Experimental sites

The experimental trials were set up at three research stations during two growing seasons (2018 and 2019). The three research stations were Koussanar, Vélingara and Kédougou (Table 1). Meteorological data were recorded at each location within 50 m of the plot by automatic weather stations (iMETOS^® IMT280 or ATMOS 41). Summaries of climatic data were reported from the PD to the end of growing season.

Table 1. Description of the 12 growing environments used in the study

KD, Kédougou; KO, Koussanar; VL, Vélingara.

^a Classification according to the USDA method based on data over the 0–30 cm horizon.

^b Rainfall = total rainfall during the trial (from planting to harvest).

^c The standard deviation of the mean is indicated in parenthesis.

The top 30 cm of the soil were sampled and analysed in the IMAGO laboratory of the Institut de Recherche pour le Développement in Dakar. In Kédougou, all soil had very low organic matter content with a maximum value of 1.45%. The soil classification according to the USDA system was silty clay loam in Kédougou, clay in Vélingara and a sandy loam in Koussanar (Table 1).

Experimental design

At each site, the field experiment was set up in a split plot with two factors (PD and cultivar) and three replicates. The two PDs were randomly assigned to the main plots using a complete block design (P1: early planting as soon as possible and P2: as soon as possible in the late planting window). The eight cultivars were then randomly assigned to sub plots within the main plots. These cultivars were chosen a priori for their wide range of response to drought (Table 2).

Table 2. Name, geographic origin and traits of cultivars used in the study

For all growing environments, each sub plot consisted of six rows (10 m each). The planting configuration was 0.80 m between the lines and 0.25 m between hills. In all growing environments except Koussanar in 2018, fertilization consisted of 250 kg/ha of complex granular fertilizer (NPKSB 14-23-14-5-1 in 2018 and NPKSBCaO 14-18-18-5-1-2.5 in 2019) and 100 kg/ha of urea at 46% N. In Koussanar in 2018, the complex fertilizer was supplied at 200 kg/ha and the urea at 50 kg/ha_. In every site, complex fertilizer was applied at thinning and urea between 40 and 45 days after planting. The pesticides were used according to a single calendar (based on PD) to have the same application dates (in days after planting) and application rates. Air-dried SCY from each plot was measured on the three central lines and converted into kg/ha for statistical analysis.

Data analysis

A mixed model (Eqn 1) was adjusted using residual maximum likelihood (REML) to the square root of the SCY to ensure homoscedasticity of the residuals, because this was not obtained with the untransformed yield. The effects of genotype, PDs, and their interaction were considered as fixed, and the environment, block and main plot effects with their interactions were considered as random. The mixed model is:

(1)\begin{align} {Y_{ijkl} = \mu + g_i + p_j + ( gp) _{ij} + E_k + B( E) _{lk} + ( gE) _{ik} + ( pE) _{\,jk} \\ \quad \quad \quad + M( pE) _{\,jkl} + \varepsilon _{ijkl}}\end{align}

where Y _ijkl is the measured square root of SCY of the ith genotype for the jth PD in the kth environment [location × year] and the lth block;

• μ is the overall mean;

• g _i is the effect of the ith genotpe;

• p _j is the effect of the jth PD;

• (gp)_ij is the effect of the interaction of the ith genotype with the jth PD;

• E _k is the random effect of the kth environment;

• B(E)_lk is the random effect of lth block in the kth environment;

• (gE)_ik is the random effect of the interaction of the ith genotype with the kth environment;

• (pE)_jk is the random effect of the interaction of the jth PD with the kth environment;

• M(pE)_jkl is the random effect of the main plot with the jth PD within the lth block in the kth environment (main plot effect);

• and $\varepsilon _{ijkl}$ is experimental error.

The estimation of the effects in a mixed model using REML may be badly affected by outliers, and the detection of outliers is prone to error. Robust statistical methods are designed to address this problem in the mixed model (Eqn 1) to reduce the effect of outliers. A robust method was used to estimate the parameters of the mixed model. Subsequently, cultivar SCYs for any proportion of early planting were estimated using linear estimation methods. Finally, the estimated means and the minimum significant differences using Tukey tests with 5% experiment-wise risk were computed and plotted. Only the tests for fixed and random effects were performed using a non-robust method.

The rate of late planting at the country level was based on actual data collected by SODEFITEX between 2000 and 2022. The slope of the linear model of late planting proportion as a function of the campaign year was evaluated for trend analysis.

A situation where a choice has to be made between disseminating one or two varieties in a given area, based on the early and late planting rates measured in the area was considered. Then, simulations were conducted to determine the potential production and monetary gains when changing from the current cultivar Stam 129A to one or two new cultivars. Monetary gains were computed based on the costs of 2020 from the SODEFITEX: A cost of inputs for seeds, fertilizer, herbicides, insecticides and battery for application devices of 125 820 FCFA/ha and a price of seed cotton of 300 FCFA/kg.

All statistical analyses were performed using R software version 4.3.1 (2023-06-16) with the packages lmerTest (Kuznetsova et al., Reference Kuznetsova, Brockhoff and Christensen2017) and robustlmm (Koller, Reference Koller2016) for mixed modelling with REML and robust estimation methods, respectively. The packages stringr and plyr (Wickham, Reference Wickham2011) were used for data manipulation, and the package ggplot2 (Wickham, Reference Wickham2016) was used for graphical representation of the results. The R script used for this study is provided as Supplementary material (Sup. 1).