Spatial-temporal patterns of foliar and bulk soil 15N isotopic signatures across a heterogeneous landscape: Linkages to soil N status, nitrate leaching, and N2O fluxes

IF 9.8 1区 农林科学 Q1 SOIL SCIENCE
Elizabeth Gachibu Wangari , Ricky Mwangada Mwanake , Tobias Houska , David Kraus , Hanna-Marie Kikowatz , Benjamin Wolf , Gretchen M. Gettel , Lutz Breuer , Per Ambus , Ralf Kiese , Klaus Butterbach-Bahl
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引用次数: 0

Abstract

The natural abundance of plant and bulk soil 15N isotopic signatures provides valuable insights into the magnitude of nitrogen cycling and loss processes within terrestrial ecosystems. However, 15N isotopic signatures are highly variable in space due to natural and anthropogenic factors affecting N cycling processes and losses. To date, most studies on foliar and bulk soil 15N isotopic signatures have focused on N-limited forest ecosystems at relatively large spatial scales, while similar studies in N-enriched ecosystems at finer spatial scales are lacking. To address this gap and evaluate links between soil 15N isotopic signatures and ecosystem N cycling and loss processes (plant N uptake, N leaching, and gaseous loss), this study quantified foliar and bulk soil 15N isotopic signatures, soil physicochemical parameters, gaseous (N2O), and hydrological (NO3) N losses at 80 sites distributed across a heterogeneous landscape (∼5.8 km2). To account for the spatial-temporal heterogeneity, the measurements were performed in four campaigns (March, June, September 2022, and March 2023) at sites that considered different land uses, soil types, and topography. Results indicated that foliar and bulk soil 15N isotopic signatures were significantly (P < 0.05) more enriched in arable and grassland ecosystems than forests, suggesting a more open N cycle with significant N cycling and losses due to higher N inputs from fertilizers. Similar to soil inorganic N, N2O fluxes, and NO3 leaching rates, landscape-scale foliar and soil 15N isotopic signatures varied widely spatially, particularly at grassland and arable land (−3 to 9.0‰), with bivariate and multivariate analyses also showing significant relationships between landscape-scale soil 15N isotopic signatures and the aforementioned parameters (r2: 0.29 to 0.82). Based on these relationships, our findings suggested that foliar and bulk 15N isotopic signatures may capture fine-scale areas with persistently high and low environmental N losses (N2O fluxes and NO3 leaching) within a heterogeneous landscape.
异质地貌中叶面和大体积土壤 15N 同位素特征的时空模式:与土壤氮状况、硝酸盐沥滤和一氧化二氮通量的联系
植物和大体积土壤 15N 同位素特征的自然丰度为了解陆地生态系统中氮循环和损失过程的规模提供了宝贵的信息。然而,由于影响氮循环过程和损失的自然和人为因素,15N 同位素特征在空间上变化很大。迄今为止,有关叶面和土壤中 15N 同位素特征的大多数研究都集中在空间尺度相对较大的限氮森林生态系统中,而对空间尺度较小的富氮生态系统则缺乏类似的研究。为了填补这一空白,并评估土壤 15N 同位素特征与生态系统氮循环和流失过程(植物氮吸收、氮沥滤和气态流失)之间的联系,本研究在分布于异质景观(∼5.8 平方公里)的 80 个地点量化了叶面和块状土壤 15N 同位素特征、土壤理化参数、气态(N2O)和水文(NO3)氮流失。为了考虑时空异质性,在考虑了不同土地利用、土壤类型和地形的地点,分四次(2022 年 3 月、6 月、9 月和 2023 年 3 月)进行了测量。结果表明,与森林相比,耕地和草地生态系统的叶片和土壤15N同位素特征明显更富集(P <0.05),这表明氮循环更开放,由于肥料的氮输入较多,氮循环和损失显著。与土壤无机氮、一氧化二氮通量和三氧化二氮淋失率类似,景观尺度叶片和土壤 15N 同位素特征的空间差异也很大,尤其是在草地和耕地(-3 至 9.0‰),二元和多元分析也表明景观尺度土壤 15N 同位素特征与上述参数之间存在显著关系(r2:0.29 至 0.82)。基于这些关系,我们的研究结果表明,叶面和体表 15N 同位素特征可以捕捉到异质景观中环境氮损失(N2O 通量和 NO3 沥滤)持续较高和较低的精细尺度区域。
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来源期刊
Soil Biology & Biochemistry
Soil Biology & Biochemistry 农林科学-土壤科学
CiteScore
16.90
自引率
9.30%
发文量
312
审稿时长
49 days
期刊介绍: Soil Biology & Biochemistry publishes original research articles of international significance focusing on biological processes in soil and their applications to soil and environmental quality. Major topics include the ecology and biochemical processes of soil organisms, their effects on the environment, and interactions with plants. The journal also welcomes state-of-the-art reviews and discussions on contemporary research in soil biology and biochemistry.
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