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Mow-kill Regulation of Winter Cereals for Spring No-till Crop Production

Published online by Cambridge University Press:  12 June 2017

Erik D. Wilkins  and
Robin R. Bellinder
Erik D. Wilkins
Affiliation:
Dep. Fruit and Veg. Sci., Plant Sci. Bldg., Cornell Univ., Ithaca, NY 14853-0327
Robin R. Bellinder
Affiliation:
Dep. Fruit and Veg. Sci., Plant Sci. Bldg., Cornell Univ., Ithaca, NY 14853-0327
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Abstract

Field studies determined the influence of developmental stage on mow-killing of winter wheat and rye. Both crops were clipped at either three or four different growth stages in 1992 and 1993. When mowed at first node, wheat biomass was 4350 and 1970 kg/ha in 1992 and 1993, respectively. At this stage, primary tiller apices were below 10 cm and regrowth was vigorous. Mowing prior to 75% heading consistently yielded more than 1000 kg/ha regrowth 8 wk later. Wheat cut after flowering produced 15 460 and 9160 kg/ha dry matter in 1992 and 1993, respectively, but less than 30 kg/ha total regrowth. At first and second node, rye produced 4440 and 1800 kg/ha biomass in 1992 and 1993. When mowed belore boot, more than 50% of the total rye biomass was due to regrowth. Rye mowed at boot yielded 6940 and 3740 kg/ha in 1992 and 1993 respectively, and regrowth measured 780 and 910 kg/ha 8 wk later. Mowing after flowering resulted in no measurable regrowth. Soil temperature and PAR were affected by mow-kill date and biomass. Biomass at first mowings (first and second node) in both wheat and rye reduced seasonal soil temperatures 3.5 C compared to bare soil temperatures; while biomass at kernal-filling lowered temperatures 6.0 C. Measured 8 wk after mowing, first node mowings absorbed between 55% and 70% PAR, while plants mowed at kernal-filling absorbed less than 5%.

Keywords

Rye. Secale cereale L., winter wheat, Triticum aestivum L.Feekes scaleherbicide reductionmulch regrowthmulch regulationphoto-synthetically active radiation
Type
Research
Information
Weed Technology , Volume 10 , Issue 2 , June 1996 , pp. 247 - 252
Copyright
Copyright © 1996 by the Weed Science Society of America 

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References

Literature Cited

1. Aase, J. K., and Siddoway, F. H. 1975. Regrowth of spring-clipped winter wheat in the northern great plains of the United States. Can. J. Plant Sci. 55:631633.Google Scholar
2. Barnes, J. P., and Putnam, A. R. 1983. Rye residues contribute to weed suppression in no-tillage cropping systems. J. Chem. Ecol. 9:10451057.Google Scholar
3. Baskin, J. M., and Baskin, C. C. 1986. Temperature requirements for afterripening in seeds of nine winter annuals. Weed Res. 26:375380.Google Scholar
4. Baskin, J. M., and Baskin, C. C. 1987. Temperature requirements for afterripening in buried seeds of four summer annual weeds. Weed Res. 27:385389.CrossRefGoogle Scholar
5. Bristow, K. L., 1988. The role of mulch and its architecture in modifying soil temperature. Aust. J. Soil Res. 26:269280.Google Scholar
6. Crutchfield, D. A., Wicks, G. A., and Burnside, O. C. 1986. Effect of winter wheat (Triticum aestivum L.) straw on weed control. Weed Sci. 34:110114.Google Scholar
7. DeAlmeida, F. S., 1985. Effect of some winter mulches on the soil weed infestation. Proc. Br. Crop. Prot. Conf. Weeds. 2:651659.Google Scholar
8. Greb, B. W., 1967. Percent soil cover by six vegetative mulches. Agron. J. 59:610611.Google Scholar
9. Hayes, W. A., 1982. What is minimum tillage? p. 1534 in Hayes, W. A., ed. Minimum Tillage Farming. No-till Farmer, Inc., Brookfield, WI.Google Scholar
10. Kim, Y. H., Jung, P. K., Oh, S. J., and Ko, M. H. 1991. Effects on soil erosion control with different levels of barley straw mulches. Res. Rep. Rural Dev. Adm. 33:2934.Google Scholar
11. Lanfranconi, L. E., Bellinder, R. R., and Wallace, R. W. 1993. Grain rye residues and weed control strategies in reduced tillage potatoes. Weed Technol. 7:2328.Google Scholar
12. Large, E. C., 1954. Growth stages in cereals: illustration of the Feekes scale. Plant Pathol. 3:128129.Google Scholar
13. Lodhi, M. A. K., Blal, R., and Malik, K. A. 1987. Allelopathy in agroecosystems: wheat phytotoxicity and its possible roles in crop rotation. J. Chem. Ecol. 13:18811891.Google Scholar
14. Oke, T. R., 1990. Intentionally modified climates. p. 230261 in Oke, T. R., ed. Boundary Layer Climates, 2nd edit. Routes. New York, NY.Google Scholar
15. Papendick, R. I., 1987. Tillage and water conservation experience in the Pacific northwest USA. Soil Use Manage. 3:6974.Google Scholar
16. Ross, M. A., and Lembi, C. A. 1985. Methods of Weed Control. p. 2045 in Crochiere, N. C., ed. Applied Weed Science. MacMillan Pub. New York, NY.Google Scholar
17. Teasdale, J. R., and Mohler, C. L. 1993. Light transmittance, soil temperature, and soil moisture under residue of hairy vetch and rye. Agron. J. 85:673680.Google Scholar
18. Thorne, G. N., Pearman, I., Day, W., and Todd, A. D. 1988. Estimation of radiation interception by winter wheat from measurements of leaf area. J. Agric. Sci. 110:101108.Google Scholar
19. Wilcox, G. E., and Pfeiffer, C. L. 1990. Temperature effect on seed germination, seedling root development, and growth of several vegetables. J. Plant Nutr. 13:13931404.Google Scholar
20. Young, H. M. Jr., 1982. No-tillage, the ultimate? p. 1104 in Young, H. M., ed. No-tillage Farming. No-till Fanner Inc. Brookfield, WI.Google Scholar