The effects of intraspecific competition and light transmission within the canopy on wheat yield in a wide-precision planting pattern

doi:10.1016/S2095-3119(19)62724-3

Journal of Integrative Agriculture

2020, Vol. 19

Issue (6): 1577-1585 DOI: 10.1016/S2095-3119(19)62724-3

Special Issue: 麦类耕作栽培合辑Triticeae Crops Physiology · Biochemistry · Cultivation · Tillage

Crop Science

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The effects of intraspecific competition and light transmission within the canopy on wheat yield in a wide-precision planting pattern

LIU Xin*, WANG Wen-xin*, LIN Xiang, GU Shu-bo, WANG Dong

College of Agronomy, Shandong Agricultural University/State Key Laboratory of Crop Biology, Ministry of Science and Technology/Key Laboratory of Crop Ecophysiology and Farming System, Ministry of Agriculture, Tai’an 271018, P.R.China

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Abstract

The wide-precision planting pattern has become widely used in the North China Plain as a practice for increasing wheat yield. However, the effects of tillering development and light transmission within canopy on wheat yield under different sowing widths have not been clearly described. Therefore, a two-year experiment was conducted, including four different seeding widths (6 cm, W6; 8 cm, W8; 10 cm, W10; 12 cm, W12) and the traditional planting pattern with seeding width of 4 cm (W4). The results indicated mainly positive effects by the reduced intraspecific competition, specifically all three yield components of W6 and W8 were higher than those for W4. The configurations with more than 10-cm seeding width were mainly affected by the negative effect of a relative homogeneous canopy, leading to the weakened light transmission, leaf senescence, and reduced grain number per spike. Finally, the yields of W6 and W8 were significantly higher than that of W4, whereas the yield in W12 was lower (though not significantly) than W4. In wheat production, therefore, the appropriate seeding width of 6–8 cm is recommended for farmers, whereas the too wide seeding width, with more than 10 cm, should be avoided.

Keywords: light transmission seeding width tillers number winter wheat yield components

Received: 21 January 2019 Accepted:

Fund: This work was supported by the Special Fund for Agro-scientific Research in the Public Interest, China (201503130).

Corresponding Authors: Correspondence WANG Dong, Tel: +86-538-8240096, Fax: +86-538-8242226, E-mail: wangd@sdau.edu.cn

About author: * These authors contributed equally to this study.

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	LIU Xin
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LIU Xin, WANG Wen-xin, LIN Xiang, GU Shu-bo, WANG Dong. 2020. The effects of intraspecific competition and light transmission within the canopy on wheat yield in a wide-precision planting pattern. Journal of Integrative Agriculture, 19(6): 1577-1585.

Abichou M, Fournier C, Dornbusch T, Chambon C, Solan B D, Gouache D, Andrieu B. 2018. Parameterising wheat leaf and tiller dynamics for faithful reconstruction of wheat plants by structural plant models. Field Crops Research, 218, 213–230.
Balkcom K S, Price A J, Santen E V, Delaney D P, Boykin D L, Arriaga F J, Bergtold J S, Kornecki T S, Raper R S. 2010. Row spacing, tillage system, and herbicide technology affects cotton plant growth and yield. Field Crops Research, 117, 219–225.
Beres B L, Turkington T K, Kutcher H R, Irvine R B, Johnson E N, O’Donovan J T, Harker K N, Holzapfel C B, Mohr R M, Peng G, Spaner D M. 2016. Winter wheat cropping system response to seed treatments, seed size and sowing density. Agronomy Journal, 108, 1101–1111.
Bian C Y, Ma C J, Liu X H, Gao C, Liu Q R, Yan Z X, Ren Y J, Li Q Q. 2016. Responses of winter wheat yield and water use efficiency to irrigation frequency and planting pattern. PLoS ONE, 11, e0154673.
Cai T, Xu H C, Peng D L, Yin Y P, Yang W B, Ni Y L, Chen X G, Xu C L, Yang D Q, Cui Z Y, Wang Z L. 2014. Exogenous hormonal application improves grain yield of wheat by optimizing tiller productivity. Field Crops Research, 155, 172–183.
Chen X, Hao M D. 2015. Low contribution of photosynthesis and water-use efficiency to improvement of grain yield in Chinese wheat. Photosynthetica, 53, 519–526.
Dai X L, Xiao L L, Jia D Y, Kong H B, Wang Y C, Li C X, Zhang Y, He M R. 2014. Increased plant density of winter wheat can enhance nitrogen-uptake from deep soil. Plant and Soil, 384, 141–152.
Dornbusch T, Baccar R, Watt J, Hillier J, Bertheloot J, Fournier C, Andrieua B. 2014. Plasticity of winter wheat modulated by sowing date, plant population density and nitrogen fertilisation: Dimensions and size of leaf blades, sheaths and internodes in relation to their position on a stem. Field Crops Research, 121, 116–124.
Gonzalez-navarro O E, Griffiths S, Molero G, Reynolds M P, Slafer G A. 2016. Variation in developmental patterns among elite wheat lines and relationships with yield, yield components and spike fertility. Field Crops Research, 196, 294–304.
Haegele J W, Becker R J. 2014. Row arrangement, phosphorus fertility, and hybrid contributions to managing increased plant density of maize. Agronomy Journal, 106, 1838–1846.
Li Q Q, Bian C J, Liu X H, Ma C, Liu Q R. 2015. Winter wheat grain yield and water use efficiency in wide-precision planting pattern under deficit irrigation in North China Plain.Agricultural Water Management, 153, 71–76.
Lin P, Qi H, Li C F, Zhao M. 2016. Optimized tillage practices and row spacing to improve grain yield and matter transport efficiency in intensive spring maize. Field Crops Research, 198, 258–268.
Liu X, Rahman T, Song C, Yang F, Su B Y, Cui L, Bu W Z, Yang W Y. 2018. Relationships among light distribution, radiation use efficiency and land equivalent ratio in maize-soybean strip intercropping. Field Crops Research, 224, 91–101.
Liu X H, Ren Y J, Gao C, Yan Z X, Li Q Q. 2017. Compensation effect of winter wheat grain yield reduction under straw mulching in wide-precision planting in the North China Plain. Scientific Reports, 7, 1–9.
Ma S C, Wang T C, Guan X K, Zhang X. 2018. Effect of sowing time and seeding rate on yield components and water use efficiency of winter wheat by regulating the growth redundancy and physiological traits of root and shoot. Field Crops Research, 221, 166–174.
Man J G, Wang D, White P J, Yu Z W. 2014. The length of micro-sprinkling hoses delivering supplemental irrigation affects photosynthesis and dry matter production of winter wheat. Field Crops Research, 168, 65–74.
Quan R D, Shang M, Zhang H, Zhao Y X, Zhang J R. 2004. Improved chilling tolerance by transformation with betA gene for the enhancement of glycinehetaine synthesis in maize. Plant Science, 166, 141–149.
Retasánchez D G, Fowler J L. 2002. Canopy light environment and yield of narrow-row cotton as affected by canopy architecture. Agronomy Journal, 94, 1317–1323.
Sadras V O, Lawson C. 2013. Nitrogen and water-use efficiency of Australian wheat varieties released between 1958 and 2007. European Journal of Agronomy, 46, 34–41.
Slafer G A, Savin R, Sadras V O. 2014. Coarse and fine regulation of wheat yield components in response to genotype and environment. Field Crops Research, 157, 71–83.
Soil System Classification Group of Nanjing Soil Research Institute of Chinese Academy of Sciences, Collaborative Research Group on Soil System Classification in China. 2001. Soil System Classification and Retrieval in China. 3rd ed. China University of Science and Technology Press. (in Chinese)
Spink J H, Semere T, Sparkes D L, Whaley J M, Foulkes M J, Clare R W, Scott P K. 2015. Effect of sowing date on the optimum plant density of winter wheat. Annals of Applied Biology, 137, 179–188.
Townsend A J, Retkute R, Chinnathambi K, Randall J W, Foulkes J, Carmosilva E, Murchie E H. 2018. Suboptimal acclimation of photosynthesis to light in wheat canopies. Plant Physiology, 176, 1233–1246.
Wang D, Yu Z W, White P J. 2013. The effect of supplemental irrigation after jointing on leaf senescence and grain filling in wheat. Field Crops Research, 151, 35–44.
Wang M, Chen Y, Zhang R, Wang W, Zhao X, Du Y, Yin H. 2015. Effects of chitosan oligosaccharides on the yield components and production quality of different wheat cultivars (Triticum aestivum L.) in Northwest China. Field Crops Research, 172, 11–20.
Yu S L, Yu Z W, Dong Q Y, Wang D, Zhang Y L, Yao D C, Wang J Q. 2010. Winter wheat high-yield culture technique of 789.9 kg per mu. Shandong Agricultural Sciences, 4, 11–12. (in Chinese)
Zhang J W, Sun J S, Duan A W, Wang J L, Shen X J, Liu X F. 2007. Effects of different planting patterns on water use and yield performance of winter wheat in the Huang-Huai-Hai Plain of China. Agricultural Water Management, 92, 41–47.
Zhao D D, Shen J Y, Lang K, Liu Q R, Li Q Q. 2013. Effects of irrigation and wide-precision planting on water use, radiation interception, and grain yield of winter wheat in the North China Plain. Agricultural Water Management, 118, 87–92.
Zhao H, Dai T, Jing Q, Jiang D, Cao W. 2007. Leaf senescence and grain filling affected by post-anthesis high temperatures in two different wheat cultivars. Plant Growth Regulation, 51, 149–158.

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