Modelling maize yield, soil nitrogen balance and organic carbon changes under long-term fertilization in Northeast China

Optimized fertilization is an effective strategy for improving nitrogen (N) use efficiency and maintaining high crop yield, but its long-term impacts on soil organic carbon (C) and inorganic N dynamics remain unclear. The objectives of this study were to 1) explore the economic optimum N rate and evaluate the DSSAT CERES-Maize model using the measurements from three 3-year maize (Zea mays L.) field experiments, in Gongzhuling and Yushu County, Northeast China, and 2) assess the long-term impacts of farmers' N rate (N250), optimum N rate (N180) and organic-inorganic combined N rate (MN180) on maize yields, soil N and C changes from 1985 to 2020. Results showed that similar maize yields of 8000-11,000 kg ha-1 were achieved under the average eco-nomic optimum N rate of 170 kg N ha-1 relative to N250 in both counties. Good agreements were observed between the simulated and measured maize yield, above-ground biomass, N uptake and soil nitrate (NO3--N). Long-term simulation confirmed that N180 and MN180 can achieve the same yield as N250 in both counties. The lowest annual soil inorganic N balance, NO3--N leaching, and nitrous oxide (N2O) and ammonia (NH3) emissions were achieved under MN180, followed by N180 in both sites. Higher NO3--N leaching was found in sandy clay loam soil than silt clay loam and clay loam soils. Average soil organic C (SOC, 0-0.2 m) increased from 1.3 to 2.4% in Gongzhuling and from 2.2 to 2.4% in Yushu under MN180 during the 35-year period, but it showed declining trends under N180 and N250. We concluded that the economic optimum N rate could be an option to replace current farmers' N rate for the continuous maize. Substitution of inorganic fertilizer by 20-30% manure under the optimum N rate showed advantage on maintaining high yield, reducing soil inorganic N losses as well as increasing SOC stock for sustainable agriculture.

Automated summary

Optimized fertilization is an effective strategy for improving nitrogen use efficiency and maintaining high crop yield. This study investigated the long-term impacts of different nitrogen rates on maize yields and soil nitrogen and carbon dynamics. The results showed that the optimum nitrogen rate and combined organic-inorganic nitrogen rate can achieve similar yields as the farmers' nitrogen rate. Furthermore, substituting 20-30% manure for inorganic fertilizer under the optimum nitrogen rate could help reduce soil nitrogen losses and increase soil organic carbon stock for sustainable agriculture.