Optimum plot size for experiments with the sunflower<sup>1</sup>

Sousa, Roberto Pequeno de; Silva, Paulo Sérgio Lima e; Assis, Janilson Pinheiro de; Silva, Paulo Igor Barbosa e; Silva, Júlio César do Vale

doi:10.1590/S1806-66902015000100020

Abstracts

The aim of this study was to determine a suitable plot size for field experiments with the sunflower. An experiment was carried out in a randomised complete block design with 14 sunflower cultivars and 10 replications. The plots consisted of four rows, six metres in length, spaced 0.7 m apart with 0.3 m between plants. The working area of the plot (7.56 m²), consisting of the two central rows, was divided into 12 basic units, each consisting of three plants per row (0.63 m²), from where the yield of the sunflower seeds was obtained. Suitable plot size was estimated using the intraclass correlation coefficient method. The detectable difference between treatments was also estimated (d). The optimum plot size for the evaluation of grain yield in the sunflower was 2.52 m²(working area), considering a boundary of one row on each side. Greater gains in experimental precision (16%) with increases in plot size, occurred up to eight basic units (5.04 m²) using seven replications. Increasing the number of replications and the plot size was more efficient in increasing experimental precision, than increasing the number of cultivars.

Helianthus annuus L.; Intraclass correlation coefficient; Breeding

O objetivo desse trabalho foi determinar o tamanho adequado de parcela para experimentação de campo com girassol. Foi realizado um experimento no delineamento em blocos completos casualizados com 14 cultivares de girassol e 10 repetições. As parcelas foram constituídas de quatro fileiras de seis metros de comprimento, espaçadas de 0,7 m e entre plantas de 0,3 m. A área útil da parcela (7,56 m²), composta das duas fileiras centrais, foi dividida em 12 unidades básicas, cada uma constituída de três plantas na fileira (0,63 m²), onde a produção de grãos do girassol foi obtida. O tamanho adequado da parcela experimental foi estimado através do método do coeficiente de correlação intraclasse. Estimou-se também a diferença detectável entre tratamentos (d). O tamanho ótimo de parcela para avaliação do rendimento de grãos de girassol foi de 2,52 m² (área útil), considerando bordadura de uma linha nas laterais. Maiores ganhos em precisão experimental (16%), com incrementos no tamanho da parcela, ocorreram até oito unidades básicas (5,04 m²), utilizando-se sete repetições. O aumento do número de repetições e do tamanho da parcela foram mais eficientes para aumentar a precisão experimental, que o incremento no número de cultivares.

Helianthus annuus L; Coeficiente de correlação intraclasse; Melhoramento genético

INTRODUCTION

Among oilseeds, the sunflower (Helianthus annuus L.) is the crop with the fastest growth rate in the world (SMIDERLE, 2010SMIDERLE, J. O. Efeito residual de doses de calcário na produtividade, teor e acidez de óleo do girassol produzido em cerrado de Roraima. Comunicado Técnico, n. 57, 2010. 5 p.). The demand for sunflower cultivars with better adaptation has given direction to the breeding program of Embrapa Tabuleiros Costeiros, which has sought to evaluate and indicate cultivars adapted to different areas of the northeast of Brazil (OLIVEIRA, 2010OLIVEIRA, I. R. et al.. Avaliação de cultivares de girassol em municípios dos Estados da Bahia, Alagoas, Sergipe e Rio Grande do Norte: ensaios realizados no ano agrícola de 2008. Comunicado Técnico, n. 105, 2010. 6 p.).

For a breeding program to be successful, it is necessary for experiments to be able to detect ever smaller variations, since the trend is for differences between new cultivars to decrease. For this reason, the challenge for breeders is to increase the precision of experiments, which would result in genetic advances and, as a consequence, materials which are more productive and of better quality (SILVA, 2009SILVA, J. R. da. Tamanho de parcela e efeito de bordadura em experimentos com meloeiro. 2009. 142 f. Tese (Doutorado em Fitotecnia) - Universidade Federal Rural do Semi-Árido, Mossoró, 2009.).

However, for conducting experiments of high precision, planning is needed, and within that context, one of the basic issues that always comes up in the experiments concerns the proper size of the plot or experimental unit (SILVA, 2009SILVA, J. R. da. Tamanho de parcela e efeito de bordadura em experimentos com meloeiro. 2009. 142 f. Tese (Doutorado em Fitotecnia) - Universidade Federal Rural do Semi-Árido, Mossoró, 2009.).

Plot size tends to increase with the progress of the breeding program, i.e. the more advanced the population, the larger the plot size needed for the experiment, because as the generations advance there is a reduction in variation between the selected materials, requiring a larger number of plants for such variations to be detected and for selections to be made. From the point where increasing the size of the plot does not result in increased precision, additional increases in precision can be obtained through the use of a greater number of replications (CARGNELUTTI FILHO et al., 2012CARGNELUTTI FILHO, A. et al. Medidas de precisão experimental e número de repetições em ensaios de genótipo de arroz irrigado. Pesquisa Agropecuária Brasileira, v. 47, n. 3, p. 336-343, 2012.).

Several factors are involved in determining the size and shape of the plot. Among them, the heterogeneity of the soil is the most important; information about the area in which the experiments will be conducted being essential (STORCK et al., 2006)STORCK, L. et al. Experimentação vegetal. 2. ed. Santa Maria: UFSM, 2006. 198 p..

Many methods have been used to estimate the optimum plot size, either from tests of uniformity or from experiments that include the effects of treatments. Among the methods used to estimate the optimum plot size from the use of experimental data from the tests of treatments, the intraclass correlation coefficient method proposed by Pimentel Gomes (1984)PIMENTEL GOMES, F. O problema do tamanho das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 19, n. 12, p. 1507-1512, 1984. should be mentioned. This method was initially applied to tree species, but the theory also applies to annual plants, as long as they are considered as lines or unitary sub-plots instead of trees, and the number of working unitary sub-plots, which gives the minimum variance for the means of treatments, is determined from the intraclass correlation coefficient.

The literature on plot size involves many crops and different situations. However, for the sunflower few studies on experimental plot size were found.

The aim of this work was to determine the plot size for experiments with the sunflower using the method proposed by Pimentel Gomes (1984)PIMENTEL GOMES, F. O problema do tamanho das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 19, n. 12, p. 1507-1512, 1984..

Methods

The experiment was conducted from May to July of 2011 at the Rafael Fernandes Experimental Farm of the Federal Rural University of the Semi-Arid (UFERSA), 20 km from the town of Mossoró, in the state of Rio Grande do Norte (RN), Brazil (5°11' S, 37°20'W, at an altitude of 18 m).

A randomised complete block design was used, with 14 sunflower cultivars and 10 replications. The plots consisted of four rows, each six metres long, with an area of 16.8 m² (2.8 m x 6.0 m). Spacing between rows was 0.7 m, with 0.3 m between plants. The working area of a plot consisted of the two central rows, eliminating a plant at each end, giving an area of 7.56 m² (1.4 m x 5.4 m). To collect data on grain yield for the sunflower, the working area of the plot was divided into 12 basic units, each consisting of three plants in a row and an area of 0.63 m².

Based on Pimentel Gomes (1984)PIMENTEL GOMES, F. O problema do tamanho das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 19, n. 12, p. 1507-1512, 1984., the statistical model adopted was (equation1):

referring to a randomised block design with k samples (basic units) per plot, where: Y_ijk grain yield obtained in the basic unit k, from cultivar i, in block j; m = general mean; c_i = effect from cultivar i (i = 1, 2, ..., I cultivars); b_j = effect from block j (j = 1, 2, ..., J blocks); e_ij = experimental error between plots and e_ijk = experimental error between basic units in the plot (k = 1, 2, ..., K basic units per plot). From the adopted statistical model, variance analysis was carried out, considering the experimental error between plots (residual (a)) and between basic units in the plot (residual (b)) (Table 1).

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Table 1
Variance analysis with K basic units per plot, and mathematical expectations of the mean squares. Mossoró RN, UFERSA, 2013 ¹ 1 V1 = residual mean square between plots; V2 = residual mean square in the plot; O2 — variance relative to the experimental error between the basic units in the plot; p — Intraclass correlation coefficient due to the basic units in the plot

The intraclass correlation coefficient was estimated from the variance analysis (Table 1), with the residual mean squares being equal to the respective mathematical expectations, in this case giving (Equation 2):

₁ = residual mean square between plots; V₂ = residual mean square between basic units in the plot; and K = number of basic units in the plot (12 basic units).= estimate of the intraclass correlation coefficient; V

Pimentel Gomes (1984)PIMENTEL GOMES, F. O problema do tamanho das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 19, n. 12, p. 1507-1512, 1984. proposes the determination of optimum plot size from plots of K basic units, with full borders and a double row of working plants. In that case, the estimated number of working basic units (k) is: a) if expression 3: ≥ 0.50 recommended is k = 2; b) if 0 < < 0.50, the solution given by

with k a natural number, or for one of the values of k, even natural numbers nearest to the root value; c) ^, k should be the greatest possible natural number, consistent with a reasonable number of degrees of freedom for the residual (usually at least 10 g.1.).

The difference between two means of the cultivars, expressed as a percentage of the expected detected mean, was calculated using Hatheway's method (1961)HATHEWAY, E. H. Convenient plot size. Agronomy Journal, v. 53, n. 4, p. 279-280, 1961., by the formula 4:

where: t₁ is the critical value for Student's t-distribution at 5%; t₂ the tabulated value of Student's t without the probability of obtaining a significant result (80%) from P; CV₁ the coefficient of variation of the plots making up a basic unit; r the number of replications; and b the

heterogeneity coefficient of the soil obtained after linearization of Smith's equation (1938)SMITH, H. F. An empirical law describing heterogeneity in yields of agricultural crops. Journal Agricultural Science, v. 28, n. 1, p. 1-23, 1938.:

where V_X is the variance per unit area of plots of X BUs in size, V₁ is the variance of plots consisting of one BU, and X is the number of BUs that make up the plot (plot size). The values for b and CV₁ were estimated in each of the 140 plots (14 cultivars and 10 replications), using the 12 BUs of the working area of the plot.

To estimate the detectable difference (d) an experiment was considered of a randomised complete block design with 4, 8, 12 and 16 cultivars; 3, 5 and 7 replications; and plot sizes of 2, 4, 6, 8, 10 and 12 basic units.

RESULTS AND DISCUSSION

Variance analysis was performed (Table 2) to estimate the intraclass correlation coefficient (Table 3).) and then to estimate the optimum number of basic units per plot (

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Table 2
Summary of the variance analysis of grain yield in sunflower cultivars. Mossoro RN, UFERSA, 2013 ¹ 1** significant by F-test at 1% probability

From analysis of the data (Table 3), it was found that the residual mean square between plots was greater than in the plot. This means that there was more variability between plots and less variability between basic units in the plot, consequently resulting in a positive value not close to zero (0.2786) for the intraclass correlation coefficient (²). This result agrees with that of Lorentz et al. (2010)LORENTZ, L. H. et al. Plot size and experimental precision for sunflower production. Scientia Agrícola, v. 67, n. 4, p. 408-413, 2010. who conducted an experiment with the sunflower and found an optimum plot size of 2.4 m².) for the basic units in the plot. This shows that there was some correlation between the basic units in the plot, which helped in the use of reasonably small plots, in this case of 4 (four) working basic units (2.52 m

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Table 3
Optimum plot size in basic units for grain yield in the sunflower, estimated by the intraclass correlation coefficient method. Mossoró RN, UFERSA, 2013 ¹ 1 basic unit = 0,7 m x 0,9 m

An experiment conducted by Oliveira et al. (2010)OLIVEIRA, I. R. et al.. Avaliação de cultivares de girassol em municípios dos Estados da Bahia, Alagoas, Sergipe e Rio Grande do Norte: ensaios realizados no ano agrícola de 2008. Comunicado Técnico, n. 105, 2010. 6 p. to evaluate the yield of sunflower cultivars, used plots with a working area of 8.64 m². However, according to the results obtained in this study, the size for the plot could be significantly reduced without compromising the data being collected, since plot sizes with a working area of 2.52 m² proved well-suited to the evaluation of grain yield in sunflower cultivars.

According to Pimentel Gomes (1988)PIMENTEL GOMES, F. Novos aspectos do problema do tamanho ótimo das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 23, n. 1, p. 59-62, 1988., when ρ>0.15, the solutions obtained are excellent (in this experiment Silva et al . (2003)SILVA, R. L. et al. Determinação do tamanho ótimo da parcela experimental pelos métodos da máxima curvatura modificado, do coeficiente de correlação intraclasse e da análise visual em testes clonais de eucalipto. Revista Árvore, v. 27. n. 25, p. 669-676, 2003. when conducting clonal tests with eucalyptus. These same authors also attribute the possibility of inconsistent values occurring to another factor, the presence of only one coefficient (ρ), that of the plot which was actually analysed. In this case, this may result in the number of working plants in the plot being underestimated, since this estimate of ρ from which the others are inferred, may confuse the expected intraclass correlation coefficient in a design with a small number of trees and with a possible different degree of competition in relation to the plot used when calculating ρ. = 0.2786), but in the case of low positive values for ρ (ρ≤0.15), the number of working plants in a plot of optimum size can increase, i.e. become overestimated, and then the number of working rows to be used should also be studied. This information was confirmed by

To estimate the true detectable difference (d) between the cultivar means, using the formula proposed by Hatheway (1961)HATHEWAY, E. H. Convenient plot size. Agronomy Journal, v. 53, n. 4, p. 279-280, 1961., values for b (heterogeneity coefficient of the soil ) and CV (coefficient of variation of plots of one basic unit in size) were used considering all the cultivars, adopting a significance level of 5% probability, for plot sizes ranging from 2 to 12 basic units (from 1.26 to 7.56 m² respectively) and considering an experiment in a randomised complete block design of 4, 8, 12 and 16 cultivars, and 3, 5 and 7 replications.

Table 4 shows values for the estimates of d in accordance with the pre-established conditions. Analysing this table, significant decreases can be seen in the values of d (gains in experimental precision) with increases in the size of small plots, although this increase in precision is small with additional increases in the area of plots over a certain size limit, agreeing with the results obtained by various authors (BRUM et al., 2008BRUM, B. et al. Tamanho ótimo de parcela para ensaios com sorgo granífero em duas épocas de semeadura. Ciência Rural, v. 38, n. 2, p. 315-320, 2008.; DONATO et al., 2008DONATO, S. L. R. et al. Estimativas de tamanho de parcelas para avaliação de descritores fenotípicos em bananeira. Pesquisa Agropecuária Brasileira, v. 43, n. 8, p. 957-969, 2008.; HENRIQUES NETO et al., 2004HENRIQUES NETO, D. et al. Tamanho de parcelas em experimentos com trigo irrigado sob plantio direto e convencional. Pesquisa Agropecuária Brasileira, v. 39, n. 6, p. 517-524, 2004.; LÚCIO et al., 2011LÚCIO, A. D. et al. Estimativa do tamanho de parcela para experimento com alface. Horticultura Brasileira, v. 29, n. 4, p. 510-515, 2011.; LÚCIO et al., 2012LÚCIO, A. D. et al. Tamanhos de amostras e de parcelas para variáveis de crescimento e produtivas de tomateiro. Horticultura Brasileira, v. 30, n. 4, p. 660-668, 2012.; MARTIN et al., 2004;MARTIN, T. N. et al. Definição de plano experimental para comparações de cultivares de milho em áreas limitadas. Revista Brasileira de Milho e Sorgo, v. 3 n. 3, p. 325-332, 2004.; SANTOS et al., 2012SANTOS, D. et al. Tamanho ótimo de parcela para a cultura do feijão-vagem. Revista Ciência Agronômica, v. 43, n. 1, p.119-128, 2012.).

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Table 4
Difference between the means for two cultivars as a percentage of the expected detected mean, in the evaluation of grain yield in the sunflower, considering different plot sizes (BU), number of cultivars and replications, estimated by Hatheway's method. Mossoró RN, UFERSA 2013 ¹ 1 BU (Basic Unit) = 0,7 m x 0,9 m; b = heterogeneity coefficient of the soil = 1,0585; CV1 = CV of plots made up of one BU = 31,57%

It was also seen that the greatest gains in experimental precision (a reduction in the values of d) with increases in plot size (Table 4) occurred up to eight basic units (5.04 m²). It is important to note that differences of around 20% (of the mean) between the means for cultivars can be detected using plots of six basic units (3.78 m²), seven replications and four or more cultivars; using plots of eight basic units (5.04 m²), five replications and four or more cultivars; or with plots of twelve basic units (7.56 m²), three replications and eight or more cultivars. Differences of around 15% can be detected with the use of plots of eight basic units (5.04 m²), seven replications and 12 or more cultivars; using plots of ten basic units (6.30 m²), seven replications and four or more cultivars; or twelve basic units (7.56 m²), five replications and eight or more cultivars. Similar results were obtained by Lorentz et al. (2010)LORENTZ, L. H. et al. Plot size and experimental precision for sunflower production. Scientia Agrícola, v. 67, n. 4, p. 408-413, 2010. who, with a sunflower crop, and using plots of 4.00 m², with five replications and four treatments, obtained a value for d of 24.51%, very close to that obtained in this work of d = 23.61%, when using plots of 3.78 m² with the same number of replications and treatments.

It is worth noting that an increase in the number of replications was more efficient in reducing the value of d (increased experimental precision), when compared to an increase in the number of cultivars (Table 4), a fact also demonstrated by Donato et al., 2008DONATO, S. L. R. et al. Estimativas de tamanho de parcelas para avaliação de descritores fenotípicos em bananeira. Pesquisa Agropecuária Brasileira, v. 43, n. 8, p. 957-969, 2008., Storck, Bisognin and Oliveira, 2006STORCK, L.; BISOGNIN, D. A.; OLIVEIRA, S. J. R. Dimensões dos ensaios e estimativas do tamanho ótimo de parcela em batata. Pesquisa Agropecuária Brasileira, v. 41, n. 6, p. 903-909, 2006. and Storck et al. 2007STORCK, L. et al. Persistência do plano experimental em ensaios de avaliação de germoplasma elite de feijão. Ciência Rural, v. 37, n. 6, p. 1549-1553, 2007..

Conclusion

The optimum plot size for evaluation of grain yield in the sunflower was 2.52 m²(working area) considering a border of one row at the sides, this being smaller than the size generally used in research with sunflower crops (8.64 m²);
Greater gains in experimental precision (16%) with increases in plot size, occurred up to 8 basic units (5.04 m²), using seven replications;
An increase in the number of replications and in plot size were more efficient in increasing experimental precision than an increase in the number of cultivars.

Parte da Tese de Doutorado do primeiro autor apresentada na Universidade Federal Rural do Semi-Árido/UFERSA, projeto financiado pela Petrobras

REFERENCES

BRUM, B. et al. Tamanho ótimo de parcela para ensaios com sorgo granífero em duas épocas de semeadura. Ciência Rural, v. 38, n. 2, p. 315-320, 2008.
CARGNELUTTI FILHO, A. et al. Medidas de precisão experimental e número de repetições em ensaios de genótipo de arroz irrigado. Pesquisa Agropecuária Brasileira, v. 47, n. 3, p. 336-343, 2012.
DONATO, S. L. R. et al. Estimativas de tamanho de parcelas para avaliação de descritores fenotípicos em bananeira. Pesquisa Agropecuária Brasileira, v. 43, n. 8, p. 957-969, 2008.
HATHEWAY, E. H. Convenient plot size. Agronomy Journal, v. 53, n. 4, p. 279-280, 1961.
HENRIQUES NETO, D. et al. Tamanho de parcelas em experimentos com trigo irrigado sob plantio direto e convencional. Pesquisa Agropecuária Brasileira, v. 39, n. 6, p. 517-524, 2004.
LORENTZ, L. H. et al. Plot size and experimental precision for sunflower production. Scientia Agrícola, v. 67, n. 4, p. 408-413, 2010.
LÚCIO, A. D. et al. Estimativa do tamanho de parcela para experimento com alface. Horticultura Brasileira, v. 29, n. 4, p. 510-515, 2011.
LÚCIO, A. D. et al. Tamanhos de amostras e de parcelas para variáveis de crescimento e produtivas de tomateiro. Horticultura Brasileira, v. 30, n. 4, p. 660-668, 2012.
MARTIN, T. N. et al. Definição de plano experimental para comparações de cultivares de milho em áreas limitadas. Revista Brasileira de Milho e Sorgo, v. 3 n. 3, p. 325-332, 2004.
OLIVEIRA, I. R. et al. Avaliação de cultivares de girassol em municípios dos Estados da Bahia, Alagoas, Sergipe e Rio Grande do Norte: ensaios realizados no ano agrícola de 2008. Comunicado Técnico, n. 105, 2010. 6 p.
PIMENTEL GOMES, F. Novos aspectos do problema do tamanho ótimo das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 23, n. 1, p. 59-62, 1988.
PIMENTEL GOMES, F. O problema do tamanho das parcelas em experimentos com plantas arbóreas. Pesquisa Agropecuária Brasileira, v. 19, n. 12, p. 1507-1512, 1984.
SANTOS, D. et al. Tamanho ótimo de parcela para a cultura do feijão-vagem. Revista Ciência Agronômica, v. 43, n. 1, p.119-128, 2012.
SILVA, J. R. da. Tamanho de parcela e efeito de bordadura em experimentos com meloeiro. 2009. 142 f. Tese (Doutorado em Fitotecnia) - Universidade Federal Rural do Semi-Árido, Mossoró, 2009.
SILVA, R. L. et al. Determinação do tamanho ótimo da parcela experimental pelos métodos da máxima curvatura modificado, do coeficiente de correlação intraclasse e da análise visual em testes clonais de eucalipto. Revista Árvore, v. 27. n. 25, p. 669-676, 2003.
SMIDERLE, J. O. Efeito residual de doses de calcário na produtividade, teor e acidez de óleo do girassol produzido em cerrado de Roraima. Comunicado Técnico, n. 57, 2010. 5 p.
SMITH, H. F. An empirical law describing heterogeneity in yields of agricultural crops. Journal Agricultural Science, v. 28, n. 1, p. 1-23, 1938.
STORCK, L.; BISOGNIN, D. A.; OLIVEIRA, S. J. R. Dimensões dos ensaios e estimativas do tamanho ótimo de parcela em batata. Pesquisa Agropecuária Brasileira, v. 41, n. 6, p. 903-909, 2006.
STORCK, L. et al. Experimentação vegetal. 2. ed. Santa Maria: UFSM, 2006. 198 p.
STORCK, L. et al. Persistência do plano experimental em ensaios de avaliação de germoplasma elite de feijão. Ciência Rural, v. 37, n. 6, p. 1549-1553, 2007.

Publication Dates

Publication in this collection
Jan-Mar 2015

History

Received
25 Nov 2013
Accepted
06 Nov 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Parte da Tese de Doutorado do primeiro autor apresentada na Universidade Federal Rural do Semi-Árido/UFERSA, projeto financiado pela Petrobras

Source of Variation	Degrees of Freedom	Mean Square (MS)	Expectation (MS)
Blocks	J-1
Cultivars	I-1
Residual (a)	(J-1)(I-1)	V₁	σ₂[1 + (K - 1)ρ]
Residual (b)	JI(K-1)	V₂	σ²(1 - ρ)

Source of Variation	Degrees of Freedom	Mean Square
Blocks	9	102,706.41**
Cultivars	13	95,150.19**
Residual (a)	117	15,291.49
Residual (b)	1540	2,713.96

Number of Cultivars
	4			8			12			16
BU	Nbr of Replications			Nbr of Replications			Nbr of Replications			Nbr of Replications
BU	3	5	7	3	5	7	3	5	7	3	5	7
Differences between Means for Two Cultivars in % of the Mean (d)
2	59.89	42.22	34.65	53.82	40.16	33.56	52.37	39.65	33.28	51.73	39.40	33.17
4	41.50	29.26	24.01	37.29	27.83	23.25	36.29	27.48	23.06	35.84	27.30	22.99
6	33.48	23.61	19.37	30.09	22.46	18.76	29.28	22.17	18.61	28.92	22.03	18.55
8	28.75	20.27	16.63	25.84	19.28	16.11	25.14	19.04	15.98	24.84	18.92	15.93
10	25.55	18.02	14.78	22.96	17.14	14.32	22.34	16.92	14.20	22.07	16.81	14.15
12	23.20	16.36	13.42	20.85	15.56	13.00	20.29	15.36	12.89	20.04	15.26	12.85

Brasil

Brasil

Optimum plot size for experiments with the sunflower¹

Tamanho ótimo da parcela para experimentação com girassol

Abstracts

INTRODUCTION

Methods

RESULTS AND DISCUSSION

Conclusion

REFERENCES

Publication Dates

History

Brasil

Brasil

Optimum plot size for experiments with the sunflower1

Tamanho ótimo da parcela para experimentação com girassol

Abstracts

INTRODUCTION

Methods

RESULTS AND DISCUSSION

Conclusion

REFERENCES

Publication Dates

History

Optimum plot size for experiments with the sunflower¹