Mechanisms of lime-induced N2O mitigation in acidic soils: A meta-analysis of microbial activity and substrate dynamics

IF 4.8 2区农林科学 Q1 SOIL SCIENCE

Applied Soil Ecology Pub Date : 2025-05-15 DOI:10.1016/j.apsoil.2025.106175

Kiya Adare Tadesse , Tianfu Han , Zhe Shen , Nano Alemu Daba , Jiwen Li , Muhammad Numan Khan , Asad Shah , Huimin Zhang

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引用次数: 0

Abstract

Previous studies reported a reduction in N₂O emissions following lime application. However, the mechanisms underlying N₂O reduction under different soil acidifications are not clear and require further investigation. As a result, it is imperative to gain insights into how lime application affects N₂O emissions and associated microbial activities under varying soil acidification and other factors. Only studies obtained from the agroecosystems were considered for the current meta-analysis. Accordingly, this meta-analysis was conducted with 684, 141, 149, and 94 paired observations for the response variables of N₂O emissions, archaeal amoA gene abundance, bacterial amoA gene abundance, and nosZ gene abundance, respectively, obtained from 39 peer-reviewed studies. The current meta-analysis findings indicated that the lime application reduced soil N₂O emissions by 46.63 % and raised soil pH by 27.63 % across all paired observations compared to control. Overall, lime application also increased the abundance of bacterial amoA and nosZ genes by 101.17 % and 49.63 %, respectively, while decreasing the abundance of archaeal amoA by 6.39 %. Our structural equation modeling (SEM) suggested that the differences in the reduction of N₂O emission magnitudes under different lime rates are due to differences in the degree of soil pH manipulation. Lime application rate was identified as the primary factor influencing the response of soil N₂O emissions to lime, followed by soil pH. Our results from SEM indicated that the main drivers of the variable responses in soil N₂O emissions to lime application under different soil acidifications are the variable responses of N₂O-associated microbial activities and substrate availability. The greater reduction in N₂O emissions under neutral soil conditions, compared to acidic conditions, is primarily attributed to a pH-driven shift in microbial activity, evidenced by a larger increase in nosZ gene abundance and a decrease in bacterial amoA gene abundance.

Grain yields of wheat, rice, and maize increased by 9.42 %, 11.40 %, and 62.42 %, respectively, following lime application compared to the control. Based on our findings, we concluded that applying lime to acidic soils is a suitable option for reducing soil N₂O emissions by affecting the activity of associated microbial functional genes and substrate availability in agricultural ecosystems.

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酸性土壤中石灰诱导的N2O缓解机制：微生物活动和基质动态的荟萃分析

以前的研究报告了石灰施用后N2O排放量的减少。然而，不同酸化条件下N2O还原的机制尚不清楚，需要进一步研究。因此，深入了解石灰在不同土壤酸化等因素下对N2O排放及相关微生物活动的影响是十分必要的。目前的荟萃分析只考虑了来自农业生态系统的研究。因此，本meta分析分别对39项同行评审研究中获得的684、141、149和94个配对观测值进行了N₂O排放量、古菌amoA基因丰度、细菌amoA基因丰度和nosZ基因丰度的响应变量进行了分析。目前的荟萃分析结果表明，与对照相比，在所有成对观察中，石灰施用减少了土壤N2O排放46.63%，土壤pH值提高了27.63%。总体而言，石灰处理使细菌amoA和nosZ基因的丰度分别提高了101.17%和49.63%，而使古细菌amoA的丰度降低了6.39%。我们的结构方程模型（SEM）表明，不同石灰用量下N2O排放减少幅度的差异是由于土壤pH操纵程度的差异。石灰施用量是影响土壤N2O排放对石灰响应的主要因素，其次是土壤ph。SEM结果表明，不同酸化条件下土壤N2O排放对石灰响应的主要驱动因素是N2O相关微生物活性和基质有效性的变量响应。与酸性土壤条件相比，中性土壤条件下的N₂O排放量减少幅度更大，主要是由于ph驱动的微生物活动变化，nosZ基因丰度增加较大，细菌amoA基因丰度减少。施用石灰后，小麦、水稻和玉米产量分别比对照提高9.42%、11.40%和62.42%。基于我们的研究结果，我们得出结论，在酸性土壤中施用石灰是通过影响农业生态系统中相关微生物功能基因的活性和底物有效性来减少土壤N2O排放的合适选择。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

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.