Abstract
In terms of tillering potential, the aboveground portions of rice are significantly influenced by the nitrogen level (NL) and transplant density (TD). To obtain a suitable combination of NL and TD, five NLs (0, 90, 180, 270 and 360 kg ha-1) and two TDs [high density (HD), 32.5×104 hills ha-1; low density (LD), 25.5×104 hills ha-1] were used in the rice experiments during 2012 to 2014, in Jiangsu, China. The results showed the highest grain yield of rice obtained at HD and LD when N supply was 180 and 270 kg ha-1, respectively. That’s because there are more tillers per unit area, a larger leaf biomass fraction of total aboveground biomass, a larger leaf area index (LAI) and a larger canopy photosynthesis potential (CPP) at HD. It can be concluded that, higher rice planting densities resulted in less N inputs, while more N is needed to improve single plant actual tiller ability under low density to offset the reduced planting density. When the NL was more than 180 kg ha-1, the actual tillering ability of a single plant at LD was 20% more than that at HD. Based on these results, the supply of 1 kg N can be replaced by adding approximately 1000 planting hills per hectare. Therefore, adjusting the transplant density could be an efficient method to reduce the amount of nitrogen fertilizer and increase the nitrogen fertilizer use efficiency, which is very conducive to the sustainable development of agriculture.
Highlights
Rice (Oryza sativa L.) is one of the most important food crops and is the staple food for more than half of the world population [1]
The results showed that rice plants at high and low densities obtained their highest grain yields when they needed lower and higher nitrogen supply rates, respectively
Consistent with previous studies, our results demonstrated that the response of rice yield to nitrogen level (NL) follows a parabolic curvilinear relationship both at high density (HD) and at low density (LD) [12, 20, 21]
Summary
Rice (Oryza sativa L.) is one of the most important food crops and is the staple food for more than half of the world population [1]. Due to increasing global population and improvements in the quality of life, approximately 50% more food will be needed by 2030, with double that being needed by 2050 [2]. Enhancement of N use efficiency is a key factor to sustain and increase the yield of rice. Due to its main role in the formation of chlorophyll, proteins and nucleic acids, N is considered a major mineral element that is required more consistently and in larger amounts than the other nutrients for rice production [3, 4]. To obtain ideal population productivity, nitrogen fertilizer has been widely used by farmers, while the adjustment of planting density is often neglected.
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