One-time fertilization at first flowering improves lint yield and dry matter partitioning in late planted short-season cotton

doi:10.1016/S2095-3119(19)62623-7

Journal of Integrative Agriculture

2020, Vol. 19

Issue (2): 509-517 DOI: 10.1016/S2095-3119(19)62623-7

Special Issue: 棉花合辑Cotton

Crop Science

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One-time fertilization at first flowering improves lint yield and dry matter partitioning in late planted short-season cotton

LUO Hong-hai^{1, 2*}, WANG Qiang^1*, ZHANG Jie-kun¹, WANG Lei-shan¹, LI Ya-bing³, YANG Guo-zheng¹

¹ College of Plant Science and Technology, Huazhong Agricultural University, Wuhan 430070, P.R.China
² College of Agronomy, Shihezi University, Shihezi 832003, P.R.China
³ Cotton Research Institute, Chines Academy of Agricultural Science, Anyang 455000, P.R.China

Abstract
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Abstract

Cotton producers have substantially reduced their inputs (labor, nutrients, and management) mainly by adopting a short-season cropping management that is characterized by late sowing, high density, and reduced fertilization with one-time application at the first bloom stage without lint yield reduction. However, it has been hypothesized that one-time fertilization at an earlier growth stage could be a more effective and economic management practice. A two-year field experiment was conducted by applying five fertilizer one-time fertilization at 0 (FT1), 5 (FT2), 10 (FT3), 15 (FT4), and 20 (FT5) days after the first flower appeared in the field and one three-split fertilizer application taken as the conventional control (FT6), making six treatments altogether. Cotton growth period, biomass accumulation, yield, and its formation were quantified. The results showed that the one-time fertilization did not affect the cotton growth progress as compared to FT6, however, the total crop cycles for FT3–FT5 were 3 days shorter. FT1 produced the highest cotton lint yield (1 396 kg ha^–1), which was similar to the FT6 but higher than the other treatments, and could be attributed to more bolls per unit area and higher lint percentage. Cotton yield was positively correlated with cotton plant biomass accumulated. FT1 had both the highest average (V_T) (193.7 kg ha^–1 d^–1) and the highest maximum (V_M) (220.9 kg ha^–1 d^–1) rates during the fast biomass accumulation period. These results suggest that one-time fertilizer application at the first flower stage might be an adjustment that is more effective than at first bloom, and allowed for easier decision making for application date due to non counting of plants with flowers is needed.

Keywords: one-time fertilization first flower cotton biomass accumulation yield

Received: 11 September 2018 Accepted:

Fund: This project was supported by the National Natural Science Foundation of China (31271665) and the Pairing Program of Key Laboratory of Oasis Ecology Agriculture, Xinjiang Production and Construction Group with Eminent Scholars in Elite Universities, China (201601).

Corresponding Authors: Correspondence YANG Guo-zheng, Tel/Fax: +86-27-87282130, E-mail: ygzh9999@mail.hzau.edu.cn; LI Ya-bing, Tel/Fax: +86-372-2562200, E-mail: criliyabing@163.com

About author: LUO Hong-hai, E-mail: luohonghai79@163.com; * These authors contributed equally to this study.

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	LUO Hong-hai
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Cite this article:

LUO Hong-hai, WANG Qiang, ZHANG Jie-kun, WANG Lei-shan, LI Ya-bing, YANG Guo-zheng. 2020.

One-time fertilization at first flowering improves lint yield and dry matter partitioning in late planted short-season cotton

. Journal of Integrative Agriculture, 19(2): 509-517.

Bange M, Milory S. 2004. Growth and dry matter partitioning of diverse cotton genotype. Field Crops Research, 87, 73–87.
Chen Y, Li Y B, Zhou M Y, Rui Q Z, Cai Z Z, Zhang X, Chen Y, Chen D H. 2018. Nitrogen (N) application gradually enhances boll development and decreases boll shell insecticidal protein content in N-deficient cotton. Frontiers in Plant Science, 9, 51–60.
Clawson E, Cothren J, Blouin D, Satterwhite J. 2008. Timing of maturity in ultra-narrow and conventional row cotton as affected by nitrogen fertilizer rate. Agronomy Journal, 100, 421–431.
Constable G, Bange M. 2015. The yield potential of cotton (Gossypium hirsutum L.). Field Crops Research, 182, 98–106.
Dong H, Kong X, Li W, Tang W, Zhang D. 2010. Effects of plant density and nitrogen and potassium fertilization on cotton yield and uptake of major nutrients in two fields with varying fertility. Field Crops Research, 119, 106–113.
Dong H, Li W, Eneji A, Zhang D. 2012. Nitrogen rate and plant density effects on yield and late-season leaf senescence of cotton raised on a saline field. Field Crops Research, 126, 137–144.
Fang W, Li L, Xie D, Ma Z, Zhang D, Du Y. 2009. Comparison of dry matter accumulation and N, P, K uptake and distribution in different organs and yield on hybrid cotton and conventional cotton. Plant Nutrition and Fertilizer Science, 15, 1401–1406.
Geng J, Ma Q, Zhang M, Li C, Liu Z, Lyu X, Zheng W. 2015. Synchronized relationships between nitrogen release of controlled release nitrogen fertilizers and nitrogen requirements of cotton. Field Crops Research, 184, 9–16.
Khan A, Najeeb U, Wang L, Tan D K Y, Yang G, Munsif F, Ali S, Hafeez A. 2017a. Planting density and sowing date strongly influence growth and lint yield of cotton crops. Field Crops Research, 209, 129–135.
Khan A, Wang L, Ali S, Tung S A, Hafeez A, Yang G. 2017b. Optimal planting density and sowing date can improve cotton yield by maintaining reproductive organ biomass and enhancing potassium uptake. Field Crops Research, 214, 164–174.
Kumbhar A, Buriro U, Junejo S, Oad F, Jamro G, Kumbhar B, Kumbhar S. 2008. Impact of different nitrogen levels cotton growth, yield and N-uptake planted in legume rotation. Pakistan Journal of Botany, 40, 767–778.
Laszlo S. 2008. Education, labor supply, and market development in rural Peru. World Development, 36, 2421–2439.
Ma Z, Fang W, Xie D, Li L, Zhu W. 2008. Effects of different ratios of base and top-dressing nitrogen fertilizer on the leaf senescence and yield of insect-resistant hybrid cotton. Acta Botanica Boreali-Occidentalia Sinica, 28, 2062–2066.
Mao S C, Li Y B, Zhi X Y, Lei Y P, Han Y C, Wang G P, Yang B F. 2016. Technology advancement of China’s cotton cultivation. Agricultural Outlook, 12, 57–64. (in Chinese)
McConnell J, Mozaffari M. 2005. Yield, petiole nitrate, and node development responses of cotton to early season nitrogen fertilization. Journal of Plant Nutrition, 27, 1183–1197.
Mullins G, Monks C, Delaney D. 2003. Cotton response to source and timing of nitrogen fertilization on a sandy coastal plain soil. Journal of Plant Nutrition, 26, 1345–1353.
Rochester I J, Constable G A. 2015. Improvements in nutrient uptake and nutrient use-efficiency in cotton cultivars released between 1973 and 2006. Field Crops Research, 173, 14–21.
Shafiq M. 2007. Household schooling and child labor decisions in rural Bangladesh. Journal of Asian Economics, 18, 946–966.
Shah A, Yang G, Tanveer M, Iqba J. 2017. Leaf gas exchange, source-sink relationship, and growth response of cotton to the interactive effects of nitrogen rate and planting density. Acta Physiologiae Plantarum, 39, 119.
Sun Y, Ma J, Sun Y, Xu H, Yang Z, Liu S, Jia X, Zhen H. 2012. The effects of different water and nitrogen manangements on yield and nitrogen use efficiency in hybrid rice of China. Field Crops Research, 127, 85–98.
Takahirl I. 2009. Caste discrimination and transaction costs in the labor market: Evidence from rural North India. Journal of Development Economics, 88, 292–300.
Tang H, Yang G, Zhang X, Siddique K. 2012. Improvement of fertilizer N recovery by allocating more N distribution in cotton (Gossypium hirsutum L.). International Journal of Basic and Applied Science, 12, 32–37.
Tung S A, Huang Y, Ali S, Hafeez A, Shah A N, Ma X, Shoaib A, Chattha M S, Liu A, Liu J, Zhang Z, Yang G. 2019. Mepiquat chloride effects on potassium acquisition and functional leaf physiology as well as lint yield in highly dense late-sown cotton. Industrial Crops and Products, 129, 142–155.
Wang L, Zhu J, Yang T, Wang B, Chen B, Liu H, Xu Y, Ma X, Zhao D. 2010. Effects of using strategy of N fertilizer on dry matter accumulation and yield component of cotton. Xinjiang Agricultural Sciences, 47, 1952–1957. (in Chinese)
Watts D B, Runion G B, Balkcom K S. 2017. Nitrogen fertilizer sources and tillage effects on cotton growth, yield and fiber quality in a coastal plain soil. Filed Crops Research, 201, 184–191.
Yang G, Tang H, Nie Y, Zhang X. 2011. Responses of cotton growth, yield, and biomass to nitrogen split application ratio. European Journal of Agronomy, 35, 164–170.
Yang G, Tang H, Tang J, Nie Y, Zhang X. 2012. Effect of fertilization frequency on cotton yield and biomass accumulation. Field Crops Research, 125, 161–166.
Yang G, Zhou M. 2010. Muti-site investigation of optimum planting density and boll distribution of high-yielding cotton (G. Hirsutum L.) in Hubei Province. Agricultural Sciences in China, 9, 1749–1757.
Yang G Z, Chu K Y, Tang H Y, Nie Y C, Zhang X L. 2013. Fertilizer 15N accumulation, recovery and distribution in cotton plant as affected by N rate and split. Journal of Integrative Agriculture, 12, 999–1007.

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