Crops ›› 2023, Vol. 39 ›› Issue (1): 158-162.doi: 10.16035/j.issn.1001-7283.2023.01.023

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Effects of Different Doses of AFD on Growth and Yield of Cotton

Li Wenshan(), Zhang Junyao, Tang Jianghua, Xu Wenxiu(), Xu Qinghua   

  1. College of Agricultural, Xinjiang Agricultural University, Urumqi 830052, Xinjiang, China
  • Received:2021-11-03 Revised:2021-11-23 Online:2023-02-15 Published:2023-02-22

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Abstract:

Through exploring the suitable drop amount of the new plant growth regulator AFD in cotton production, the basis for light and simplified cultivation of cotton was provided. The field experiment was conducted from April to October in 2020, with five treatments of 0 (CK), 750 (A), 1050 (B), 1350 (C), 1650g/ha (D). The effects of different dosage of AFD on agronomic characteristics, dry matter weight, yield and fiber quality of cotton were analyzed. The results showed that the plant height and stem diameter of cotton were not significantly affected by different dosage of AFD, but the growth of leaf and fruit branch length were promoted. The number of fruit branches, effective boll number, dry weight per plant and organ (stem, leaf and boll) of cotton showed an increasing trend with the increase of AFD application amount, and the following changes were observed D > C > B > A > CK treatment. Compared with CK treatment, boll number per plant and boll weight per plant were significantly increased, and seed cotton yield was increased. D treatment had the highest yield, was 5269.70kg/ha, which was 12.45%, 11.57%, 7.68% and 1.82% higher than CK, A, B and C treatments, respectively. The treatment level of AFD had positive correlation with the uniformity of cotton plant, breaking strength and fiber length, and the D treatment was the highest, but it inhibited the short fiber percentage and Micronaire value. In conclusion, 1650g/ha was the best application rate of AFD in cotton cultivation.

Key words: Drip-application, AFD, Cotton, Dry matter accumulation, Yield

Table 1

Agronomic characteristics of cotton with different drops"

处理
Treatment		 株高Plant height (cm) 茎粗Stem diameter (mm) 叶枝长
Leaf branch
length (cm)		 果枝长
Fruit branch
length (cm)		 果枝数
Number of
branches
打顶前
Before multi-topping		 打顶后
After multi-topping		 打顶前
Before multi-topping		 打顶后
After multi-topping
CK 78.17a 78.50a 1.09a 1.13a 33.27c 29.50b 6.67b
A 76.80a 78.44a 1.11a 1.15a 33.90c 30.27b 7.33ab
B 76.88a 77.33a 1.11a 1.17a 33.50c 30.83b 8.00ab
C 79.57a 79.30a 1.12a 1.17a 36.90b 31.03b 8.33a
D 76.60a 77.78a 1.15a 1.18a 40.33a 33.37a 8.67a

Fig.1

Changes of number of bolls under different treatments"

Table 2

Dry matter weight of each organ and individual plant of cotton under different treatments g"

处理
Treatment
Boll
Stem
Leaf		 单株总重
Total weight per plant
CK 61.86e 21.91d 14.49c 98.26e
A 71.57d 24.57cd 17.67d 113.81d
B 76.76c 27.37bc 23.22b 127.34c
C 88.27b 28.27ab 21.23c 137.77b
D 98.26a 31.18a 26.70a 156.14a

Table 3

Cotton yield and its components under different treatments"

处理
Treatment		 株数(万株/hm2
Plant numbers (×104/hm2)		 籽棉产量
Seed cotton yield (kg/hm2)		 单株铃数
Number of bolls per plant		 单铃重
Weight per boll (g)
CK 14.62a 4686.20c 8.50c 4.19b
A 14.21a 4723.05b 8.33c 4.34b
B 14.90a 4894.00b 9.25bc 4.75a
C 14.98a 5175.60a 9.83b 4.88a
D 14.46a 5269.70a 10.83a 4.96a

Table 4

Cotton quality under different treatments"

处理
Treatment		 整齐度指数
Uniformity index (%)		 断裂比强度
Specific strength (CN/tex)		 短纤维指数
Short fiber index (%)		 马克隆值
Micronaire value		 纤维长度
Fiber length (mm)
CK 83.01b 28.93b 8.07a 4.97a 28.94b
A 84.30b 29.27b 5.93cd 4.63ab 29.20b
B 83.47b 29.20b 6.70bc 4.60ab 30.06ab
C 84.40b 29.47ab 7.30ab 4.63ab 29.80ab
D 85.77a 30.47a 5.10d 4.50b 31.01a
[1] 郭艳芹, 王茹茹, 常欢欢. 基于区域竞争力视角的中国棉花产区产业竞争力研究. 棉花科学, 2021, 43(4):32-40.
[2] 周春江, 田晓莉, 李松林, 等. 缓释缩节胺包衣处理对棉花农艺及经济性状的调控效果. 中国棉花, 2004(9):14-16.
[3] 夏芝, 王华, 吴翠翠, 等. 棉花化控技术在生产应用中常见误区及正确调控措施. 现代农村科技, 2019(12):27-28.
[4] 李健, 宋美珍, 贵会平, 等. 棉花化学调控技术研究进展. 中国棉花, 2016, 43(7):1-5.
[5] 李雪, 朱昌华, 夏凯, 等. 辛酸甲酯、癸酸甲酯和6-BA对棉花去顶的影响. 棉花学报, 2009, 21(1):70-72.
[6] 李宗霆, 周燮著. 植物激素及其免疫检测技术. 南京: 江苏科学技术出版社, 1996.
[7] 崔明晖, 任爱民, 马卫军, 等. 冀南植棉区杂交棉花铃期喷施艾氟迪对其农艺性状的影响. 棉花科学, 2018, 40(4):15-17.
[8] 崔爱花, 夏绍南, 张丽娟, 等. 喷施艾氟迪对鄱阳湖棉区棉花生育性状的影响. 江西农业学报, 2014, 26(11):93-95.
[9] 刘帅, 董合林, 李亚兵. 艾氟迪和缩节胺不同处理对黄河流域棉花产量的影响. 中国棉花, 2018, 45(2):19-23,27.
[10] 李梅珍. 新型调控剂艾氟迪棉田施用试验. 农村科技, 2014(1):37-38.
[11] 张巨松, 陈冰, 周抑强, 等. DPC对棉花群体发育调控效应的研究. 新疆农业大学学报, 1999(1):21-25.
[12] 宋妮, 崔文军, 孙景生. 喷施艾氟迪与缩节胺对棉花生育性状的影响. 棉花科学, 2012, 34(3):15-18.
[13] 戴宝生, 范媛媛, 李蔚, 等. 艾氟迪(AFD)在棉花上的应用效果. 棉花科学, 2011, 33(6):53-54.
[14] 赵文超, 杜明伟, 黎芳, 等. 应用缩节安(DPC)调控棉花株型的定位定量效应研究. 作物学报, 2019, 45(7):1059-1069.
doi: 10.3724/SP.J.1006.2019.84162
[15] 张特, 赵强, 李广维. 缩节胺对棉花生长发育影响研究进展. 江苏农业科学, 2021, 49(18):14-18.
[16] 张特, 王蜜蜂, 赵强. 滴施缩节胺与氮肥对棉花生长发育及产量的影响. 作物学报, 2022, 48(2):396-409.
doi: 10.3724/SP.J.1006.2022.14026
[17] 刘帅, 吴洁, 李亚兵, 等. 不同艾氟迪(AFD)处理对棉花产量形成和纤维品质的影响. 棉花学报, 2018, 30(4):344-352.
[18] Coyle G G, Smith C W. Combining ability for within-boll yield components in cotton,Gossypium hirsutum L. Crop Science, 1997, 37(4):1118-1122.
doi: 10.2135/cropsci1997.0011183X003700040014x
[19] 陈超, 潘学标, 张立祯, 等. 种植密度对棉花产量构成、成铃和棉铃性状分布的影响. 中国棉花, 2012, 39(1):16-21.
[20] 王汉霞, 华含白, 李召虎, 等. 供钾水平对棉花产量构成及其与产量相关性的影响. 棉花学报, 2011, 23(6):581-586.
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