Plant Production Science (Jan 2016)

Characterizing N uptake and use efficiency in rice as influenced by environments

  • Peng Jiang,
  • Xiaobing Xie,
  • Min Huang,
  • Xuefeng Zhou,
  • Ruichun Zhang,
  • Jiana Chen,
  • Dandan Wu,
  • Bing Xia,
  • Hong Xiong,
  • Fuxian Xu,
  • Yingbin Zou

DOI
https://doi.org/10.1080/1343943X.2015.1128103
Journal volume & issue
Vol. 19, no. 1
pp. 96 – 104

Abstract

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To compare N uptake and use efficiency of rice among different environments and quantify the contributions of indigenous soil and applied N to N uptake and use efficiency, field experiments were conducted in five sites in five provinces of China in 2012 and 2013. Four cultivars were grown under three N treatments in each site. Average total N uptake was 10–12 g m−2 in Huaiji, Binyang, and Haikou, 20 g m−2 in Changsha, and 23 g m−2 in Xingyi. Rice crops took up 54.6–61.7% of total plant N from soil in Huaiji, Binyang, and Haikou, 64.3% in Changsha, and 63.5% in Xingyi. Partial factor productivity of applied N and recovery efficiency of applied N in Changsha were higher than in Huaiji, Binyang, and Haikou, but were lower than in Xingyi. Physiological efficiency of soil N and fertilizer N were lower in Changsha than in Huaiji, Binyang, and Haikou, while the difference in them between Changsha and Xingyi were small or inconsistent. Average grain yields were 6.5–7.5 t ha−1 (medium yield) in Huaiji, Binyang, and Haikou, 9.0 t ha−1 (high yield) in Changsha, and 12.0 t ha−1 (super high yield) in Xingyi. Our results suggest that both indigenous soil and applied N were key factors for improving rice yield from medium to high level, while a further improvement to super high yield indigenous soil N was more important than fertilizer N, and a simultaneous increasing grain yield and N use efficiency can be achieved using SPAD-based practice in rice production.

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