Chemical Topping and Planting Density Interactively Affect Cotton Growth and Partitioning Index

Chemical Topping and Planting Density Interactively Affect Cotton Growth and Partitioning Index

Due to the labor shortage, replacing manual topping with chemical topping has become an important practice in cotton-producing areas such as Xinjiang, China. Similarly, increasing planting density is a common strategy to enhance cotton yields. This study aimed to quantify the interactive effects of...

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Bibliographic Details
Main Authors: Yutong Zhang, Yongfan Chen, Shuai Sun, Pengzhong Zhang, Zeshan Zhang, Xuejiao Wang, Xuelian Tang, Mingfeng Yang, Dao Xiang, Sen Wang, Fen Ji, Lizhen Zhang
Format: Article
Language:English
Published: MDPI AG 2024-12-01
Series:Agronomy
Subjects:
growth dynamics
assimilate partitioning
beta growth function
maximum dry matter
seed cotton yield
topping method
Online Access:https://www.mdpi.com/2073-4395/14/12/3011
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Summary:Due to the labor shortage, replacing manual topping with chemical topping has become an important practice in cotton-producing areas such as Xinjiang, China. Similarly, increasing planting density is a common strategy to enhance cotton yields. This study aimed to quantify the interactive effects of chemical topping and planting density on cotton growth and assimilate partitioning. To achieve this, a two-year (2020–2021) field experiment was conducted in Xinjiang, China. The main plots were assigned low (15 plants m<sup>−2</sup>) or high plant density (25 plants m<sup>−2</sup>), and the subplots were chemical topping using heavy amounts of mepiquat chloride (MC) or manual topping. The dynamics of dry matter accumulation and partitioning in cotton were well quantified using a beta-growth function with an overall nRMSE of 11.5%. Results indicated that chemical topping increased aboveground dry matter maximum by 4.88%, fruit dry matter maximum by 17.9% and seed cotton yield by 14.0% compared to manual topping. At low plant density, the partitioning index between vegetative and reproductive organs showed no significant differences. However, at high plant density, the time when 50% of assimilate partitioning to reproductive organs for chemical topping was 2.6 physiological days (under optimal temperature conditions) delayed than that for manual topping, resulting in a 2.7 physiological days delay in the time that fruits reached maximum growth rate. The results of the study suggest that applying chemicals for topping a little earlier in high-density planting could reduce the negative effects of delayed boll growth and promote carbon assimilate partitioning to fruit growth.
ISSN:2073-4395

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