Moderate effects of distance to air-filled macropores on denitrification potentials in soils

IF 5.1 1区农林科学 Q1 SOIL SCIENCE

Biology and Fertility of Soils Pub Date : 2024-09-18 DOI:10.1007/s00374-024-01864-3

Hester van Dijk, Maik Geers-Lucas, Sina Henjes, Lena Rohe, Hans-Jörg Vogel, Marcus A. Horn, Steffen Schlüter

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Abstract

Denitrification is a major source of the greenhouse gas N₂O. As a result of spatial heterogeneity of organic carbon, oxygen and nitrate, denitrification is observed even under relatively dry conditions. However, it is unclear whether denitrification potentials of microbial communities exhibit spatial patterns relative to variations in distance to soil pores facilitating oxygen exchange and nutrient transfer. Thus, we determined genetic and process-level denitrification potentials in two contrasting soils, a cropland and a grassland, with respect to the distance to air-filled pores. An X-ray computed tomography aided sampling strategy was applied for precise sampling of soil material. Process-level and genetic denitrification potentials in both soils were spatially variable, and similar with respect to distance to macropores. In the cropland soil, a minor increase of process-level potentials with distance to pores was observed and related to changes in NO₃⁻ rather than oxygen availability. Genetic denitrification potentials after the short-term incubations revealed a certain robustness of the local community. Thus, distance to macropores has a minor impact on denitrification potentials relative to the observed spatial variability. Our findings support the notion that the impact of macropore induced changes of the environmental conditions in soil does not overrule the high spatial variability due to other controlling factors, so that the rather minor proportion of spatial heterogeneity of functional genes and activity potentials related to macropore distances in soil need not be considered explicitly in modelling denitrification.

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与充满空气的大孔隙的距离对土壤反硝化潜力的适度影响

反硝化作用是温室气体一氧化二氮的主要来源。由于有机碳、氧气和硝酸盐的空间异质性，即使在相对干燥的条件下也能观察到反硝化作用。然而，目前还不清楚微生物群落的反硝化潜力是否会随着与促进氧气交换和养分转移的土壤孔隙的距离变化而呈现空间模式。因此，我们测定了两种不同土壤（耕地和草地）中与充气孔隙距离有关的遗传和过程级反硝化潜力。采用 X 射线计算机断层扫描辅助取样策略对土壤材料进行了精确取样。这两种土壤的过程级和遗传反硝化潜力在空间上是可变的，而在与大孔隙的距离上是相似的。在耕地土壤中，随着与孔隙距离的增加，过程级反硝化潜力略有增加，这与氮氧化物的变化而不是氧气的供应有关。短期培养后的遗传反硝化潜力表明，当地群落具有一定的稳健性。因此，相对于观察到的空间变化，与大孔隙的距离对反硝化潜力的影响较小。我们的研究结果支持这样一种观点，即大孔隙引起的土壤环境条件变化的影响并不能抵消其他控制因素造成的高空间变异性，因此在建立反硝化模型时，不必明确考虑与土壤中大孔隙距离有关的功能基因和活动潜能的空间异质性所占的比例相当小。

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

Biology and Fertility of Soils 农林科学-土壤科学

CiteScore

11.80

自引率

10.80%

发文量

审稿时长

2.2 months

期刊介绍： Biology and Fertility of Soils publishes in English original papers, reviews and short communications on all fundamental and applied aspects of biology – microflora and microfauna - and fertility of soils. It offers a forum for research aimed at broadening the understanding of biological functions, processes and interactions in soils, particularly concerning the increasing demands of agriculture, deforestation and industrialization. The journal includes articles on techniques and methods that evaluate processes, biogeochemical interactions and ecological stresses, and sometimes presents special issues on relevant topics.