Can deep fertilizer application enhance maize productivity by delaying leaf senescence and decreasing nitrate residue levels?

Abstract

Deep fertilizer application is an effective strategy for minimizing gaseous losses and improving the nutrient use efficiency and grain yield. However, it is unclear whether deep fertilizer application can improve the antioxidant defense system in maize ( Zea mays L.) leaves and the photosynthetic capacity after silking to delay senescence, and then contribute to improvements in the yield and resource utilization efficiency. The effects on the NO 3 – -N residue levels also require elucidation. Therefore, we tested different fertilization application depths in the field during 2019–2020, where all of the N-P fertilizer was applied underground at 5 cm (D5), 15 cm (D15), 25 cm (D25), and 35 cm (D35) before sowing spring maize in the Loess Plateau region of China. The results showed that the antioxidant and photosynthetic performance of the leaves followed the order of: D25 > D15 > D5 > D35. The H 2 O 2 and O 2 – contents decreased by 2 1.5% and 14.0% under D25 compared with D5, respectively, and the net photosynthetic rate (Pn) and mean grain filling rate (G mean ) increased by 32.9% and 5.0%. The translocation and assimilation of nitrogen under D25 increased by 20.1% and 18.6% compared with D5, respectively, the translocation and assimilation of phosphorus increased by 43.6% and 54.3%, and the biomass and maize yield increased by 12.7% and 13.8%. The water use efficiency (23.5 kg·ha –1 ·mm –1 ), water productivity (45.7 kg ha –1 mm –1 ), nitrogen use efficiency (43.6%), and phosphorus use efficiency (20.3%) were significantly higher under D25 than the other treatments. The accumulated residual nitrate contents in the 0–100 cm soil layer were 6.0% and 8.0% lower under D15 and D25 than D5, respectively ( P < 0.05). However, D35 significantly increased the accumulated residual nitrate content in the 0–200 cm soil depth to increase the risk of leaching. A fertilization depth of 25 cm can delay maize leaf senescence and enhance the grain-filling capability by improving the antioxidant defense system and photosynthetic capacity of the leaves after silking, thereby increasing the maize yield and resource utilization efficiency. • Fertilization depth influenced spatial and temporal distribution of soil NO 3 – -N. • Leaf antioxidant defense system improved with appropriate fertilization depth. • Fertilization depth of 25 cm enhanced maize productivity and resource utilization. • Fertilization depth of 35 cm increased NO 3 – -N residue contents in 0–200 soil layer.