Nitrogen fertilizer driven nitrous and nitric oxide production is decoupled from microbial genetic potential in low carbon, semi-arid soil

IF 2.1 Q3 SOIL SCIENCE

Frontiers in soil science Pub Date : 2023-01-10 DOI:10.3389/fsoil.2022.1050779

M. McDonald, Katie L. Lewis, P. DeLaune, Brian A. Hux, T. Boutton, T. Gentry

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引用次数: 3

Abstract

Introduction Nitrous oxide (N2O) emission from soil is a major concern due to its contribution to global climate change and its function as a loss mechanism of plant-available nitrogen (N) from the soil. This is especially true in intensive agricultural soils with high rates of N fertilizer application such as those on the semi-arid Southern High Plains, USA. Methods This study examined emissions of N2O, pore-space concentrations of N2O and nitric oxide (NO), soil chemical properties, water content, and the genetic potential for N cycling five years after conservation system and N management implementation. Results For these semi-arid soils with low N, carbon, and water contents, large soil N2O emissions (up to 8 mL N2O-N m-2 day-1) are directly related to the application of N fertilizer which overwhelms the N2O reducing capacity of the soil. When this fertilizer N is depleted, N2O flux is either low, non-existent, or net-negative and has been observed as early as mid-season for preplant applied N fertilizer (-0.1 mL N2O-N m-2 day-1). Soil pore-space gas concentrations (N2O and NO) remained relatively constant across the growing season (average N2O: 0.78 µL N2O L-1 soil air; NO: 3.3 µL NO L-1 soil air, indicating a base-level of N-cycle activity, but was not directly related to surface emissions of N2O which decreased across the growing season. In addition, genetic potential for N cycle activities increased across the growing season simultaneously with stagnant/reduced N cycle activity. This reflects the difficulty in relating genetic potential to in-situ activity in field research. Conclusion It is likely that in a nutrient and carbon-poor soil, such as the semi-arid agricultural soil in this study, the microbial processes associated with N cycling are mostly limited by inorganic-N and less directly related to genetic potential at the time of sampling.

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在低碳半干旱土壤中，氮肥驱动的氮和一氧化氮生产与微生物遗传潜力脱钩

土壤中氧化亚氮(N2O)的排放对全球气候变化的贡献及其作为土壤中植物有效氮(N)损失机制的功能是一个主要问题。这在密集的农业土壤中尤其如此，氮肥的施用率很高，如美国半干旱的南部高平原。方法本研究考察了土壤N2O排放量、N2O和一氧化氮(NO)孔隙浓度、土壤化学性质、水分含量以及实施保护系统和氮素管理后5年氮素循环的遗传潜力。结果在低氮、低碳、低含水量的半干旱土壤中，大量的N2O排放(高达8 mL N2O-N m-2 day-1)与施用氮肥超过土壤的N2O还原能力直接相关。当氮肥耗尽时，N2O通量要么很低，要么不存在，要么是净负的，早在种植前施用氮肥的季节中期就观察到(-0.1 mL N2O-N m-2 day-1)。土壤孔隙空间气体浓度(N2O和NO)在整个生长季节保持相对恒定(平均N2O: 0.78µL N2O -1土壤空气;NO: 3.3µL NO L-1土壤空气，表明氮循环活动的基本水平，但与N2O的地表排放没有直接关系，N2O在整个生长季节减少。此外，氮素循环活性的遗传潜力在整个生长季节增加，同时氮素循环活性停滞或降低。这反映了在野外研究中将遗传潜力与现场活动联系起来的困难。结论在养分和碳贫乏的土壤中，如本研究的半干旱农业土壤，与N循环相关的微生物过程可能主要受到无机氮的限制，而与采样时的遗传势的直接关系较少。

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

Frontiers in soil science

CiteScore

1.90

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0.00%

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