5 research outputs found
Effects of Insecticide and Tolerant Alfalfa Cultivars on Potato Leafhopper (\u3cem\u3eEmpoasca fabae\u3c/em\u3e) Populations and Forage Yields in Quebec (Canada)
The potato leafhopper [PLH, Empoasca fabae (Harris)], which affects several crops including alfalfa (Medicago sativa L.), is a recurrent problem in several regions of Quebec. The objective was to evaluate alfalfa management tools in order to reduce yield losses caused by this pest. An experiment was conducted at two sites in Quebec over three field seasons to evaluate the impact of insecticide applications and the use of PLHtolerant cultivars on forage yield and PLH populations. Foliar insecticide applications in the seeding year reduced PLH populations but generally failed to impact alfalfa yields compared to untreated alfalfa. However, in one experiment at one site, applications done in the seeding year resulted in increased first-cut alfalfa yields in the post-seeding year compared to untreated alfalfa, even if PLH populations were low. Differences in yields between PLH-tolerant and PLH-susceptible cultivars were minimal in the seeding and post-seeding years regardless of the PLH population levels. However, two PLH-tolerant cultivars produced lower yields compared to other cultivars in the post-seeding year at one site. Preliminary results suggest that foliar insecticide applications could be a more effective way to reduce PLH populations than PLH-tolerant cultivars. However, more data will be required to confirm these results and determine the impact of these management tools on alfalfa yields
Evaluation of Annual Companion Crops for the Establishment of Perennial Forage Crops in Eastern Canada
The use of companion crops when establishing perennial forages is desirable as it often reduces weed growth and increases forage biomass in the seeding year. In eastern Canada, oat (Avena sativa L.) is the main species used as companion crop; although other species are used, they have not been systematically evaluated. A field study was established in 2019 at three sites in Québec, Canada, to contrast the use of six annual species as companion crops for the establishment of lucerne (Medicago sativa L.)-timothy (Phleum pratense L.) mixtures. Species evaluated include berseem clover (Trifolium alexandrinum L.), annual ryegrass (Lolium multiflorum Lamarck), forage pea (Pisum sativum L.), forage oat, Japanese millet [Echinochloa esculenta (A. Braun) H. Scholz], and sudangrass [Sorghum × drummondii (Nees ex. Steud.) Millsp. & Chase]. The control treatment consisted of the perennial species seeded without companion crop. Treatments were seeded at three dates (mid-May to early-June, mid-June to early-July, and early August) and evaluated during the seeding year based on biomass production and botanical composition. Overall, across sites, for the first two seeding dates, highest annual forage yields were observed with sudangrass, Japanese millet, and oat as companion crops. The use of these species increased yields by 1.8 to 2.5 Mg ha-1 on a dry matter basis (DM) compared to the control which yielded an average of 3.7 Mg DM ha-1. For the early August seeding, response varied significantly across sites. Annual yields were the highest with the use of oat at two sites (avg. of 2.4 Mg DM ha-1), whereas no differences between treatments were observed at the other site. Companion crop species which maximized total forage yields in the seeding year often reduced weed biomass, but also that of perennial species. The impact of treatments on the survival of perennial forages and their production during the first post-seeding year will be presented in a later publication
Impacts of Improved Switchgrass and Big Bluestem Selections on Yield, Morphological Characteristics, and Biomass Quality
Switchgrass (Panicum virgatum L.) and big bluestem (Andropogon gerardii V.) are promising warm-season grasses for biomass production. Understanding the morphological and quality-related traits of these grasses can guide breeders in developing strategies to improve yield and quality for bioindustrial applications. Elite selections were made in Southern Quebec from four promising varieties of switchgrass and one of big bluestem. Biomass yield, morphological characteristics, and selected quality traits were evaluated at two sites in 2011 and 2012. Significant variation was detected for all measured characteristics, with differences varying by site and year. In some cases the selection process modified characteristics including increasing height and reducing tiller mortality. Switchgrasses reached a similar tiller equilibrium density in both years of 690 m−2 and 379 m−2 at a productive and marginal site, respectively. Differences in yield were pronounced at the marginal site, with some advanced selections having a higher yield than their parent varieties. Switchgrass yields were generally greater than those of big bluestem. A delayed spring harvest date greatly reduced yield but reduced moisture content and slightly increased cellulose concentration. Big bluestem had a higher cellulose content than switchgrass, likely due to greater stem content
Effects of Soil Characteristics on Spring-Harvested Switchgrass Biomass Composition
<p>Switchgrass (<i>Panicum virgatum</i> L.) is a promising bioenergy crop for temperate regions. Overwintering has been used to improve biomass quality, resulting in a more efficient combustion, partially due to a reduction in minerals concentration. This study examines the effects of soil composition on overwintered switchgrass composition. Samples were collected in the spring from 58 environments in Southern Quebec to determine possible relationships between soil composition and biomass quality. Principal component analysis and stepwise regressions were used to identify relationships between soil and biomass compositions. Soil parameters monitored explained 74% of the variation in biomass silicon (Si) concentration, 45% of the variation in ash, and 32% of the variation in magnesium (Mg). Soil composition had limited effects on the concentration of other elements in switchgrass biomass. Switchgrass biomass quality is influenced by soil composition and appears well suited to biomass combustion when overwintered and harvested in the spring.</p