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Plot size and experimental precision for sunflower production

Tamanho de parcela e precisão experimental para produção de girassol

Abstracts

In order for sunflower cultivation to be economically sustainable, research should be based upon suitable experimental techniques. Since this kind of information is not readily available, the aim of this study was to estimate the seed production heterogeneity index and the optimal experimental plot size, and to verify experimental precision in sunflower experiments. Sunflower seed yield figures for plots of 1-meter rows (0.4 m spacing) were collected. The experiments were carried out in the 2004/05 and 2005/06 growing seasons in a 1-ha area, by marking out 12 randomized blocks (12 uniformity trials) of two rows 48 plots long on land used for commercial production of sunflowers in Bossoroca, state of Rio Grande do Sul, Brazil. Plots of different sizes were simulated and estimates made for the mean, variance and coefficient of variance for each plot size, and the production heterogeneity index, optimal plot size and experimental precision estimated. The sunflower seed production heterogeneity index was high, the plots should be large and the rows are the blocks. The optimal plot size is two 3-meter rows (2.4 m²).

Helianthus annuus L; experimental techniques; number of replications; experimental design


Para sustentar a expressão econômica da cultura do girassol, a pesquisa deve dispor de técnicas experimentais adequadas. Pela falta desta informação, o trabalho tem como objetivo estimar o índice de heterogeneidade da produção de grãos, o tamanho ótimo de parcela experimental e verificar a precisão experimental em experimentos com girassol. Foi obtida a produção de grãos de girassol em parcelas de uma fila (espaçadas em 0,4 m) de 1 m de comprimento. Nas safras de 2004 e 2005, 2 blocos (12 ensaios em branco) constituídos por duas filas com 48 parcelas de comprimento foram casualizados, numa área de 1 ha com produção comercial de girassol em Bossoroca, RS. Foram planejadas parcelas de diferentes tamanhos, estimadas a média, variância e coeficiente de variação para cada tamanho de parcela, sendo estimados o índice de heterogeneidade da produção, o tamanho ótimo de parcela e a precisão experimental. O índice de heterogeneidade da produção de grãos de girassol é alto, as parcelas devem ser grandes e as filas devem ser os blocos. O tamanho ótimo de parcela é igual a duas filas de 3 m de comprimento (2,4 m²).

Helianthus annuus L; técnicas experimental; número de repetições; delineamento experimental


CROP SCIENCE

Plot size and experimental precision for sunflower production

Tamanho de parcela e precisão experimental para produção de girassol

Leandro Homrich LorentzI; Alexandra Augusti BoligonII; Lindolfo StorckII,* * Corresponding author < lindolfo@pq.cnpq.br> ; Alessandro Dal'Col LúcioII

IUNIPAMPA - Campus Itaqui, R. Luiz Joaquim de Sá Britto, s/n - 97650-000 - Itaqui, RS - Brasil

IIUFSM - Depto. de Fitotecnia, Av. Roraima, 1000 - 97105-900 - Santa Maria, RS - Brasil

ABSTRACT

In order for sunflower cultivation to be economically sustainable, research should be based upon suitable experimental techniques. Since this kind of information is not readily available, the aim of this study was to estimate the seed production heterogeneity index and the optimal experimental plot size, and to verify experimental precision in sunflower experiments. Sunflower seed yield figures for plots of 1-meter rows (0.4 m spacing) were collected. The experiments were carried out in the 2004/05 and 2005/06 growing seasons in a 1-ha area, by marking out 12 randomized blocks (12 uniformity trials) of two rows 48 plots long on land used for commercial production of sunflowers in Bossoroca, state of Rio Grande do Sul, Brazil. Plots of different sizes were simulated and estimates made for the mean, variance and coefficient of variance for each plot size, and the production heterogeneity index, optimal plot size and experimental precision estimated. The sunflower seed production heterogeneity index was high, the plots should be large and the rows are the blocks. The optimal plot size is two 3-meter rows (2.4 m2).

Key words:Helianthus annuus L., experimental techniques, number of replications, experimental design

RESUMO

Para sustentar a expressão econômica da cultura do girassol, a pesquisa deve dispor de técnicas experimentais adequadas. Pela falta desta informação, o trabalho tem como objetivo estimar o índice de heterogeneidade da produção de grãos, o tamanho ótimo de parcela experimental e verificar a precisão experimental em experimentos com girassol. Foi obtida a produção de grãos de girassol em parcelas de uma fila (espaçadas em 0,4 m) de 1 m de comprimento. Nas safras de 2004 e 2005, 2 blocos (12 ensaios em branco) constituídos por duas filas com 48 parcelas de comprimento foram casualizados, numa área de 1 ha com produção comercial de girassol em Bossoroca, RS. Foram planejadas parcelas de diferentes tamanhos, estimadas a média, variância e coeficiente de variação para cada tamanho de parcela, sendo estimados o índice de heterogeneidade da produção, o tamanho ótimo de parcela e a precisão experimental. O índice de heterogeneidade da produção de grãos de girassol é alto, as parcelas devem ser grandes e as filas devem ser os blocos. O tamanho ótimo de parcela é igual a duas filas de 3 m de comprimento (2,4 m2).

Palavras-chave:Helianthus annuus L., técnicas experimental, número de repetições, delineamento experimental

Introduction

Sunflower (Helianthus annuus L.) is one of the five most grown oil crops in the world (Fagundes, 2007). In Brazil, the most productive regions are in the Center Brazil (states of Mato Grosso - MT, Mato Grosso do Sul -MS, Goiás - GO and Brasília - DF), the Southeast (São Paulo - SP) and the South (Rio Grande do Sul - RS and Paraná - PR), and oil of excellent industrial and nutritional quality is produced (Leite et al., 2005).

Due to the importance of the crop, research has been conducted to study sunflower seed productivity as a function of nitrogen fertilization (Castro et al., 1999), weed-control (Brighenti et al., 2006), irrigation (Santos et al., 2002), agronomic and morphological characteristics and forage potential (Tomich, 2003). Stability and adaptability have also been analyzed (Porto, 2007).

There are many studies relating to sources of experimental error and the use of experimental techniques to eliminate error (Banzatto and Kronka, 1996; Gomez and Gomez, 1984; Ramalho et al., 2005; Steel et al., 1997; Storck et al., 2006a). Rossetti (2002), Viana et al. (2002), Neto et al. (2004), Lopes et al. (2005), Martin et al. (2005), Oliveira et al. (2005), Oliveira et al. (2006) and Storck et al. (2006b) described applications of methods for determining optimal experimental techniques for a variety of crops. The experimental design to be used depends on the crop, the response under study, crop management, environment and other factors, such as the actual method used to determine the best design.

For sustainable sunflower production, it is essential that suitable experimental techniques are available as a basis for conducting experimental studies aimed at increasing productivity. For sunflower, we could not find any studies regarding experimental error, plot size or the number of replications required to obtain predetermined precision. The aim of this study was, therefore, to estimate the seed production heterogeneity index and optimal plot size, and to verify the experimental precision of sunflower experiments.

Material and Methods

The study was carried out in a sunflower production area in Bossoroca, Rio Grande do Sul, (28º45' S, 54º55' W and 210 m alt.), over two consecutive growing seasons (2004/05 and 2005/06). In each crop, a 1-ha area was marked out for collecting data. Approximately 75,000 plants ha-1 (three seeds per linear meter) with row spacing of 0.4 m were drilled on a field of dissecated white oats (Quercus alba L.) during the first two weeks of August each year. Fertilizer (200 kg ha-1 of the fertilizer NPK 5-20-30 (5% N, 20% P2O5, 30% K2O) was applied on the row ten days after emergence, and 60 kg of urea was also applied 25 days after emergence. In the selected area, 12 blocks 48-m long and two rows wide were sampled (48 × 0.8 = 38.4 m2 per block). Each block, considered as a uniform section, was subdivided into 96 basic units (BU) 1 m long and 0.4 m wide. The flower heads from each BU were harvested, dried, threshed and the seeds produced weighed on precision scales (0.1 g). The number of plants in each BU was also counted.

To test the homogeneity assumption for the 12 blocks, analysis of variance was conducted based on a fully randomized design, with 12 blocks and 96 plots for each crop. To test the homogeneity assumption for the two crops, analysis of variance was also carried out based on a fully randomized design, with two treatments (crops) and 1152 plots.

Based on the values obtained from the 96 BUs in each of the 12 blocks and for the two crops, different plot sizes were simulated. The plots were X1 BUs long (tabular column) and X2 rows wide (tabular row). Plot sizes were simulated by combining adjacent BUs, such that X1*X2=X, where X is the plot size expressed as the number of BUs. The 12 plot sizes (X1*X2) simulated were: 1*1, 2*1, 3*1, 4*1, 6*1, 8*1, 1*2, 2*2, 3*2, 4*2, 6*2 and 8*2. Thus, for plots of X BUs, the number of replications is limited to N(x)=96/X. Taking Y(x)i as the total seed yield in the simulated plot consisting of X BUs, for replication i (varying from 1 to N(x)) the following statistics were calculated:M(x) = ΣiN(x) Y(x)i / N(x), average of plots with X BUs; V(x) = Σ iN(x) [Y(x)i - M(x)] / [N(x) - 1] , variance of plots with X BUs; VU(x) = V(x) / X2, calculated variance per BU between the plots of X BUs; and, VC(x) = , variation coefficient between the plots of X BUs.

For each of the 24 blocks (12 blocks × 2 crops), the heterogeneity index "b" was calculated in accordance with Smith's empirical formula VU(x)=V1/Xb for sunflower seed yield. The value of "b" was estimated as a coefficient of linear regression, using the logarithmic transform of function VU(x)=V1/Xb. The estimate of the parameters (V1 and b) was weighted by degrees of freedom (DF=N(x)-1), associated with each of the 12 simulated plot sizes, since the number of replications or DF depends on the plot size (Steel et al., 1997). In this model, VC(x) = 100 V1 is the parameter for estimating the variance among plots of one BU (0.4 m2). Similarly, using the logarithmic transform and the DF weighting, the parameters of function VC(x) = A/XB were estimated. In this model, A is the parameter for estimating the VC between the plots of one BU and B=b/2.

The estimates for the parameters of functions VU(x)=V1/Xb and VC(x)=A/XB were used to estimate optimal plot size (number of BUs) by the modified maximum curvature method (Meier and Lessman, 1971), Xo = [A2B2 (2B + 1) / (B + 2)]1/(B+2). The significant difference between treatment means, expressed as a percentage of the average (D), was estimated by the Hatheway (1961) method using the experimental precision formula D = . In this formula, r is the number f replications, Xo is the optimal plot size expressed as number of BUs; A and b are the mean estimates obtained for the functions VC(x)=A/XB and VU(x)=V1/ Xb, t1 is the tabulated value of t for significance tests (twosided at 5% significance) and t2 is the tabulated value of t corresponding to an error of 2(1-P), using p = 0.80 as the probability of obtaining significant results. The tabulated values of t-student distribution were obtained with DF degrees of freedom, considering the randomized block design, ie. DF = (I-1)(r-1). The number of treatments (I) was set at 4, 8, 12, 16 and 20 combined with 3, 4, 5 and 6 replications (r) per treatment. The values t1 and t2 are 2.131 and 0.866 respectively for a designed experiment with, for instance, four treatments (I = 4) and six replications (r = 6).

Results and Discussion

In the two growing seasons (2004 and 2005), there was variation (p < 0.01) in seed yields of different blocks and, in the second year, blocks also varied in terms of plant density (Table 1). This is important because it indicates the need to use a randomized block design in which double rows (or simply "blocks") really should be used as blocks in the experimental design. In spite of the singular fact of using long blocks and plots within a row (one after the other within the row), this type of variation can be explained for sunflowers by the distance between blocks within the larger area (one hectare) and by the fertilizer application technique (applied mechanically in each row). In this case, differences in rates between the individual rows are possible. A similar situation was found for fertilizer application to rows by Storck et al. (2006b) in a potato crop. Thus, using machines which apply non-uniform rates of fertilizer to different rows can increase experimental error if this not prevented. In addition, the fact that there was a significant variation (p < 0.01) between the two years in seed yield and plant density indicates the need to analyze seed production experiments on a collective basis since there is a higher probability of interaction between the treatment and significantly different environments (Cruz and Carneiro, 2003).

The average seed productivity of the two crops (2.15 t ha-1) is much higher than the historic average (1.5 t ha-1) for the region (CONAB, 2006), with a significantly higher yield for the 2004/05 season in comparison to the 2005/06 season (Table 1). In addition to environmental factors (excess irradiance, precipitation, etc.) affecting seed production, the correlation analysis between plant density and seed yield could explain the difference between the two years. For all the blocks and both years (Table 2), seed productivity was higher than the historic average and therefore the 24 uniformity trials (blocks) are suitable for the proposed study, taking into account the wide variety of environmental conditions within a larger experimental area. In the 2004/05 season, there was greater variation in seed production between the basic units (Table 2), reflected in the variation coefficients often higher than 40% (average = 43.6%). This variation in production and the high productivity may be related to the lower plant stand quality caused by emergence heterogeneity, resulting in higher production for some blocks in comparison to locations with higher plant density. This explanation does not apply for the following year (2005/06) when the density was higher but production was lower, due in part to excessive rainfall during flowering, leading to a higher number of unfertilized flowers.

Pearson coefficients, correlating seed production and plant density in the 12 blocks, were 0.22 and 0.84 respectively for the of 2004/05 and 2005/06 seasons. These data indicate that the relationship between plant density and production is significant at high densities. Considering that the key variable in the experiments was seed production, and that this may be related to plant density, one way of reducing experimental error for seed production is to ensure uniform, suitable plant density in the experimental units; a similar conclusion was also reached for corn crops (Cargnelutti Filho et al., 2006).

The data obtained from VC(x) and VU(x) were welladjusted for functions VU(x)= V1/Xb and VC(x)=A/XB (Table 2) because, although there are variations in the estimates of V1, b, A and B, the determination coefficient was high for all the blocks in both years. There is a mathematical similarity between the two functions such that the determination coefficient is the same and B is half of b.

The lower plant density and the higher density variation within blocks in the 2004/2005 season could have resulted in higher estimated heterogeneity indexes (b) (Table 2), showing variations between 0.670 and 1.672 (average = 1.065). In the 2005/2006 season, the index varied from 0.271 to 1.100 (average = 0.770) and there was higher variability between blocks (higher VC). Considering that the production heterogeneity index is directly related to the soil heterogeneity index, the soil is too heterogeneous for conducting the experiments, requiring larger plots for a given level of precision. When b is lower than 0.2, experiments should be designed with a higher number of replications for smaller plots, and when b is higher than 0.7, as in this study, experiments should be designed with larger plots and fewer replications (Lin and Binns, 1986). Thus, as all the blocks in the 2004/2005 season (block 9 is extreme) and nine of the 12 blocks of the 2005/2006 season, have a b value higher than 0.7, we have to design experiments with larger plots and modify the number of replications to obtain the precision required.

There were variations in the estimated optimal plot size (X0) in relation to the blocks and between the two crops, with average figures of 6.95 and 5.34 BUs (BU = 0.4 m2) for the 2004/05 and 2005/06 crops, respectively. A difference between X0 averages of less than two BUs (0.8 m2) and the similarity of the variation coefficients (17.9% and 20.4%) for X0 values for the blocks in both years, even when differences in the plant densities and environmental conditions are taken into account, shows that the results are consistent for an average plot size of around 24 blocks. In this case, plots of six basic units (2.40 m2) are adequate for designing sunflower experiments in the evaluated region. Based on seed productivity variations among the blocks and between the crops, due to the influence of environmental factors, management techniques and plant density, we can infer that the estimated plot size (2.4 m2) is suitable for most of the environments in which the sunflower is grown. This inference is supported by the method adopted in this study, i,e., a sample of 12 blocks (12 uniformity trials), over a much larger or more representative experimental area (one hectare) and in two successive growing seasons. Variations between blocks in a given season could be compared to variations between years, and in this case the results could have much greater relevance when a randomized block design is used.

Experimental precision (D), the difference between two treatment averages, increases (D-value drops, see Table 3) as the number of treatments, the number of replications and the plot size is increased. In practice, since the values of b are high (Lin and Binns, 1986), experimental precision is increased more effectively by increasing plot size rather than the number of replications, assuming the area per treatment to be the same. For an experiment with eight treatments, for example, it is reasonable to design experiments with plots of eight BUs (3.2 m2) and four replications per treatment, for a total experimental area of 102.4 m2, which would result in a minimum significant difference of 29.71% in average seed yield.

Although the variation coefficients for the estimates of parameters V1, b, A, B were relatively different, the D-values did not differ in magnitude for the two seasons. For instance, with Xo, r and I values of 10, 3 and 12 respectively, we obtained a D-value of 30.4% for the experiment on the 2004/05 crop, whereas for the 2005/06 experiment, it was 32.2%.

Conclusion

A randomized block design ("blocks" understood to mean "rows") is suitable for evaluating sunflower seed productivity. The optimal plot size for sunflower experiments was found to be two rows (0.4 m spacing) three meters long (area 2.4 m2). Finally, for experiments designed with 2.4 m2 plots, the minimum significant difference between the two treatment means was between 24.24% and 45.62%, depending on the number of replications and treatments considered.

Received January 19, 2008

Accepted April 06, 2010

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  • Publication Dates

    • Publication in this collection
      02 Aug 2010
    • Date of issue
      Aug 2010

    History

    • Accepted
      06 Apr 2010
    • Received
      19 Jan 2008
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