美国大平原草地土壤对甲烷吸收的生物和物理控制

IF 2.7 3区 环境科学与生态学 Q2 ECOLOGY
Ecosphere Pub Date : 2024-09-26 DOI:10.1002/ecs2.4955
Akihiro Koyama, Nels G. Johnson, Paul Brewer, Colleen T. Webb, Joseph C. von Fischer
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引用次数: 0

摘要

草地生物群落是大气中甲烷(CH4)这一主要温室气体的重要吸收汇。由于草地所处的环境梯度不同,许多环境条件都会影响非生物因素(如进入土壤的 CH4 扩散率)和生物因素(如甲烷营养),从而决定 CH4 的时空动态,因此草地 CH4 吸收能力存在很大的不确定性。我们在分布于美国大平原的 7 个地点的 22 个田间地块调查了土壤气体扩散率与净甲烷营养体活动的相对重要性,方法是在 3 年的生长季节大约每两周进行一次测量。我们采用一种结合了气体示踪剂、腔顶空测量和数学模型的方法来量化净甲烷营养体活性和扩散率。我们还测量了每个地块的环境特征,包括充满水的孔隙空间(WFPS)、土壤温度和无机氮含量,并研究了这些特征在控制扩散率和净甲烷滋养体活性方面的相对重要性。在七个地点的大多数地块中,当 WFPS 处于地块水平的中间时,CH4 吸收率最大。我们的研究结果表明,在解释净甲烷营养体吸收 CH4 的时间变化时,净甲烷营养体活性的变化比扩散率更重要,但这两个因素在七个地点的空间变化中同样重要。只有在沙质土壤的地块中,WFPS 才是扩散率的重要预测因子。WFPS 是控制净甲烷营养体活性的最重要因素,净甲烷营养体活性对 WFPS 呈抛物线响应(向下凹),且该响应的形状在不同地点之间存在显著差异。此外,我们还发现净甲烷营养体活动峰值时的 WFPS 水平与该地点的年平均降水量密切相关。这些结果表明,当地的降水机制决定了CH4吸收率对土壤水分的独特敏感性。我们的研究结果表明,可以利用当地的土壤水分条件来预测草地的甲烷吸收率。预测未来的极端降雨和干旱可能会导致土壤水分更加多变,这可能会降低未来草地的甲烷吸收能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Biological and physical controls of methane uptake in grassland soils across the US Great Plains

Biological and physical controls of methane uptake in grassland soils across the US Great Plains

The grassland biome is an important sink for atmospheric methane (CH4), a major greenhouse gas. There is considerable uncertainty in the grassland CH4 sink capacity due to diverse environmental gradients in which grasslands occur, and many environmental conditions can affect abiotic (e.g., CH4 diffusivity into soils) and biotic (e.g., methanotrophy) factors that determine spatial and temporal CH4 dynamics. We investigated the relative importance of a soil's gas diffusivity versus net methanotroph activity in 22 field plots in seven sites distributed across the US Great Plains by making approximately biweekly measures during the growing seasons over 3 years. We quantified net methanotroph activity and diffusivity by using an approach combining a gas tracer, chamber headspace measurements, and a mathematical model. At each plot, we also measured environmental characteristics, including water-filled pore space (WFPS), soil temperature, and inorganic nitrogen contents, and examined the relative importance of these for controlling diffusivity and net methanotroph activity. At most of the plots across the seven sites, CH4 uptake rates were consistently greatest when WFPS was intermediate at the plot level. Our results show that variation in net methanotroph activity was more important than diffusivity in explaining temporal variations in net CH4 uptake, but the two factors were equally important for driving spatial variation across the seven sites. WFPS was a significant predictor for diffusivity only in plots with sandy soils. WFPS was the most important control on net methanotroph activity, with net methanotroph activity showing a parabolic response to WFPS (concave down), and the shape of this response differed significantly among sites. Moreover, we found that the WFPS level at peak net methanotroph activity was strongly correlated with the mean annual precipitation of the site. These results suggest that the local precipitation regime determines unique sensitivity of CH4 uptake rates to soil moisture. Our findings indicate that grassland CH4 uptake may be predicted using local soil water conditions. More variable soil moisture, potentially induced through predicted future extremes of rainfall and drought, could reduce grassland CH4 sink capacity in the future.

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来源期刊
Ecosphere
Ecosphere ECOLOGY-
CiteScore
4.70
自引率
3.70%
发文量
378
审稿时长
15 weeks
期刊介绍: The scope of Ecosphere is as broad as the science of ecology itself. The journal welcomes submissions from all sub-disciplines of ecological science, as well as interdisciplinary studies relating to ecology. The journal''s goal is to provide a rapid-publication, online-only, open-access alternative to ESA''s other journals, while maintaining the rigorous standards of peer review for which ESA publications are renowned.
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