Long-term effects of film mulching and fertilization regimes on gross N transformations in calcareous dryland soils

IF 4.8 2区 农林科学 Q1 SOIL SCIENCE
Na Gao , Ting Zhang , Zhaoyang Li , Xiaofan Tian , Jiayu Chen , Jinbo Zhang , Christoph Müller , Shiqing Li
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Abstract

Plastic film mulching (PM) and nitrogen (N) fertilization regimes significantly affect crop yield, N supply capacity, and N losses. However, the long-term effects and the underlying mechanisms, like the belowground N transformations, call for in-depth investigation. Here, a 15N tracing study was conducted to quantify the gross N transformation rates of the calcareous soil subjected to 12 years of PM and various fertilization regimes. We found that autotrophic nitrification (ONH4) and mineralization (M) were the predominant soil N conversion processes, while dissimilatory nitrate reduction to ammonium (DNRA) and nitrate immobilization (INO3) were negligible in the calcareous soil, leading to the accumulation of nitrate. Long-term PM significantly decreased the rates of M, recalcitrant organic-N mineralization (MNrec), ONH4, and NH4+ immobilization to labile organic-N (INH4_Nlab) due to the negative effect on the abundances of fungi and ammonia-oxidizing bacteria (AOB) amoA gene compared to control soil. Relative to no N control, different fertilization regimes significantly increased the AOB amoA gene abundance, decreased fungal abundance and ITS:16S ratio, thus increasing ONH4 and M, decreasing NH4+ immobilization rates to labile and recalcitrant organic-N. Compared to normal N rate (F225), high N rate (F380) and normal N plus manure (F225+M) markedly increased ONH4 and INO3. Regression analyses revealed that M and AOB amoA gene abundance affected ONH4, and in turn N2O production. The findings provide an improved understanding of the long-term effects of PM and N managements on soil N supply capacity and potential N losses based on internal N cycling and molecular biology.

Abstract Image

覆膜和施肥制度对钙质旱地土壤氮转化总量的长期影响
塑料薄膜覆盖(PM)和氮(N)施肥制度对作物产量、氮供应能力和氮损失有显著影响。然而,其长期影响和潜在机制(如地下氮转化)需要深入研究。在此,我们进行了一项 15N 追踪研究,以量化石灰性土壤在 12 年的 PM 和各种施肥制度下的总氮转化率。我们发现,在钙质土壤中,自养硝化(ONH4)和矿化(M)是最主要的土壤氮转化过程,而硝酸盐还原成铵(DNRA)和硝酸盐固定化(INO3)则微不足道,从而导致硝酸盐的积累。与对照土壤相比,由于真菌和氨氧化细菌(AOB)amoA 基因的丰度受到负面影响,长期 PM 明显降低了 M、难降解有机氮矿化(MNrec)、ONH4 和 NH4+ 固定化为可变有机氮(INH4_Nlab)的速率。相对于无氮对照,不同施肥制度显著增加了氨氧化细菌(AOB)amoA基因丰度,降低了真菌丰度和ITS:16S比值,从而增加了ONH4和M,降低了NH4+对易变和难变有机氮的固定率。回归分析表明,M 和 AOB amoA 基因丰度影响 ONH4,进而影响 N2O 的产生。这些研究结果基于内部氮循环和分子生物学,加深了人们对 PM 和氮管理对土壤氮供应能力和潜在氮损失的长期影响的理解。
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来源期刊
Applied Soil Ecology
Applied Soil Ecology 农林科学-土壤科学
CiteScore
9.70
自引率
4.20%
发文量
363
审稿时长
5.3 months
期刊介绍: Applied Soil Ecology addresses the role of soil organisms and their interactions in relation to: sustainability and productivity, nutrient cycling and other soil processes, the maintenance of soil functions, the impact of human activities on soil ecosystems and bio(techno)logical control of soil-inhabiting pests, diseases and weeds.
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