Yield components of soybean cultivars under sowing densities

Paraginski, João Antônio; Toebe, Marcos; Moraes, Mariana Poll; Souza, Rafael Rodrigues de; Paraginski, Pedro Elmar; Bittencourt, Karina Chertok

doi:10.1590/0034-737X202269040005

ABSTRACT

The aim of this study was to assess yield components and grain yield of soybean cultivars in response to sowing densities. For this, two soybean cultivars and five sowing densities were tested, in a two-factor scheme. The following yield components were measured by the end of the cycle: plant height; insertion height of the first pod; number of nodes per plant; number of pods with one, two, three and four grains; number of pods per plant; number of grains per plant; weight of a thousand grains; humidity and grain yield. Sowing densities did not cause significant variations of grain yield (bags ha^-1) for any cultivar, however, higher populational densities promoted a reduction in the number of pods with two and three grains, as well as a reduction in the total number of pods and grains per plant for both cultivars. Cultivar NS 5700 IPRO was the most productive, with a higher number of pods with two and three grains and number of pods and grains per plant.

Keywords:
Glycine max; plant population; plasticity; grain yield

INTRODUCTION

Soybean [Glycine max (L.) Merrill] is the most cultivated legume in the world. In Brazil, soybean production has increased significantly over the last few years, with a record production of 120.93 million tons in the 2019/2020 harvest, representing a 5.1% increase compared to the previous growing season (Conab, 2020Conab - Companhia Nacional de Abastecimento2020 Acompanhamento da Safra Brasileira: Grãos: Décimo primeiro levantamento: Safra 2019/20. Available at: Available at: https://www.conab.gov.br . Accessed on: March 14th, 2021.
https://www.conab.gov.br... ). This yield increase stems mainly from intense plant breeding programs that result in annual launches of ever more productive and adapted genotypes, as well as from the improvement and development of management techniques that allow the maximum performance of cultivars (Sediyama et al., 2015SediyamaTSilvaFBorémA2015 Soja do plantio à colheita. Viçosa, UFV . 333p).

Among soybean management techniques, cultivar choice and sowing density are some of the factors that influence soybean yield components, and consequently, grain yield the most (Mauad et al., 2010MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181). An adequate plant population is determinant for the spatial arrangement of plants, once it interferes with the closing speed of interlines (Balbinot Junior et al., 2016Balbinot JuniorAAProcópioSONeumaierNFerreiraASWernerFDebiasiHFranchiniJC2016 Semeadura cruzada, espaçamento entre fileiras e densidade de semeadura influenciando o crescimento e a produtividade de duas cultivares de soja. Revista de Ciências Agroveterinárias, 15:83-93; Masino et al., 2018MasinoARugeroniPBorrásLRotundoJ2018 Spatial and temporal plant-to-plant variability effects on soybean yield. European Journal of Agronomy, 98:14-24), which directly affects light, water and nutrient uptake (Procópio et al., 2013ProcópioSOBalbinot JuniorAADebiasiHFranchiniJCPanisonF2013 Plantio cruzado na cultura da soja utilizando uma cultivar de hábito de crescimento indeterminado. Revista de Ciências Agrárias, 56:319-325), and therefore, plant growth and yield (Lima et al., 2012LimaSFAlvarezRCFTheodoroGFBavarescoMSilvaKS2012 Efeito da semeadura em linhas cruzadas sobre a produtividade de grãos e a severidade da ferrugem asiática da soja. Bioscience Journal, 28:954-962).

In general, at low densities, soybean plants tend to produce fewer branches and increase the number of pods per plant, thus compensating for the lower number of individual plants per area with higher production per plant. On the other hand, at high population densities, there is less branch production, and the production of each plant is smaller and more dependent on the main branch (Ferreira et al., 2016FerreiraASBalbinot JúniorAAWernerFZucareliCFranchiniJCDebiasiH2016 Plant density and mineral nitrogen fertilization influencing yield, yield components and concentration of oil and protein in soybean grains. Bragantia, 75:362-370; Werner et al., 2016WernerFBalbinot JúniorAAFerreiraASAguiar e SilvaMADebiasiHFranchiniJC2016 Soybean growth affected by seeding rate and mineral nitrogen. Revista Brasileira de Engenharia Agricola e Ambiental, 20:734-738; Ferreira et al., 2018).

However, this response can be affected by soybean’s high plasticity, which consists of the ability to adapt to environmental and management conditions, through morphological changes and yield components, to adapt them to the available space and the competition condition imposed by the arrangement of plants, thus maintaining its yield even in face of significant variations in plant density (Lopes & Lima (2015LopesNFLimaMGS2015 Fisiologia da Produção. Viçosa, UFV. 492p); De Luca et al., 2014De LucaMJNogueiraMAHungriaM2014 Feasibility of lowering soybean planting density without compromising nitrogen fixation and yield. Agronomy Journal, 106:2118-2124; Cruz et al., 2016CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06; Ferreira et al., 2018FerreiraASBalbinot JúniorAAWernerFFranchiniJCZucareliC2018 Soybean agronomic performance in response to seeding rate and phosphate and potassium fertilization. Revista Brasileira de Engenharia Agrícola e Ambiental, 22:151-157).

Moreover, genotypes may respond differently to sowing densities, which means a certain cultivar can be more productive in either higher or lower populations (Soares et al., 2015SoaresIORezendePMBruziATZuffoAMZambiazziEVFronzaVTeixeiraCM2015 Interaction between Soybean Cultivars and Seed Density. American Journal Plant Science, 06:1425-1434). In this sense, while some authors have verified sowing densities may interfere with soybean yield (Soares et al., 2015SoaresIORezendePMBruziATZuffoAMZambiazziEVFronzaVTeixeiraCM2015 Interaction between Soybean Cultivars and Seed Density. American Journal Plant Science, 06:1425-1434; Balbinot Junior et al., 2016Balbinot JuniorAAProcópioSONeumaierNFerreiraASWernerFDebiasiHFranchiniJC2016 Semeadura cruzada, espaçamento entre fileiras e densidade de semeadura influenciando o crescimento e a produtividade de duas cultivares de soja. Revista de Ciências Agroveterinárias, 15:83-93), others have found this characteristic did not variate as a function of plant population (Procópio et al., 2013ProcópioSOBalbinot JuniorAADebiasiHFranchiniJCPanisonF2013 Plantio cruzado na cultura da soja utilizando uma cultivar de hábito de crescimento indeterminado. Revista de Ciências Agrárias, 56:319-325; Ribeiro et al., 2017RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08). Therefore, the aim of this study was to assess yield components and grain yield of soybean cultivars in response to sowing densities.

MATERIAL AND METHODS

The experiment was carried out in farm fields (27º 52’ 28” S, 53º 49’ 57” W, 491 meters above sea level) located in the municipality of Santo Augusto in the state of Rio Grande do Sul (RS), Brazil, during the 2019/2020 agricultural harvest. In this region, the climate is classified as Cfa (Humid subtropical climate), according to Köppen-Geiger’s classification, and the majority of soils from cultivation areas are classified as Latosolic Dystropheric Red Nitosol (Cunha et al., 2004CunhaNGSilveiraRJCSeveroCRS2004 Estudo de Solos do Município de Santo Augusto - RS. Pelotas, Embrapa Clima Temperado. 64p).

Cultivars NS S700 IPRO and NS 6010 IPRO were used in the experiments at five sowing densities (12.20, 13.64, 14.08, 14.92 and 15.46 seeds per meter), in a two-factor scheme and a randomized block design with three repetitions. Seeds were previously treated with Fortenza^® Duo (Fortenza 600 FS^® + Cruiser^® 600 FS + Maxim Advanced^®), inoculated with Atmo^® (Bradyrhizobium japonicum), and co-inoculated with AzzoFix^® (Azospirillum brasilense, strains AbV5 and AbV6), besides adding micronutrients (SynFlex^® and Glutamin CoMo^®).

Before sowing, herbicide (Shadow^®) was applied to minimize weed incidence. Sowing was performed on November 20th, 2019, at a 6 km h^-1 speed, 4 cm depth and 45 cm spacing between lines. Base fertilization was carried out with 270 kg ha^-1 of a 2-23-23 (N-P₂O₅-K₂O) commercial formula in the sowing lines, and 20 days after seedling emergence, 120 kg ha^-1 KCl (60% K₂O) were applied manually. Sowing plots measured 3.15 m × 20 m, and each plot had seven sowing lines. In order to quantify the final population of emerged plants (Table 1), 20 days after sowing, the number of plants was accounted six times within 10 m in the two central lines of the plot.

Thumbnail

Table 1:
Final population of plants in relation to the sown density

Three insecticide and fungicide applications were performed, the first being on January 14th, 2020 (Elatus^®, Cypress^® 400 EC, Premio^® and Agrex’Oil^®) when plants were at the R1 stage (beginning of flowering - 50% of plants with one flower). The second application was on February 2nd, 2020 (Nomolt^® 150, Batent^®, Fox^®, Engeo Pleno™ S, Cuprozin Ultra^® and Agrex’Oil^®) when plants were at the R4 stage (most pods in the upper third with 2 to 4 cm in length), and the third one, on February 22nd, 2020 (Cronnos^®, Engeo Pleno™ S, Premio^® and Agrex’Oil^®) when plants were at the R5.3 stage (most pods between 25 and 50% graination). All products were used following dosage recommendations for soybean crop.

Plots were manually harvested on March 21st, 2020, when plants were at the R8 stage, only from 1 m of the central line of each plot. Next, the following yield components were assessed: plant height (cm); insertion height of the first pod (cm); number of nodes per plant; number of pods with one, two, three and four grains; number of pods per plant; number of grains per plant; weight of a thousand grains (grams); and grain yield (bags ha^-1). For statistical analyses, the weight of a thousand grains and grain yield were corrected to 13% humidity.

For each variable, the components of variance were estimated using the following mathematical model:

Y ijk = μ + C i + P j + (CP) ij + β k + ε ijk

where Y _ijk is the mean value observed of the response variable in plot ijk, m is the overall mean, C _i is the fixed effect of level i (i = 1, 2) of the cultivar factor, P _j is the fixed effect of level j (j = 271111, 303111, 312889, 331556, 343556) of the population factor, (CP) _ij is the interaction effect of level i of the cultivar factor with level j of the population factor, β _k is the random effect of the block (k = 1, 2 and 3) and ε _ijk is the effect of the experimental error, considered normal and independently distributed with a mean of zero and a common variance σ² (Storck et al., 2016StorckLGarciaDCLopesSJStefanelV2016 Experimentação vegetal. 3ª ed. Santa Maria, UFSM. 198p). From the significance of the factors under study, means were grouped through Scott-Knott test (Scott & Knott, 1974ScottAJKnottMA1974 Cluster analysis methods for grouping means in the analysis of variance. Biometrics, 30:507-512) at 5% probability of error for cultivars and, for the population factor, a regression analysis was performed. All analyses were performed using Microsoft Office Excel and Sisvar software (Ferreira, 2011FerreiraDF2011 Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia, 35:1039-1042).

RESULTS AND DISCUSSION

Figure 1 shows the weather conditions recorded during the experimental period, where rainfall up to 430 mm was accumulated, with uneven distribution, and the mean temperature oscillated from 14.30 to 29.25 ºC, which is over soybean basal temperature (Soltani & Sinclair, 2012SoltaniASinclairTR2012 Modeling Physiology of Crop Development, Growth and Yield. Wallingford, CAB International. 322p), indicating adequate thermal conditions for the development of the crop. Also, as expected, the final number of plants per meter did not differ between cultivars and had a linear growing response between plant populations (Figure 2a).

Figure 1:
Maximum, mean and minimum air temperatures and rainfall regime corresponding to the experimental period, in Santo Augusto, RS, Brazil.

Figure 2:
Effect of soybean cultivars and plant populations on: a) number of plants per meter, in units; b) insertion height of the first pod, in centimeters; and, c) number of pods with one grain, in units per plant, in Santo Augusto, RS, Brazil, during the 2019/2020 harvest.

The insertion height of the first pod differed between cultivars, in which cultivar NS 6010 IPRO obtained the highest value (23.30 cm), and also between populations, in which higher populations promoted higher heights (Figure 2b). Similarly, some authors (Mauad et al., 2010MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181; Cruz et al., 2016CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06; Ribeiro et al., 2017RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08) have observed increases in the insertion height of the first pod as sowing density was elevated. An explanation for this is high sowing density may harm sunlight uptake, resulting in plant etiolation (Mauad et al., 2010MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181; Cruz et al., 2016CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06). This characteristic is extremely important since great increases in the insertion height of the first pod may be disadvantageous, once this leads to the formation of plants with low stem exploration, decreasing the productive potential of the crop (Ribeiro et al., 2017RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08). However, if too low, there might be great harvest losses as well, considering the height of the harvester cutting bar (Mauad et al., 2010; Cruz et al., 2016).

As the majority of pods from both cultivars had three grains, the number of pods with one and four grains was low in all conditions tested, in which there was no effect of any source of variation (Table 2) and no model adjusted to the testing populations (Figures 2c and 3c). Nevertheless, the occurrence of pods with two and three grains differed only between cultivars, with higher means obtained for cultivar NS 5700 IPRO, of 10.39 and 38.95, respectively (Table 2). Accordingly, this cultivar also presented a higher number of pods and number of grains per plant. However, although no significant differences were observed between populations for those variables through the analysis of variance, linear decreasing models were significant, suggesting population increase tends to reduce the number of pods with two and three grains, the total number of pods per plant, and consequently, the number of grains per plant (Figures 3a and b).

Thumbnail

Table 2:
Abstract of the analysis of variance with the sources of variation (SV), degrees of freedom (DF) and the mean squares of the analysis of variance with the respective significance, coefficient of experimental variation (CV, in %) and the means of the variables evaluated for two soybean cultivars and five sowing populations during the 2019/2020 harvest in Santo Augusto, RS, Brazil

Figure 3:
Effect of soybean cultivars and plant populations on: a) number of pods with two grains; b) number of pods with three grains; and, c) number of pods with four grains, in units per plant, in Santo Augusto, RS, Brazil, during the 2019/2020 harvest.

Also, the number of nodes on the main stem differed between cultivars and populations (Table 2), in which cultivar NS 5700 IPRO presented a higher mean (18,35) and, in general, population increase reduced the number of nodes (Figure 4b). Possibly, these results reflect the increase in inter and intraspecific competition for soil resources, such as water and nutrients, caused by high sowing densities, which reduced the number of ramifications where reproductive gems develop, hence reducing the number of pods per plant, and therefore, the number of grains (Mauad et al., 2010MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181; Ramos Junior et al., 2019Ramos JuniorEURamosEMBulhõesCC2019 Densidade de plantas nos componentes produtivos e produtividade de cultivares de soja. Revista de Ciências Agroambientais, 17:51-56). Another issue that should be taken into account is that population density increase can result in alterations in the microclimate inside the canopy (Masino et al., 2018MasinoARugeroniPBorrásLRotundoJ2018 Spatial and temporal plant-to-plant variability effects on soybean yield. European Journal of Agronomy, 98:14-24), which might increase the incidence of pests and diseases (Farias et al., 2019FariasMCasaRTGavaFFiorentinOAGonçalvesMJMartinsFC2019 Effect of soybean plant density on stem blight incidence. Summa Phytopathologica, 45:247-251). This could also affect yield components, especially considering the elevated accumulated rainfall amount observed on some days during the cycle (Figure 1).

Figure 4:
Effect of soybean cultivars and plant populations on: a) plant height, in centimeters; b) number of nodes on the main rod, in units; and, c) number of pods per plant, in units, in Santo Augusto, RS, Brazil, during the 2019/2020 harvest in Santo Augusto - RS.

On the other hand, the weight of a thousand grains was higher for cultivar NS 6010 IPRO and was not significantly influenced by plant population (Table 2 and Figure 5b). Such a result represents intrinsic genetic characteristics of the cultivar, such as its higher resistance to hydric stress, compared with cultivar NS 5700 IPRO. Also, another characteristic that should be considered is the maturity group (MG) of both cultivars, since cultivar NS 5700 IPRO has an MG of 5.7, whereas the MG of cultivar NS 6010 IPRO is 6.0. Thus, cultivars with longer cycles, such as NS 6010 IPRO, in this case, tend to accumulate a higher amount of photoassimilates in the grain, resulting in a higher grain weight as observed by Silva (2016SilvaCM2016 Época de semeadura versus grupo de maturação nos componentes de rendimento da soja em microclima do cerrado piauiense. Master Dissertation. Universidade Federal do Piauí, Bom Jesus. 52p).

Figure 5:
Effect of soybean cultivars and populations on: a) number of grains per plant, in units; b) mass of a thousand grains, in grams; and c) grain yield, in bags per hectare, in Santo Augusto, RS, Brazil, during the 2019/2020 harvest in Santo Augusto - RS.

As for plant height, cultivar NS 6010 IPRO produced the highest plants, with mean values of 101.28 cm (Table 2). However, plant population did not interfere with this characteristic (Figure 4a). Similar results were obtained by Procópio et al. (2013ProcópioSOBalbinot JuniorAADebiasiHFranchiniJCPanisonF2013 Plantio cruzado na cultura da soja utilizando uma cultivar de hábito de crescimento indeterminado. Revista de Ciências Agrárias, 56:319-325), Balbinot Junior et al. (2016Balbinot JuniorAAProcópioSONeumaierNFerreiraASWernerFDebiasiHFranchiniJC2016 Semeadura cruzada, espaçamento entre fileiras e densidade de semeadura influenciando o crescimento e a produtividade de duas cultivares de soja. Revista de Ciências Agroveterinárias, 15:83-93) and Ribeiro et al. (2017RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08), where plant height was not influenced by variations in sowing densities. As highlighted by these authors, this may be a consequence of soybean’s high phenotypic plasticity, which, as previously mentioned, attributes to plants a high capacity of changing their morphology and, also, grain yield according to plant density, promoting the maintenance of grain yield in high plant populations (De Luca et al., 2014De LucaMJNogueiraMAHungriaM2014 Feasibility of lowering soybean planting density without compromising nitrogen fixation and yield. Agronomy Journal, 106:2118-2124; Lopes & Lima, 2015LopesNFLimaMGS2015 Fisiologia da Produção. Viçosa, UFV. 492p; Cruz et al., 2016CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06; Ferreira et al., 2018FerreiraASBalbinot JúniorAAWernerFFranchiniJCZucareliC2018 Soybean agronomic performance in response to seeding rate and phosphate and potassium fertilization. Revista Brasileira de Engenharia Agrícola e Ambiental, 22:151-157). In this sense, this fact may also explain why grain yield differed only between cultivars but did not variate between populations (Figure 5c), which also indicates the higher number of plants at high densities compensated for the lower production of pods and grains per plant. As for cultivars, the highest grain yield was observed for NS 5700 IPRO, since it had the highest number of pods with two and three grains, and the highest number of pods and grains per plant (Table 2).

CONCLUSION

Although cultivar NS 5700 IPRO was more productive than cultivar NS 6010 IPRO, both proved to be more productive when submitted to lower sowing densities, making densities between 271111 and 303111 plants.ha^-1 the most indicated for their cultivation in the conditions under study.

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

We thank the Federal University of Santa Maria (UFSM), the National Council for Scientific and Technological Development (CNPq), the Foundation of Research Support of the State of Rio Grande do Sul (FAPERGS), FAPERGS/CNPq (Process number 16/2551-0000257-6 ARD/PPP) and the Coordination for the Improvement of Higher Education Personnel (CAPES) (Brazil - Finance code 001) for scholarships and financial support. The authors declare that there are no conflicts of interest in carrying the research and publishing the manuscript.

REFERENCES

Balbinot JuniorAAProcópioSONeumaierNFerreiraASWernerFDebiasiHFranchiniJC2016 Semeadura cruzada, espaçamento entre fileiras e densidade de semeadura influenciando o crescimento e a produtividade de duas cultivares de soja. Revista de Ciências Agroveterinárias, 15:83-93
Conab - Companhia Nacional de Abastecimento2020 Acompanhamento da Safra Brasileira: Grãos: Décimo primeiro levantamento: Safra 2019/20. Available at: Available at: https://www.conab.gov.br Accessed on: March 14th, 2021.
» https://www.conab.gov.br
CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06
CunhaNGSilveiraRJCSeveroCRS2004 Estudo de Solos do Município de Santo Augusto - RS. Pelotas, Embrapa Clima Temperado. 64p
FariasMCasaRTGavaFFiorentinOAGonçalvesMJMartinsFC2019 Effect of soybean plant density on stem blight incidence. Summa Phytopathologica, 45:247-251
FerreiraDF2011 Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia, 35:1039-1042
FerreiraASBalbinot JúniorAAWernerFFranchiniJCZucareliC2018 Soybean agronomic performance in response to seeding rate and phosphate and potassium fertilization. Revista Brasileira de Engenharia Agrícola e Ambiental, 22:151-157
FerreiraASBalbinot JúniorAAWernerFZucareliCFranchiniJCDebiasiH2016 Plant density and mineral nitrogen fertilization influencing yield, yield components and concentration of oil and protein in soybean grains. Bragantia, 75:362-370
De LucaMJNogueiraMAHungriaM2014 Feasibility of lowering soybean planting density without compromising nitrogen fixation and yield. Agronomy Journal, 106:2118-2124
LimaSFAlvarezRCFTheodoroGFBavarescoMSilvaKS2012 Efeito da semeadura em linhas cruzadas sobre a produtividade de grãos e a severidade da ferrugem asiática da soja. Bioscience Journal, 28:954-962
LopesNFLimaMGS2015 Fisiologia da Produção. Viçosa, UFV. 492p
MasinoARugeroniPBorrásLRotundoJ2018 Spatial and temporal plant-to-plant variability effects on soybean yield. European Journal of Agronomy, 98:14-24
MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181
ProcópioSOBalbinot JuniorAADebiasiHFranchiniJCPanisonF2013 Plantio cruzado na cultura da soja utilizando uma cultivar de hábito de crescimento indeterminado. Revista de Ciências Agrárias, 56:319-325
Ramos JuniorEURamosEMBulhõesCC2019 Densidade de plantas nos componentes produtivos e produtividade de cultivares de soja. Revista de Ciências Agroambientais, 17:51-56
RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08
ScottAJKnottMA1974 Cluster analysis methods for grouping means in the analysis of variance. Biometrics, 30:507-512
SediyamaTSilvaFBorémA2015 Soja do plantio à colheita. Viçosa, UFV . 333p
SilvaCM2016 Época de semeadura versus grupo de maturação nos componentes de rendimento da soja em microclima do cerrado piauiense. Master Dissertation. Universidade Federal do Piauí, Bom Jesus. 52p
SoaresIORezendePMBruziATZuffoAMZambiazziEVFronzaVTeixeiraCM2015 Interaction between Soybean Cultivars and Seed Density. American Journal Plant Science, 06:1425-1434
SoltaniASinclairTR2012 Modeling Physiology of Crop Development, Growth and Yield. Wallingford, CAB International. 322p
StorckLGarciaDCLopesSJStefanelV2016 Experimentação vegetal. 3ª ed. Santa Maria, UFSM. 198p
WernerFBalbinot JúniorAAFerreiraASAguiar e SilvaMADebiasiHFranchiniJC2016 Soybean growth affected by seeding rate and mineral nitrogen. Revista Brasileira de Engenharia Agricola e Ambiental, 20:734-738

Publication Dates

Publication in this collection
22 July 2022
Date of issue
Jul-Aug 2022

History

Received
23 Apr 2021
Accepted
22 Nov 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Balbinot JuniorAAProcópioSONeumaierNFerreiraASWernerFDebiasiHFranchiniJC2016 Semeadura cruzada, espaçamento entre fileiras e densidade de semeadura influenciando o crescimento e a produtividade de duas cultivares de soja. Revista de Ciências Agroveterinárias, 15:83-93

[2] Conab - Companhia Nacional de Abastecimento2020 Acompanhamento da Safra Brasileira: Grãos: Décimo primeiro levantamento: Safra 2019/20. Available at: Available at: https://www.conab.gov.br Accessed on: March 14th, 2021.
» https://www.conab.gov.br

[3] CruzSCSSena JuniorDGSantosDMALunezzoLOMachadoCG2016 Cultivo de soja sob diferentes densidades de semeadura e arranjos espaciais. Revista de Agricultura Neotropical, 03:01-06

[4] CunhaNGSilveiraRJCSeveroCRS2004 Estudo de Solos do Município de Santo Augusto - RS. Pelotas, Embrapa Clima Temperado. 64p

[5] FariasMCasaRTGavaFFiorentinOAGonçalvesMJMartinsFC2019 Effect of soybean plant density on stem blight incidence. Summa Phytopathologica, 45:247-251

[6] FerreiraDF2011 Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia, 35:1039-1042

[7] FerreiraASBalbinot JúniorAAWernerFFranchiniJCZucareliC2018 Soybean agronomic performance in response to seeding rate and phosphate and potassium fertilization. Revista Brasileira de Engenharia Agrícola e Ambiental, 22:151-157

[8] FerreiraASBalbinot JúniorAAWernerFZucareliCFranchiniJCDebiasiH2016 Plant density and mineral nitrogen fertilization influencing yield, yield components and concentration of oil and protein in soybean grains. Bragantia, 75:362-370

[9] De LucaMJNogueiraMAHungriaM2014 Feasibility of lowering soybean planting density without compromising nitrogen fixation and yield. Agronomy Journal, 106:2118-2124

[10] LimaSFAlvarezRCFTheodoroGFBavarescoMSilvaKS2012 Efeito da semeadura em linhas cruzadas sobre a produtividade de grãos e a severidade da ferrugem asiática da soja. Bioscience Journal, 28:954-962

[11] LopesNFLimaMGS2015 Fisiologia da Produção. Viçosa, UFV. 492p

[12] MasinoARugeroniPBorrásLRotundoJ2018 Spatial and temporal plant-to-plant variability effects on soybean yield. European Journal of Agronomy, 98:14-24

[13] MauadMSilvaTLBAlmeida NetoAIAbreuVG2010 Influência da densidade de semeadura sobre características agronômicas na cultura da soja. Revista Agrarian, 03:175-181

[14] ProcópioSOBalbinot JuniorAADebiasiHFranchiniJCPanisonF2013 Plantio cruzado na cultura da soja utilizando uma cultivar de hábito de crescimento indeterminado. Revista de Ciências Agrárias, 56:319-325

[15] Ramos JuniorEURamosEMBulhõesCC2019 Densidade de plantas nos componentes produtivos e produtividade de cultivares de soja. Revista de Ciências Agroambientais, 17:51-56

[16] RibeiroABMBruziATZuffoAMZambiazziEVSoaresIOVilelaNJDPereiraJLARMoreiraSG2017 Productive performance of soybean cultivars grown in different plant densities. Ciência Rural, 47:01-08

[17] ScottAJKnottMA1974 Cluster analysis methods for grouping means in the analysis of variance. Biometrics, 30:507-512

[18] SediyamaTSilvaFBorémA2015 Soja do plantio à colheita. Viçosa, UFV . 333p

[19] SilvaCM2016 Época de semeadura versus grupo de maturação nos componentes de rendimento da soja em microclima do cerrado piauiense. Master Dissertation. Universidade Federal do Piauí, Bom Jesus. 52p

[20] SoaresIORezendePMBruziATZuffoAMZambiazziEVFronzaVTeixeiraCM2015 Interaction between Soybean Cultivars and Seed Density. American Journal Plant Science, 06:1425-1434

[21] SoltaniASinclairTR2012 Modeling Physiology of Crop Development, Growth and Yield. Wallingford, CAB International. 322p

[22] StorckLGarciaDCLopesSJStefanelV2016 Experimentação vegetal. 3ª ed. Santa Maria, UFSM. 198p

[23] WernerFBalbinot JúniorAAFerreiraASAguiar e SilvaMADebiasiHFranchiniJC2016 Soybean growth affected by seeding rate and mineral nitrogen. Revista Brasileira de Engenharia Agricola e Ambiental, 20:734-738

Treatment	Cultivar	Sown density (20/11/2019)		Final Population (10/12/2019)
Treatment	Cultivar	Plants m^-1	Plants ha^-1	Plants m^-1	Plants ha^-1
T1	NS 5700 IPRO	12.20	271111	10.47	232593
T2	NS 5700 IPRO	13.64	303111	10.77	239260
T3	NS 5700 IPRO	14.08	312889	11.15	247778
T4	NS 5700 IPRO	14.92	331556	12.13	269630
T5	NS 5700 IPRO	15.46	343556	12.78	284075
T6	NS 6010 IPRO	15.46	343556	12.88	286297
T7	NS 6010 IPRO	14.92	331556	12.75	283334
T8	NS 6010 IPRO	14.08	312889	12.48	277408
T9	NS 6010 IPRO	13.64	303111	11.32	251482
T10	NS 6010 IPRO	12.20	271111	10.72	238149

SV	DF	NP⁽¹⁾	IHFP	P1G	P2G	P3G	P4G
SV	DF	Mean Square
Block	2	0.23 ^ns	183.45*	0.15 ^ns	10.88 ^ns	254.95*	0.07 ^ns
Cultivar	1	1.63 ^ns	189.25*	0.02 ^ns	18.99*	1078.48*	0.04 ^ns
Population	4	4.97*	39.09*	0.04 ^ns	9.24 ^ns	92.17 ^ns	0.03 ^ns
Interaction	4	0.13 ^ns	2.82 ^ns	0.07 ^ns	2.62 ^ns	17.76 ^ns	0.05 ^ns
Error	18	0.71	7.97	0.10	3.75	41.64	0.03
CV	%	7.31	17.47	83.94	20.18	16.55	107.49
Cultivar	Population	------------------------- Mean -------------------------
NS 5700 IPRO	271111	10.33	11.10	0.52	11.03	51.13	0.23
NS 5700 IPRO	303111	10.67	12.82	0.34	12.00	45.78	0.00
NS 5700 IPRO	312889	11.00	12.66	0.30	11.48	44.09	0.06
NS 5700 IPRO	331556	12.00	17.31	0.47	8.81	42.53	0.25
NS 5700 IPRO	343556	12.67	15.39	0.13	8.08	38.95	0.05
Mean NS 5700 IPRO		11.33a	13.65b	0.36a	10.39a	44.99a	0.12a
NS 6010 IPRO	271111	10.67	16.28	0.41	9.72	37.63	0.16
NS 6010 IPRO	303111	11.33	18.47	0.53	10.00	33.50	0.12
NS 6010 IPRO	312889	11.67	16.59	0.37	8.09	33.86	0.40
NS 6010 IPRO	331556	12.67	23.30	0.32	7.87	28.11	0.16
NS 6010 IPRO	343556	12.67	18.47	0.42	8.32	32.08	0.18
Mean NS 6010 IPRO		11.80a	18.68a	0.41a	8.80b	33.00b	0.20a
Overall Mean		11.57	16.17	0.38	9.59	38.99	0.16
SV	DF	PH	NN	PP	GP	MTG	GY
SV	DF	Mean Square
Block	2	284.26*	8.13*	371.67*	2136.91*	523.90 ^ns	116.45 ^ns
Cultivar	1	661.81*	5.41*	1344.62*	8632.57*	1865.19*	670.85*
Population	4	8.22 ^ns	4.59*	156.75 ^ns	841.03 ^ns	365.28 ^ns	46.02 ^ns
Interaction	4	2.27 ^ns	0.44 ^ns	26.49 ^ns	164.66 ^ns	287.36 ^ns	15.65 ^ns
Error	18	21.97	0.94	69.24	496.73	293.33	115.99
CV	%	4.85	5.41	16.92	18.38	11.58	14.42
Cultivar	Population	------------------------- Mean -------------------------
NS 5700 IPRO	271111	94.41	18.97	62.90	152.19	142.75	82.98
NS 5700 IPRO	303111	90.36	18.66	58.13	141.91	143.69	80.43
NS 5700 IPRO	312889	90.91	18.82	55.94	143.33	133.59	77.84
NS 5700 IPRO	331556	92.24	17.61	52.06	129.53	136.53	77.49
NS 5700 IPRO	343556	91.98	17.26	47.21	116.71	143.49	78.30
Mean NS 5700 IPRO		91.89b	18.35a	55.86a	138.21a	140.01b	79.41a
NS 6010 IPRO	271111	101.87	18.13	48.19	117.16	156.08	71.97
NS 6010 IPRO	303111	99.73	17.91	44.15	108.74	163.10	73.99
NS 6010 IPRO	312889	101.33	18.54	42.71	107.74	137.70	63.66
NS 6010 IPRO	331556	101.33	16.08	36.45	87.97	174.21	70.82
NS 6010 IPRO	343556	101.62	16.89	41.00	100.58	147.82	69.30
Mean NS 6010 IPRO		101.28a	17.50b	42.48b	104.28b	155.78a	69.95b
Overall Mean		96.58	17.92	49.17	121.25	147.90	74.68