
Farooq, M, Flower, KC, Jabran, K, Wahid, A, Siddique, KHM (2011) Crop yield and weed management in rainfed conservation agriculture. Soil Tillage Res. 117:172183 Google Scholar
Garton, RW (1994) Influence of conservation tillage on soil temperature and tomato yield. HortScience. 29: 451 [Abstract 155]Google Scholar
Golisz, A, Gawronski, SW (2003) Allelopathic activity of buckwheat against quackgrass. Acta Physiol Plant. 25(Suppl):28 Google Scholar
Golisz, A, Lata, B, Gawronski, SW, Fujii, Y (2007) Specific and total activities of the allelochemicals identified in buckwheat. Weed Biol Manag. 7:164171 Google Scholar
Gorski, T (1986) Buckwheat yield dependency on climatic conditions. Pages 169179 in Buckwheat Research: Proceedings of the 3rd International Symposium on Buckwheat. Pulawy, Poland International Buckwheat Research Association Google Scholar
Hobbs, PR, Sayre, K, Gupta, R (2008) The role of conservation agriculture in sustainable agriculture. Philos Trans R Soc Lond B Biol Sci. 363:543555 Google Scholar
Holland, JM (2004) The environmental consequences of adopting conservation tillage in Europe: reviewing the evidence. Agric Ecosyst Environ. 103:125 Google Scholar
Horowitz, J, Ebel, R, Ueda, K (2010) “No-Till” Farming Is a Growing Practice. Economic Information Bulletin, Number 70. Washington, DC U.S. Department of Agriculture, Economic Research Service. 28 pGoogle Scholar
Hothorn, T, Bretz, F, Westfall, P (2008) Simultaneous inference in general parametric models. Biometrical J. 50:346363 Google Scholar
Hoyt, GD, Walgenbach, JF (1995) Pest evaluation in sustainable cabbage production systems. HortScience. 30:10461048 Google Scholar
Huggins, BDR, Reganold, JP (2008) No-till: the quiet revolution. Sci Am. 299:7077 Google Scholar
Iqbal, Z, Hiradate, S, Noda, A, Isojima, S, Fujii, Y (2003) Allelopathic activity of buckwheat: isolation and characterization of phenolics. Weed Sci. 51:657662 Google Scholar
Kahm, M, Hasenbrink, G, Lictenberg-Frate, H, Ludwig, J, Kschischo, M (2010) grofit: fitting biological growth curves with R. J Stat Software. 33:120 Google Scholar
Kalinova, J (2004) Influence of common buckwheat on growth of other plant species. Pages 529531 in Advances in Buckwheat Research: Proceedings of the 9th International Symposium on Buckwheat. Prague, Czech Republic Research Institute of Crop Production Google Scholar
Kumar, V, Brainard, DC, Bellinder, RR (2009a) Suppression of Powell amaranth (Amaranthus powellii) by buckwheat residues: role of allelopathy. Weed Sci. 57:6673 Google Scholar
Kumar, V, Brainard, DC, Bellinder, RR (2009b) Effects of spring-sown cover crops on establishment and growth of hairy galinsoga (Galinsoga ciliata) and four vegetable crops. HortScience. 44:730736 Google Scholar
Kumar, V, Brainard, DC, Bellinder, RR, Hahn, RR (2011) Buckwheat residue effects on emergence and growth of weeds in winter-wheat (Triticum aestivum) cropping systems. Weed Sci. 59:567573 Google Scholar
Lefcheck, J (2013) R^2 for Linear Mixed Effects Models. http://jonlefcheck.net/2013/03/13/r2-for-linear-mixed-effects-models/. Accessed October 23, 2013Google Scholar
Masiunas, JB, Eastburn, DM, Mwaja, VN, Eastman, CE (1997) The impact of living and cover crop mulch systems on pests and yields of snap beans and cabbage. J Sustain Agric. 9:6189 Google Scholar
Menne, MJ, Durre, I, Vose, RS, Gleason, BE, Houston, TG (2012) An overview of the global historical climatology network—daily database. J Atmos Ocean Technol. 29:897910 Google Scholar
Mischler, R, Duiker, SW, Curran, WS, Wilson, D (2010) Hairy vetch management for no-till organic corn production. Agron J. 102:355362 Google Scholar
Montgomery, D (2007) Dirt: The Erosion of Civilizations. Berkeley and Los Angeles, CA University of California Press. 285 pGoogle Scholar
Morse, RD (1995) No-till, no-herbicide systems for production of transplanted broccoli. Pages 113116 in Kingery, WL, Buehring, N, eds. Conservation Farming—A Focus on Water Quality. Proceedings of the 1995 Southern Region Conservation Tillage for Sustainable Agriculture. Jackson, MS Mississippi State University Google Scholar
Morse, RD (1999) No-till vegetable production—its time is now. Hort Technology. 9:373379 Google Scholar
Mulvaney, MJ, Price, AJ, Wood, CW (2011) Cover crop residue and organic mulches provide weed control during limited-input no-till collard production. J Sustain Agric. 35:312328 Google Scholar
N'Dayegamiye, A, Tran, TS (2001) Effects of green manures on soil organic matter and wheat yields and N nutrition. Can J Soil Sci. 81:371382 Google Scholar
Nakagawa, S, Schielzeth, H (2013) A general and simple method for obtaining R2 from generalized linear mixed-effects models. Methods Ecol Evol. 4:133142 Google Scholar
Parr, M, Grossman, JM, Reberg-Horton, SC, Brinton, C, Crozier, C (2011) Nitrogen delivery from legume cover crops in no-till organic corn production. Agron J. 103:15781590 Google Scholar
Peigné, J, Ball, BC, Roger-Estrade, J, David, C (2007) Is conservation tillage suitable for organic farming? A review. Soil Use Manag. 23:129144 Google Scholar
Pinheiro, J, Bates, DM, Debroy, S, Sarkar, D (2014) nlme: Linear and Nonlinear Mixed Effects Models. http://cran.r-project.org/package=nlme. Accessed January 2, 2014Google Scholar
Pinheiro, JC, Bates, DM (2000) Mixed-Effects Models in S and S-PLUS. New York Springer. 528 pGoogle Scholar
R Core Team. (2013). R: A Language and Environment for Statistical Computing. Vienna, Austria. R Foundation for Statistical Computing. http://www.r-project.org/. Accessed February 13, 2013Google Scholar
Roberts, W, Duthie, J, Edelson, J, Cartwright, B, Shrefler, J, Roe, N, Index, AD (1999) Limitations and possibilities for some conservation tillage systems with vegetable crops in the southern plains of the United States. Hort Technology. 9:359365 Google Scholar
Saunders Bulan, M (2014) A Crop in Context: Buckwheat (Fagopyrum spp.) Farming Systems in Yunnan, China and Wisconsin, USA. Ph.D dissertation. Madison, WI University of Wisconsin-Madison. 301 pGoogle Scholar
Schonbeck, M (1991) Comparison of weed biomass and flora in four cover crops and a subsequent lettuce crop on three New England organic farms. Biol Agric Hortic. 8:123143 Google Scholar
Silva, E (2013) No-till production using the roller-crimper and cover crops in the upper Midwest. Pages 198202 in Proceedings of the Wisconsin Crop Management Conference. Madison, WI University of Wisconsin-Extension. Vol. 52 Google Scholar
Spokas, K, Forcella, F (2009) Software tools for weed seed germination modeling. Weed Sci. 57:216227 Google Scholar
Teasdale, JR, Brandsaeter, LO, Calegari, A, Skora Neto, F (2007) Cover crops and weed management. Pages 4964 in Upadhyaya, MK, Blackshaw, RE, eds. Non-chemical Weed Management: Principles, Concepts and Technology. Wallingford, UK CAB International Google Scholar
Teasdale, JR, Mohler, CL (2000) The quantitative relationship between weed emergence and the physical properties of mulches. Weed Sci. 48:385392 Google Scholar
Tominaga, T, Uezu, T (1995) Weed suppression by buckwheat. Pages 693697 in Current Advances in Buckwheat Research: Proceedings of the 6th International Symposium on Buckwheat. Shinshu, Japan Shinshu University Press Google Scholar
[USDA] U.S. Department of Agriculture National Agricultural Statistics Service (2013) Wisconsin—Vegetables 2012. Madison, WI Wisconsin Field Office. 1 pGoogle Scholar
[USDA] U.S. Department of Agriculture National Agricultural Statistics Service (2014) Vegetables 2013 Summary. Washington, D.C. U.S. Department of Agriculture. 83 pGoogle Scholar
Utset, A, Cid, G (2001) Soil penetrometer resistance spatial variability in a Ferralsol at several soil moisture conditions. Soil Tillage Res. 61:193202 Google Scholar
Vakali, C, Zaller, JG, Köpke, U (2011) Reduced tillage effects on soil properties and growth of cereals and associated weeds under organic farming. Soil Tillage Res. 111:133141 Google Scholar
Van Huyssteen, L (1983) Interpretation and use of penetrometer data to describe soil compaction in vineyards. S Afr J Enol Vitic. 4:5965 Google Scholar
Vollmer, ER, Creamer, N, Reberg-Horton, C, Hoyt, G (2010) Evaluating cover crop mulches for no-till organic production of onions. HortScience. 45:6170 Google Scholar
Walters, R (2005) High Residue Conservation Tillage for Row Crops. Conservation Tillage Underground Report 1. Raleigh, NC North Carolina State University. 4 pGoogle Scholar
Wang, G, McGiffen, ME, Hutchinson, CM, Ifas, F (2008) Summer cover crop and in-season management system affect growth and yield of lettuce and cantaloupe. HortScience. 43:13981403 Google Scholar
Wilhoit, JH, Morse, RD, Vaughn, D (1990) Strip-tillage production of summer cabbage using high residue levels. Appl Agric Res. 5:338342 Google Scholar
Williams, MM, Mortensen, DA, Doran, JW (1998) Assessment of weed and crop fitness in cover crop residues for integrated weed management. Weed Sci. 46:595603 Google Scholar
Wolfe, DW, Topoleski, DT, Gundersheim, NA, Ingall, BA (1995) Growth and yield sensitivity of four vegetable crops to soil compaction. J Am Soc Hortic Sci. 120:956963 Google Scholar
Wortman, SE, Francis, CA, Bernards, ML, Drijber, RA, Lindquist, JL (2012) Optimizing cover crop benefits with diverse mixtures and an alternative termination method. Agron J. 104:14251435 Google Scholar
Zhu, Y-GG, He, Y-QQ, Smith, SE, Smith, FA (2002) Buckwheat (Fagopyrum esculentum Moench) has high capacity to take up phosphorus (P) from a calcium (Ca)-bound Source. Plant Soil. 239:18 Google Scholar