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Enhancing maize yield stability, soil health, and microbial diversity via long-term manure practices: Insights from a 14-year trial

Minghui Qu, Yinglong Chen, Aziz Khan, Peng Liu

2025Environmental Technology & Innovation13 citationsDOIOpen Access PDF

Abstract

Identifying efficient nutrient management strategies is crucial for maintaining soil health and boosting crop production. A 14-year field experiment with no nitrogen fertilizer (CK), urea with 200 kg N ha −1 (U 200 ), urea with 100 kg N ha −1 (U 100 ), manure with 200 kg N ha −1 (M 200 ), manure with 100 kg N ha −1 (M 100 ), and urea with 100 kg N ha −1 plus manure with 100 kg N ha −1 (U 100 M 100 ) was conducted to assess the effects on soil quality, microbial diversity and yield sustainability. Long-term fertilization increased the α-diversity of bacteria and significantly altered the β-diversity of both bacteria and fungi. Prolonged fertilization significantly augmented soil nitrogen and phosphorus levels. Concomitantly, the activities of urease, invertase, and alkaline phosphatase were substantially elevated. Compared with U 200 , M 200 and U 100 M 100 raised the soil quality index (SQI) by 27–35 % and 11–24 %, respectively. Long-term manure application increased yield by 42–51 % compared with CK. Furthermore, manure application promoted yield stability (CV) and sustainable yield index (SYI) from 2017 to 2023. Notably, U 100 M 100 improved yield, SYI, and SQI more effectively. SQI significantly correlated with yield, SYI, and CV, suggesting its importance for sustainable production. A partial least squares path model showed that the bacterial community influenced SQI by modulating soil nutrients, and the fungal community impacted SQI by affecting soil enzyme activities. Ultimately, these microbial-mediated effects on SQI influenced crop yield. Overall, substitution of partial mineral fertilizers with manure is a promising strategy for sustainable agricultural production in terms of improving soil health and yield sustainability. • Manure substitution enhanced soil bacterial α-diversity. • Microbial community diversity regulated soil nutrients and enzyme activity. • Manure substitution displayed superior yield potential and soil quality index. • Manure enhanced sustainable yield index and yield stability.

Topics & Concepts

ManureTerm (time)AgronomyYield (engineering)Diversity (politics)Soil healthEnvironmental scienceLong-term experimentMathematicsAgroforestrySoil scienceBiologySoil waterSoil organic matterSociologyFertilizerMetallurgyAnthropologyQuantum mechanicsPhysicsMaterials scienceCrop Yield and Soil FertilitySoil Carbon and Nitrogen DynamicsAgronomic Practices and Intercropping Systems