Biennial wormwood (Artemisia biennis) competition with soybean (Glycine max)

Biennial wormwood has become a serious weed of several crops in the northern Great Plains of the United States and Prairie Provinces of Canada. Greenhouse replacement series experiments were conducted to investigate the effects of watering regime (stressed and non-stressed) and nitrogen rate (50, 100, 150, and 200 mg kg-1 of soil) on competition between soybean and biennial wormwood. Soybean height was reduced after 9 weeks of competition with biennial wormwood compared with soybean grown in monoculture, whereas biennial wormwood plants were taller when grown with soybean than in monoculture. The change in plant height indicated that biennial wormwood height was increased due to interspecific competition, whereas soybean height was reduced. When moisture was limited, the relative yield of biennial wormwood was greater than that of soybean, indicating that biennial wormwood was more aggressive than soybean. Soybean growth was unaffected by an increase in nitrogen rate, whereas biennial wormwood fresh weight was 30% greater when the nitrogen rate was increased from 50 to 200 mg kg-1. Biennial wormwood aggressivity tended to increase as the nitrogen rate was increased from 50 to 200 mg kg-1. Overall results suggest that the negative impact of biennial wormwood competition with soybeans under field conditions may increase when soil moisture is limited and nitrogen fertility is increased.L'armoise bisannuelle est devenue une importante mauvaise herbe pour plusieurs cultures dans le nord des Grandes Plaines des États-Unis et dans les provinces des Prairies au Canada. Des expériences avec des séries de remplacement ont été menées en serre afin d'étudier les effets du régime d'alimentation en eau (stressant et non stressant) et de la quantité d'azote (50, 100, 150 et 200 mg kg-1 de sol) sur la compétition entre le soja et l'armoise bisannuelle. Après 9 semaines de compétition avec l'armoise bisannuelle, la taille du soja était inférieure à celle du soja en monoculture alors que l'armoise bisannuelle était plus grande en présence de soja qu'en monoculture. Les différences dans la taille des plantes montrent que la compétition interspécifique a fait augmenter celle de l'armoise bisannuelle et diminuer celle du soja. Lorsque l'eau était un facteur limitatif, le rendement relatif de l'armoise bisannuelle était plus élevé que celui du soja, ce qui montre que l'armoise bisannuelle était plus agressive que le soja. L'augmentation de la quantité d'azote n'a pas affecté la croissance du soja. Cependant, le poids de matière fraîche de l'armoise bisannuelle était 30 % plus élevé lorsque la quantité d'azote est passée de 50 à 200 mg kg-1. L'agressivité de l'armoise bisannuelle a eu tendance à augmenter lorsque la quantité d'azote est passée de 50 à 200 mg kg-1. Globalement, les résultats montrent que les impacts négatifs de la compétition entre l'armoise bisannuelle et le soja, dans des conditions naturelles, peuvent s'accroître lorsque l'eau manque et que la quantité d'azote disponible augmente

Influence of Crop Rotation, Tillage, and Management Inputs on Weed Seed Production

Approaches to crop production that successfully reduce weed seed production can benefit farming systems by reducing management inputs and costs. A 5-yr rotation study was conducted in order to determine the effects that interactions between crop rotation, tillage, and amount of herbicide and fertilizer (management inputs) have on annual grass and broad-leaved weed seed production and fecundity. There were 10 crop rotation and tillage system combinations and three levels of management inputs (high, medium, and low). Green and yellow foxtail were the major weed species, and together they yielded between 76 and 93% of collected weed seeds. From 1990 to 1994, average grass weed seed productions were 7.3 by 103, 3.7 by 103 6.1 by 103 and 5.7 by 103 seeds m−-2, whereas average broad-leaved weed seed productions were 0.4 by 103, 0.4 by 103, 1.4 by 103, and 0.4 by 103 seeds m−-2 in crop rotations using conventional tillage (moldboard plow), conservation tillage, no tillage, and ridge tillage, respectively. Crop rotations using conventional or ridge tillage consistently produced more grass and broad-leaved weed seeds, especially in low-input plots. There was little difference in weed seed production among input levels for crop rotations using conservation tillage. Comparing rotations that began and ended with a corn crop revealed that by increasing crop diversity within a rotation while simultaneously reducing the amount of tillage, significantly fewer grass and broad-leaved weed seeds were produced. Among the rotations, grass and broad-leaved weed fecundity were highly variable, but fecundity declined from 1990 to 1994 within each rotation, with a concomitant increase in grass and broad-leaved weed density over the same period. Crop rotation in combination with reduced tillage is an effective way of limiting grass and broad-leaved weed seed production, regardless of the level of management input applied