文献类型： 外文期刊

作者： Xu, Lei ¹ ; Zhou, Yan ¹ ; Miao, Congrong ¹ ; Chen, Hong ¹ ; Zhang, Jianwei ³ ; Qian, Haoyu ¹ ; Hou, Pengfu ⁴ ; Ding, Yanfeng ¹ ; Liu, Zhenghui ¹ ; Li, Weiwei ¹ ; Wang, Songhan ¹ ; Jiang, Yu ¹ ; Li, Ganghua ¹ ;

作者机构： 1.Nanjing Agr Univ, Sanya Inst Nanjing Agr, Jiangsu Collaborat Innovat Ctr Modern Crop Prod, Key Lab Crop Physiol Ecol & Prod Management, Nanjing, Peoples R China

2.Zhejiang A&F Univ, Hangzhou 311300, Peoples R China

3.Jiangsu Acad Agr Sci, China Inst Agr Resources & Environm, Sci Observing & Expt Stn Arable Land, Minist Agr & Rural Affairs, Nanjing 210095, Jiangsu, Peoples R China

4.Jiangsu Acad Agr Sci, Key Lab Agroenvironm Downstream Yangze Plain, Minist Agr & Rural Affairs China, Nanjing 210014, Peoples R China

关键词： straw return; microbial-derived nitrogen; soil aggregates; eco-enzymatic stoichiometry

期刊名称：SOIL & TILLAGE RESEARCH （ 影响因子：6.8； 五年影响因子：7.8 ）

ISSN： 0167-1987

年卷期： 2024 年 244 卷

页码：

收录情况： SCI

摘要： Straw return is a widespread agricultural practice for improving cropland nitrogen (N) stocks. However, the contribution of microbial N to the soil aggregate N pool and the underlying microbial metabolic regulation mechanisms remain uncertain. This study was based on a 13-year field experiment with rice (Oryza sativa L.) and wheat (Triticum aestivum L.) rotation, using only a chemical fertilizer alone (CF) as the control. We analyzed the effects of the chemical fertilizer combined with (CS, 9500 kg ha(-1) y(-1)) and wheat (4000 kg ha(-1) y(-1)) straw on microbial derived-N, microbial carbon (C) and N limitations. We also assessed microbial N use efficiency (NUE) in various aggregates of ferric lixisols (0-20 cm). Rotary tillage reached a depth of 20 cm. The CS significantly increased microbial-derived N concentrations in soil aggregates and enhanced the contribution of fungal residual N to the N pool in aggregates < 0.25 mm, but did not affect those > 0.25 mm. Conversely, the bacterial contribution to the N pool was not affected by CS. Meanwhile, CS significantly increased the soil organic C and microbial biomass in the aggregates. The results of our eco-enzymatic stoichiometric model revealed that the CS significantly alleviated microbial C limitations and increased microbial NUE in soil aggregates. Structural equation modeling further revealed that the microbial biomass and soil organic C contents are key drivers of the microbial C limitation. The increased contribution of fungal residual N to the N pools in < aggregates 0.25 mm was attributed to improved microbial NUE resulting from the straw, without altering net N mineralization rates or beta-1,4-N-acetylglucosidase activity. Our findings suggest that straw return promotes microbial-derived N production and sequestration by alleviating microbial C limitation. The strategies governing these microbial- derived N responses in aggregates to straw return might vary. This might be valuable for designing cropland management practices to improve N storage.