AUTHOR=Zhang Weina , Xu Dongzhi , Wang Han , Jiang Bingshen , Liang Changli , Huang Minzhi , Chen Zilong , Zhang Xinmin , Su Dong , Yu Mingfu , Liu Junhe TITLE=Modeling Long-Term Impacts of Phosphorus Fertilization Strategies on Maize Productivity and Soil P Dynamics in Calcareous Soils of North China Plain JOURNAL=Spanish Journal of Soil Science VOLUME=Volume 15 - 2025 YEAR=2025 URL=https://www.frontierspartnerships.org/journals/spanish-journal-of-soil-science/articles/10.3389/sjss.2025.14718 DOI=10.3389/sjss.2025.14718 ISSN=2253-6574 ABSTRACT=The North China Plain (NCP), a major maize production region in China, faces critical challenges of P overuse under intensive farming, leading to soil P accumulation, leaching risks, and threats to groundwater quality and P resource sustainability. This study employed a parameter-calibrated APSIM model (v7.9) to simulate long-term effects (2007–2017) of eight P application rates (0–300 kg P2O5 ha−1) on maize growth, P utilization, and soil P dynamics using field trial data from Quzhou Country (36.9°N, 115.0°E), Hebei Province, China. Results demonstrated that 71 kg P2O5 ha−1 optimized maize productivity, achieving mean aboveground biomass and grain yields of 17.5 t ha−1 and 9.3 t ha−1, respectively, with a P use efficiency (PUE) of 17%. Continuous P fertilization induced progressive accumulation of labile P (32 mg/kg under 75 kg P2O5 ha−1 application rate vs. 40.8 mg/kg under 100 kg P2O5 ha-1 application rate in 2017) and stable inorganic P pools, with P100 exceeding the environmental threshold (39.9 mg/kg) for calcareous soils. Post-cessation simulations (22 years) revealed that legacy P from 11-year P75 applications sustained maize yields at 8–10 t ha−1 for 12–13 years, despite labile P decreasing from 32.3 to 15.8 mg/kg. Model analysis highlighted limitations in APSIM’s current P module, which prioritizes adsorption-desorption over precipitation-dissolution mechanisms critical for calcareous soils. These findings provide a theoretical foundation for P reduction strategies in NCP maize systems.