Boll characteristics and yield of cotton in relation to the canopy microclimate under varying plant densities in an arid area

Experimental site

The 2-year field experiment was conducted in 2019 to 2020 at the experimental station of the Institute of Cotton Research of the Chinese Academy of Agricultural Sciences in Alaer, Xinjiang (40°60′N, 81°31′E, altitude 1100 m.a.s.l.). The mean annual air temperature at the experimental site ranges from 8.4 °C to 11.4 °C, and the annual accumulated temperature of ≥ 10 °C ranges from 3450 °C to 4432 °C (Li, 2016, Jabran & Chauhan, 2020). The frost-free period lasts 180 to 221 days, and the mean annual precipitation is 48 mm. The monthly precipitation and mean temperature during the 2019 and 2020 cotton growing seasons are shown in Table 1. The soil is sandy loam, and the soil nutrient concentrations at a depth of 20 cm prior to sowing are listed in Table 2.

Experimental design and field management

The experiment was established using a randomized complete block design with three replicates of each planting density of 9 (P1), 12 (P2), 15 (P3), 18 (P4), 21 (P5), and 24 (P6) plants m⁻². The plant distances for the six densities were 29.2, 21.9, 17.5, 14.6, 12.5, and 10.9 cm, respectively. The crop row orientation was north–south. Row spacing was wide+narrow i.e., 66 cm+10 cm, and the rows were covered with a 2.05 m wide transparent plastic film. Each plot was 47.9 m² (7 × 6.84 m). The edges of the film were buried in the soil, leaving a 0.23 m wide bare soil between each sheet. The planting pattern, drip irrigation layout and film cover are illustrated in Fig. 1.

The cultivar used in the experiment was hybrid cotton variety CRI88 with a growth duration of approximately 136 days. Cotton was sown on 18 April 2019 and 21 April 2020 using the manual hill-drop method after covering the rows with plastic film. Seedlings were manually thinned at the two-leaf stage to obtain the desired planting densities. The buds of the main stem were topped on 17 July 2019 and 13 July 2020. The cotton was harvested on 15 October 2019 and 03 October 2020. Before sowing, fertilizer was applied at 4.8 t ha⁻¹ organic fertilizer, 225 kg ha⁻¹ urea (46.4% N), and 300 kg ha⁻¹ primary calcium phosphate (46% P₂O₅). Fertilizer consisting of 150 kg ha⁻¹ urea, 270 kg ha⁻¹ diammonium phosphate (18% N, 46% P₂O₅), and 112.5 kg ha⁻¹ potassium dihydrogen phosphate (52% P₂O₅, 34% K₂O) was applied as a top dressing with each irrigation. The plots were irrigated nine times over the growing period with a total of 4200 m³ ha⁻¹. Other management actions followed the local farming practices.

Data collection

Fraction of light intercepted within the canopy

Fraction of light intercepted (FLI) within the canopy was evaluated from the budding to boll opening stage in 2019 and 2020. Incident photosynthetically active radiation (PAR₀) and transmitted photosynthetically active radiation (PARc) were measured using a LI-191SA light quantum sensor and a LI-1400 data logger (LI-COR, Lincoln, NE, USA). The canopy was divided into 0.2 m ×0.2 m vertical and horizontal grids. The quantum sensor was placed perpendicular to the rows, and three replicate photosynthetically active radiation measurements were taken in each plot. The intercepted light rate (Ir) of each sensor was computed using Eq. (1). FLI was computed according to the Simpson 3/8 integration rule (Xue et al., 2017a), using Eqs. (2) and (3), where A_i isthe amount of light in a certain cross-sectional area, the coefficient vector is {1,3,3,2,3,3,2, …,3,3,2,1}, Δx is the vertical interval of the grid, Δy is the horizontal interval, i and j are grid node numbers, and G_(i,j) represents kriging interpolation points, FLI is the total light interception rate in the certain area of the canoy. The canopy was divided into lower, middle, and upper layers as shown in Fig. 2. (1)${\displaystyle {Ir=1-PARc/PAR}_0}$ (2)${\displaystyle Ai=\frac{3\Delta x}{8}\left[G_{i,1}+3G_{i,2}+3G_{i,3}+2G_{i,4}+...+2{G_{i,ncol}}_{-1}+G_{i,ncol}\right]}$ (3)${\displaystyle FLI\approx \frac{3\Delta y}{8}\left[A_1+3A_2+3A_3+2A_4+...+2{A_{ncol}}_{-1}+A_{ncol}\right]}$

Data analyses

SPSS 25.0 software (SPSS Inc., Chicago, IL, USA) was used to run non-linear regression and ANOVA. The least significant difference (LSD) test at the 0.05 level was used to compare the mean of different treatments. Graphics were created using origin 2018 graphics software (Origin LabInc., Northampton, MASS, USA).

FLI within the canopy

FLI within the canopy increased with the planting density, but decreased with the increase in canopy height (Fig. 3). Over the entire growth period, the maximum FLI in the upper layer was observed in the P5 (0.66) in the full-boll period in 2019 and in the P6 (0.35) in the full blooming period in 2020. P5 produced the highest 2-year average FLI in the middle (0.85) and lower layers (0.97) in the full-blooming period. Compared with the peak value in each treatment, FLI was reduced by 0.25–0.39, 0.17–0.40, and 0.07–0.30 in the upper, middle, and lower canopies, respectively, at the boll-opening period. Among the different planting densities, P1 and P2 resulted in the greatest FLI reduction in the upper layer, whereas the smallest FLI reduction was in P4 and occurred in the middle and lower layers.

Distribution of air T within the canopy

Consistent with changes in the outside air T (control [CK]), the air T within the canopy increased and then decreased over the course of the growing season in both years (Fig. 4). For all treatments, T was higher than CK in the upper canopy layer. The higher the planting density, the lower the T within the canopy. Increasing the planting density not only advanced the time when the cooling effect appeared but also increased the cooling rate. At the middle canopy layer, the T of P6 at the full-blooming stage was 0.31 °C lower than CK, while that for P5 was 0.16 °C lower than CK at the full-boll stage. In the lower layer, Ts of P4, P5, and P6 at the full-blooming stage were 1.68, 1.64, and 2.11 °C lower than CK, respectively, while T at P3 was 0.87 °C lower than CK at the full-boll stage.

T was higher in the upper canopy layer than in the middle and lower layers, but the depression in T was greater between the upper and middle layers than that between the middle and lower layers. Over the 2 years, the T in the middle canopy layer in the P1–P6 treatments was 4.21, 4.11, 3.19, 3.06, 2.72, and 2.49 °C lower than that in the upper layer, respectively, but 1.29, 1.15, 1.62, 1.49, 1.32, and 1.23 °C higher than that in the lower layer.

Distribution of RH within the canopy

Across canopy layers, RH was highest during the full-boll period (Fig. 5). The peak RH in the upper, middle, and lower layers was 51.66, 63.88, and 70.57% in 2019, respectively, and 52.83, 64.69, and 71.84% in 2020. At boll opening, the respective RH values decreased by 33.85, 36.10, and 37.92% in 2019, and 33.31, 39.65, and 41.84% in 2020 when compared to peak values.

Contrary to the variation in T within the canopy, RH throughout the canopy increased with planting density. In the upper layer, the canopy RH was higher than CK in the P5 and P6 plots, whereas it was lower than CK in the P1 plot depending on the growth period. In the middle and lower layers, the canopy RH of all treatments was higher than CK. As the planting density increased, the amplitude of RH variation between the middle and upper layers decreased. The 2-year average RH depression over the entire growth period was 10.16, 10.22, 9.39, 9.02, 8.14, and 8.45% for plots P1 to P6, respectively. The amplitude of RH variation between the middle and lower layers showed no particular trend.

Boll density, single boll weight, and boll setting rate at different FB positions

Increasing the density reduced the number of bolls at different FB positions (Table 3). With each 3-plants m⁻² increment, the mean boll number per plant (BNF) at FB_≥7, FB₄₋₆, and FB₁₋₃ decreased by 0.83, 0.33, and 0.5 in 2019 and 0.86, 0.55, and 0.38 in 2020, respectively. BNF in plots P1 and P2 differed significantly from BNF in the P5 and P6 plots (P < 0.05) at different FB positions. At FB_≥7, the maximum boll number per area (BNA) was greatest in P4 plots in 2019 and P3 plots in 2020, and these maxima were significantly higher than those in the P5 and P6 plots (P < 0.05). At FB₄₋₆, the BNA in P4 plots was significantly higher than those in P1 and P2 plots (P < 0.05), with maxima of 63.0 bolls m⁻² in 2019 and 64.8 bolls m⁻² in 2020. At FB₁₋₃, the 2-year average BNA was highest in P5 plots (73.19 bolls m⁻²), and it was also significantly higher than the BNA in P1 and P2 plots (P < 0.05) but not significantly different from the BNA in P6 plots. Boll-setting rates (BSR) declined in the order FB₁₋₃ >FB₄₋₆ >FB_≥7. With values of 76.48% at FB₁₋₃ and 59.89% at FB₄₋₆, the 2-year average BSR in P3 plots was significantly higher than those in the other treatments (P < 0.05).

Relationships of planting density to FLI, T, and RH

Under different planting densities, FLI in the middle canopy layer and T and RH in all canopy layers showed linear relationships with planting density. The relationship between FLI in the upper and lower layers and density followed a quadratic curve pattern (Fig. 6). Regression fits are shown in Table 4. Increasing the density had no significant effect on FLI in the upper canopy layer. There was a positive linear relationship between density and FLI in the middle layer, and a significant, negatively correlated conic relationship with FLI in the lower layer. T in each canopy layer declined with increased planting density, whereas RH increased.

Correlations among canopy FLI, T, RH, BNF, BNA, BW, and BSR

As shown in Fig. 7, canopy T and RH in each layer were negatively correlated. In the upper layer, FLI was uncorrelated with T, RH, BNF, BNA, BW, and BSR. T was positively correlated with BNF, BNA, and BSR, whereas RH was negatively correlated with BNF and BSR. In the middle and lower layers, FLI was negatively correlated with T and BNF but positively correlated with RH and BNA. T was positively correlated with BNF but negatively correlated with BNA. RH was negatively correlated with BNF and positively correlated with BNA only in the lower canopy layer.

Significant interactions between the boll number, BW, and BSR were mainly found for the upper canopy layer. Among them, BSR was positively correlated with BNF, BNA, and BW, BNF was positively correlated with BNA, and BNA was positively correlated with BW.

Yield

Yield varied greatly with planting density (Fig. 8). The average 2-year yield increased by 0.28–24.33% when the planting density increased from 9 plants m⁻² (P1) to 21 plants m⁻² (P5). The highest yields were seen for P5 of 6644.52 kg ha⁻¹ in 2019 and P4 of 6517.26 kg ha⁻¹ in 2020. There was no significant difference in the yields of P4 and P5 (P > 0.05), but they were significantly higher than the yields obtained in P1, P2, P3, and P6 in both years (P < 0.05). The relationship between yield and planting density is shown in Fig. 9. The fitting curve was parabolic and opened downwards, and the fitting coefficients R² were all higher than 0.9 (P < 0.01). The curve simulation also showed that the P4 (18 plants m⁻²) treatment had the maximum yield.