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Impact of Fallow Programs and Fumigants on Nutsedge (Cyperus spp.) Management in Plasticulture Tomato

Published online by Cambridge University Press:  20 January 2017

Cristiane Alves
Affiliation:
Horricultural Sciences Department, University of Florida, Gulf Coast Research and Education Center (GCREC), Wimauma, FL 33598
Andrew W. MacRae
Affiliation:
Horricultural Sciences Department, University of Florida, Gulf Coast Research and Education Center (GCREC), Wimauma, FL 33598
Clinton J. Hunnicut
Affiliation:
Horricultural Sciences Department, University of Florida, Gulf Coast Research and Education Center (GCREC), Wimauma, FL 33598
Tyler P. Jacoby
Affiliation:
Horricultural Sciences Department, University of Florida, Gulf Coast Research and Education Center (GCREC), Wimauma, FL 33598
Gregory E. MacDonald
Affiliation:
Agronomy Department, University of Florida, P.O. Box 110500, Gainesville, FL 32611
Peter J. Dittmar*
Affiliation:
Horticultural Sciences Department, P.O. Box 110690, Gainesville, FL 32611
*
Corresponding author's E-mail: [email protected]

Abstract

With the loss of methyl bromide (MeBr) and high prices of alternatives, tomato growers are applying lower fumigant rates or adopting a reduced system. Without the broad-spectrum control provided by the complete fumigant system, a fallow weed program might be needed to avoid an increase in pest pressure with consecutive years of application of the reduced-fumigant system. Nutsedges are among the pests of interest due to their fast reproduction by underground structures and ability to spread and quickly infest a field. Field trials were conducted between February and December of 2011 in Balm, FL, to evaluate the impacts of fallow treatments, fumigants, and halosulfuron on nutsedge control. The trial design was a split–split plot with main, sub-, and subsubplots being fallow, fumigant, and herbicide treatment, respectively. Fallow treatments were spaced evenly throughout the fallow season and consisted of sequential combinations of cultivation (C) and/or glyphosate (G) applied at 2.24 kg ae ha−1; including: C, CC, G, GG, CG, GC, GCG, and NO (nontreated control). Fumigant treatments included a reduced-fumigant system of 1,3-dichloropropene plus chloropicrin 40:60 (1,3-D + pic) at 281 kg ha−1, a complete fumigant system of dimethyl disulfide plus chloropicrin 79:21 (DMDS + pic) at 545 kg ha−1, and no fumigant (NoFum). Herbicide treatments were either two POST applications of halosulfuron at 39 g ai ha−1 (Hal) or no halosulfuron (NoHal). In general, the fallow weed treatment GCG was the most effective in reducing nutsedge shoot emergence through the plastic mulch. When the reduced-fumigant system 1,3-D + pic was combined with GCG fallow treatment and halosulfuron (GCG:1,3-D + pic:Hal), no differences were found between this combination and the complete fumigant system DMDS + pic with halosulfuron and combined with CC, G, GG, CG, GC or GCG. This study shows the importance of adding a fallow weed program and halosulfuron to either a reduced or complete fumigation system to minimize the reproduction and growth of nutsedges.

Con la pérdida de methyl bromide (MeBr) y los altos precios de las alternativas, los productores de tomate están aplicando dosis más bajas de fumigante o adoptando un sistema reducido. Sin el control de amplio espectro que se obtiene con un sistema de fumigación completo, un programa de manejo de malezas con barbecho limpio podría ser requerido para evitar el incremento en la presión de esta plaga en los años consecutivos a la aplicación del sistema de fumigación reducida. Cyperus spp. está entre las plagas de interés debido a su rápida reproducción por medio de estructuras subterráneas y su habilidad de dispersarse y rápidamente infestar un campo. Se realizaron experimentos de campo entre Febrero y Diciembre de 2011 en Balm, FL, para evaluar los impactos de tratamientos de barbecho, fumigantes, y halosulfuron sobre el control de Cyperus spp. El diseño del experimento fue parcelas divididas en dos niveles siendo el barbecho, el fumigante y el tratamiento del herbicida la parcela principal, la subparcela y la sub-subparcela, respectivamente. Los tratamientos de barbecho fueron distribuidos en forma uniforme a lo largo de la temporada de barbecho y consistieron en combinaciones secuenciales de cultivo con rastra de discos (C) y/o glyphosate (G) aplicado a 2.24 kg ae ha−1; incluyendo: C, CC, G, GG, CG, GC, GCG, y NO (testigo no tratado). Los tratamientos de fumigantes incluyeron un sistema de fumigación reducida de 1,3-dichloropropene más chloropicrin 40:60 (1,3-D + pic) a 281 kg ha−1, un sistema de fumigación completa de dimethyl disulfide más chloropicrin 79:21 (DMDS + pic) a 545 kg ha−1, y sin fumigante (NoFum). Los tratamientos de herbicidas fueron dos aplicaciones POST de halosulfuron a 39 g ai ha−1 (Hal) o sin halosulfuron (NoHal). En general, el tratamiento de barbecho GCG fue el más efectivo en reducir la emergencia de plantas de Cyperus spp. a través de la cobertura plástica. Cuando el sistema de fumigación reducida 1,3 + pic fue combinado con el tratamiento de barbecho GCG y halosulfuron (GCG:1,3-D + pic:Hal), no se encontraron diferencias entre esta combinación y el sistema de fumigación completa DMDS + pic con halosulfuron y combinado con CC, G, GG, CG, GC o GCG. Este estudio muestra la importancia de agregar un programa de barbecho y halosulfuron a sistemas de fumigación completa o reducida para minimizar la reproducción y crecimiento de Cyperus spp.

Type
Weed Management—Other Crops/Areas
Copyright
Copyright © Weed Science Society of America 

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