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Chinese Journal of Applied Ecology ›› 2016, Vol. 27 ›› Issue (3): 845-854.doi: 10.13287/j.1001-9332.201603.008

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Coupling effect of water and nitrogen on mechanically harvested cotton with drip irrigation under plastic film in arid area of western Inner Mongolia, China

LI Yong1, WANG Feng1, SUN Jing-sheng1*, LIU Hao1, YANG Jian-qiang2, XIAN Feng3, SU He2   

  1. 1Farmland Irrigation Research Institute, Chinese Academy of Agricultural Sciences/Ministry of Agriculture Key Laboratory of Crop Water Requirement and Regulation, Xinxiang 453003, Henan, China;
    2Alxa League Agricultural Technology Promotion Center, Alxa 750306, Inner Mongolia, China;
    3Inner Mongolia Academy of Agricultural and Animal Husbandry Sciences, Hohhot 010031, China
  • Received:2015-08-31 Online:2016-03-18 Published:2016-03-18
  • Contact: * E-mail: jshsun623@163.com
  • Supported by:
    This work was supported by National Science and Technology Pillar Program (2014BAD03B02) and Cotton Industry Technology System of National Modern Agriculture (CARS-18-19).

Abstract: In order to understand the main and interactive effects of water and nitrogen on crop growth and development, yield, fiber quality, and water-nitrogen use efficiency of mechanically harvested cotton with drip irrigation under plastic film in arid area of western Inner Mongolia, a two-factorial experiment with irrigation water amount and nitrogen dosage in completely randomized block design was conducted in Alxa Left Banner of Alxa League in Inner Mongolia. The levels of water irrigation were 216 mm (W1), 288 mm (W2) and 360 mm (W3), and the nitrogen dosages were 127.5 kg·hm-2(N1), 195 kg·hm-2(N2) and 262.5 kg·hm-2(N3). The results showed that water was the decisive factor for cotton growth, and plant height and dry matter accumulation increased rapidly with increasing the water irrigation level, but the ratio of reproductive organs to shoot biomass decreased. Compared with the treatments W1 and W2, the average boll number per plant in W3 was increased by 25.4% and 17.5%, the seed cotton yield was improved by 18.1% and 11.9%, but the single boll mass was decreased by 5.8% and 4.6%, respectively. It indicated that an increase in boll number per plant was the determining factor in achieving high seed cotton yield. Moreover, there was also a significant interactive effect between water and nitrogen affecting the seed cotton yield. Under the condition with low-level irrigation (W1 and W2), the highest seed cotton yield was measured in N1; while for the condition in W3, the seed cotton yield in N2 was greater than that in N1 and N3 by 8.5% and 31.9%, respectively. In general, the regulation of water and nitrogen had no significant effect on fiber quality. Water use efficiencyin W1N1 was 1.37 kg·m-3, which was not significantly different with the value in W3N2, and the nitrogen partial factor productivityin W3N1 was the maximum (51.35 kg·kg-1). Therefore, irrigation had a significant effect on yield increasing, but nitrogen application promoted the seed cotton yield only under well-watered conditions. The treatment with irrigation amount of 360 mm and nitrogen fertilizer of 195 kg·hm-2 could promote the shoot biomass accumulation significantly and achieve the highest seed cotton yield, and its water use efficiency and nitrogen partial factor productivity were 1.37 kg·m-3 and 36.41 kg·kg-1, respectively, indicating the potential of water-saving and yield increasing. Therefore, it was recommended as a suitable water and nitrogen management for the mechanically harvested cotton in arid area of western Inner Mongolia.