Architectural Characteristics and Heliotropism May Improve Spray Droplet Deposition in the Middle and Low Canopy Layers in Soybean

Müller, Mariele; Rakocevic, Miroslava; Caverzan, Andréia; Boller, Walter; Chavarria, Geraldo

doi:10.2135/cropsci2017.11.0653

Cited by 10 publications

(9 citation statements)

References 37 publications

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“…The product deposition in the soybean canopy provided by fungicide application in the lower part is generally low resulting in inefficient disease control (29). Therefore, it is necessary to develop strategies to increase the deposition of herbicide spray droplets on the lower part of the canopy.…”

Section: Resultsmentioning

confidence: 99%

Grain productive efficiency of soybean plants under lactofen application

2020

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Adverse factors cause a decrease in the productive potential of crops. For soybean [(Glycine max (L.) Merrill], the excessive growth is a factor that results in plants with low effective efficiency. Thus, plants with an architecture that favours greater interception of solar radiation and deposition of pesticides tend to be more productive. The objective of this study is to evaluate the different application of lactofen, which is used as a growth inhibitor, improve the productive efficiency of soybeans by increasing the biological activity of the leaves. The study was conducted in the field with soybean cultivars NA 5909 RG and BMX Potência RR. The experiment followed a randomized complete block design with four treatments and five replicates: T1: control; T2: application of 140 g a.i ha-1 of lactofen in phenological stage V3; T3: application of 140 g a.i ha-1 of lactofen in phenological stage V6; and T4: application of 70 g a.i ha-1 of lactofen in phenological stage V3 + 70 g a.i ha-1 of lactofen in phenological stage V6. The interception of photosynthetically active radiation in the lower layer increased in all treatments. Lactofen application increased the percent area covered and the number of phytosanitary products spray droplets per cm² in the middle and lower layers of the plants. The lower third of the plants experienced the greatest effect of the treatments with regard to the number of pods, grains and grain weight, with treatment T2 presenting significant increases. The use of lactofen as a growth inhibitor at the beginning of pod development in soybean caused changes to plant architecture and root development, consequently enhanced the productive efficiency of the plant, primarily due to increased grain production in the lower layer. Future research using lactofen in different phenological stages and cultivars may provide more insights in to the performance of this growth inhibitor in soybean.

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Section: Resultsmentioning

confidence: 99%

Grain productive efficiency of soybean plants under lactofen application

2020

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“…The greater disease severity observed in the lower third of the Cerro Largo experiment occur in the SYN 1561 IPRO cultivar, which is not resistant to ASR. In the lower third of the plants it can be veri ed conditions that favored ASR such as longer periods of leaf wetness, higher air relative humidity, lower wind speed, di culty for the fungicide to reach this location on the plant (Cunha et al 2006;Müller et al 2018) and lower incidence of radiation (Furtado et al 2009). In addition, the leaves allocated in the lower third tend to be the rst to be infected, being exposed to the pathogen for longer time (Fiallos and Forcelini 2013).…”

Section: Discussionmentioning

confidence: 99%

Forecasting system in decision-making on the chemical control of Asian soybean rust

Engers,

Radons,

Henck

et al. 2023

Preprint

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Asian soybean rust (ASR; Phakopsora pachyrhizi) is one of the most important diseases of soybean that can reduce soybean yield. The frequent use of site-specific fungicides has led to the evolution of resistant populations of the pathogen, resulting in reduced effectiveness of chemical control. Thus, to reduce the number of fungicide sprays in the crop, disease forecasting systems are tools that could help in the decision-making process about the time for fungicide application. The aim of this study was to develop and validate a forecasting system for ASR to guide chemical control. Four experiments were carried out in three locations (Cerro Largo, Entre Ijuís and Passo Fundo) in the state of Rio Grande do Sul in southern Brazil. Treatments consisted of intervals of calculated severity values (CSV) between fungicide applications, in addition to control without application. Thousand-grain mass and yield (kg ha-1) were evaluated in addition to ASR severity. The data were subjected to analysis of variance using the F test and the means compared using the Tukey’s test at 5% error probability level. The results showed that the disease forecasting system allowed the yield maintenance in different locations and crop seasons, associated with a decrease in the number of fungicide sprays. Thus, we conclude that the proposed disease forecasting system is a viable tool for ASR management.

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“…Changed canopy architecture can also improve effectiveness of fungicides and other plant protection products inside the canopy (Müller et al, 2018).…”

Section: Plant and Crop Canopy Architecturementioning

confidence: 99%