Optimizing planting density and nitrogen application to enhance profit and nitrogen use of summer maize in Huanghuaihai region of China

Low planting density and irrational nitrogen (N) fertilization are two common practices in conventional cropping of smallholder maize production in Huanghuaihai region of China. A 2-year field experiment was carried out to study the effects of N application and planting density on maize phenology, dry matter accumulation, profit, yield, N uptake and efficiency indices. The experiments included three N application levels (120 kg ha(-1), N1; 180 kg ha(-1), N2; 240 kg ha(-1), N3) and three planting densities (60,000 plants ha(-1), D1; 75,000 plants ha(-1), D2; 90,000 plants ha(-1), D3). Increasing N input and planting density delayed the physiological maturity and enhanced dry matter accumulation. Comparing with the traditional N3 level, grain yield and profit were kept stable at N2 level and decreased at N1 level, partial factor productivity of applied N (PFPN) and nitrogen efficiency ratio (NER) were increased with the decreasing of N level. Comparing with the traditional D1 density, grain yield, profit and PFPN were increased at D2 density and then kept stable at D3 density, NER was kept stable at D2 density and then decreased at D3 density. Based on the predicted maximum profit, the optimal combinations of N application and planting density were 199 kg ha(-1) and 81,081 plants ha(-1) in 2017, and 205 kg ha(-1) and 84,782 plants ha(-1) in 2018. The two optimal combinations had an increase of 17.6% for grain yield, 39.8% for PEPN, 3.6% for NRE than the traditional N3D1 treatment. Therefore, an appropriate combination of increased planting density with reduced N application could enhance profit and nitrogen use of summer maize in Huanghuaihai region of China.

Automated summary

Low planting density and irrational nitrogen fertilization are common practices in smallholder maize production in the Huanghuaihai region of China. A 2-year field experiment was conducted to study the effects of N application and planting density on maize phenology, dry matter accumulation, profit, yield, N uptake, and efficiency. The results showed that increasing N input and planting density delayed physiological maturity and enhanced dry matter accumulation. Optimal combinations of N application and planting density were found to increase grain yield, profit, and nitrogen use efficiency. Therefore, adjusting planting density and N application can enhance profit and nitrogen use in maize production.