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Pyroxsulam Compared with Competitive Standards for Efficacy in Winter Wheat

Published online by Cambridge University Press:  20 January 2017

Patrick W. Geier*
Affiliation:
Kansas State University Agricultural Research Center, Hays, KS 67601
Phillip W. Stahlman
Affiliation:
Kansas State University Agricultural Research Center, Hays, KS 67601
Dallas E. Peterson
Affiliation:
Department of Agronomy, Kansas State University, Manhattan, KS 66506
Mark M. Claassen
Affiliation:
Department of Agronomy, Kansas State University, Manhattan, KS 66506
*
Corresponding author's E-mail: [email protected]

Abstract

Field studies at six locations over 3 yr in Kansas compared pyroxsulam at two application timings to competitive standards for winter annual weed control in winter wheat. Pyroxsulam applied fall-POST (FP) controlled downy brome 84 to 99% and was similar to or greater than sulfosulfuron, propoxycarbazone, or propoxycarbazone plus mesosulfuron. Downy brome control was lower when application timing was delayed until spring (SP), such that no herbicide provided more than 90% downy brome control. Cheat control was 97% or more with almost all herbicides applied FP, and greater than 90% in most locations when herbicides were applied SP. Sulfosulfuron was the exception with only 30 to 81% cheat control. All FP-applied herbicides, except sulfosulfuron at Manhattan, KS, controlled blue mustard 95% or more. Pyroxsulam and propoxycarbazone plus mesosulfuron FP completely controlled henbit at Hesston, KS, in 2009, but no herbicide treatment provided more than 60% control when applied SP. Averaged over application timings, pyroxsulam provided the greatest henbit control (76 and 78%) at Manhattan and Hays, respectively, in 2009, and FP treatments were 33 and 28 percentage points more effective than SP treatments at those locations. Averaged over application timing, wheat yields did not differ between herbicide treatments in five of six locations. Averaged over herbicide treatment, FP-treated wheat yielded more grain than SP-treated wheat at three of the six locations.

En seis localidades de Kansas, se realizaron estudios de campo durante tres años comparando pyroxsulam en dos diferentes tiempos de aplicación en estándares competitivos para el control de maleza anual de invierno, en cultivo de trigo invernal (Triticum aestivum). El pyroxsulam aplicado en post emergencia en otoño (FP) controló Bromus tectorum 84 a 99% y obtuvo resultados similares o mayores que sulfosulfurón, propoxycarbazone o propoxycarbazone más mesosulfurón. El control de B. tectorum fue menor cuando las etapas de aplicación se retrasaron hasta la primavera (SP), de tal manera, que ningún herbicida proporcionó más de 90% de control de esta maleza. El control de B. secalinus fue de 97% o más con todos los herbicidas aplicados FP y por encima del 90% en la mayoría de las localidades cuando los herbicidas se aplicaron SP. El sulfosulfurón fue la excepción, con solamente del 30 al 81% de control de B. secalinus. Todos los herbicidas que se aplicaron FP, con excepción de sulfosulfurón en Manhattan, controlaron Chorispora tenella 95% o más. Pyroxsulam y propoxycarbazone más mesosulfurón FP controlaron totalmente Lamium amplexicaule en 2009 en Hesston, pero ningún tratamiento de herbicida proporcionó más del 60% de control cuando se aplicó SP. Promediando sobre tiempos de aplicación, pyroxsulam proporcionó el mayor control de L. amplexicaule (76 y 78%, respectivamente) en Manhattan y Hays en 2009, y los tratamientos FP fueron 33 y 28 puntos porcentuales más efectivos que los tratamientos SP en esas localidades. Promediado a través de tiempos de aplicación, los rendimientos de trigo invernal no fueron diferentes entre tratamientos de herbicida, en cinco de las seis localidades. Promediado a través de tratamientos de herbicida, el trigo tratado FP proporcionó mayor rendimiento de grano que el que fue tratado SP, en tres de las seis localidades.

Type
Weed Management—Major Crops
Copyright
Copyright © Weed Science Society of America 

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