Effect of aerated irrigation with nitrogen fertiliser on soil properties and water and nitrogen use efficiency of maize

Yun-long Zhao¹Zeng-long An^1*Zhen-zhen Yu²Hongxuan WANG³

• ¹Heilongjiang Bayi Agricultural University, Daqing, China
• ²Guangdong Ocean University, Zhanjiang, Guangdong Province, China
• ³Chinese Academy of Tropical Agricultural Sciences, Haikou, Hainan Province, China

To assess the synergistic effects of nitrogen (N) application rates on soil properties, maize yield, and water-N use efficiency under aerated irrigation in red loamy soils of Guangdong, a 3-year field experiment (2021–2023) was conducted with three N levels [150 (N1), 300 (N2), and 450 kg·hm⁻² (N3)] and a control (CK). Results showed that N2(300 kg·hm-2)and N3(450 kg·hm-2) treatments significantly reduced soil bulk density by 3.87% and 5.23% (p<0.05), and increased total porosity by 5.40% and 6.27%, respectively, compared to CK. Soil water storage and respiration were highest under N2(300 kg·hm-2)during key growth stages (V6–VT, VT–R2). N application enhanced organic carbon (up to 59.6% in 300 kg·hm-2) and total nitrogen (up to 96.2% in 450 kg·hm-2), while decreasing C/N ratio and increasing microbial biomass (up to 78.9% higher in 300 kg·hm-2 vs. CK). N2(300 kg·hm-2)significantly improved maize yield by 63.7%, WUE by 70.9%, and N use efficiency (agronomic efficiency: 25.1 kg·kg⁻¹; recovery rate: 41.9%). A quadratic yield model indicated 250–300 kg·hm⁻² N as optimal. These findings suggest that moderate N application 300 kg·hm-2 under aerated irrigation enhances soil structure, nutrient availability, and crop productivity, offering a sustainable approach for nitrogen-efficient maize production and red soil management in subtropical regions.