西伯利亚西部南针叶林草原生态系统温室气体排放与汇：2023年观测对土壤通量分量贡献的估算

IF 0.9 Q4 OPTICS

Atmospheric and Oceanic Optics Pub Date : 2025-03-04 DOI:10.1134/S1024856024701124

M. Yu. Arshinov, B. D. Belan, D. K. Davydov, A. V. Kozlov, A. V. Fofonov

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引用次数: 0

摘要

全球气候的现代变化伴随着空气和土壤温度的上升。它们是如何影响土壤呼吸的？我们应该期待温室气体排放的变化吗？不研究土壤-空气气体交换就不能回答这些问题。在这项工作中，我们分析了2023年在Fonovaya天文台测量的土壤-空气界面上的温室气体通量，使用三个室，透明室和不透明室在有植被的土壤区，透明室在没有植被的土壤区。在整个生长季节，CO2和CH4的汇是稳定的。相反，对于二氧化碳，观测到微弱的正通量。从5月到8月中旬，大气中出现了稳定的N2O汇；6月和7月达到- 600 mg m - 2 h - 1；甲烷通量（汇）达到−0.08 mg m−2 h−1。在±0.02 mg m−2 h−1范围内，氧化亚氮通量随日平均值波动在零附近。对于CO2，植被呼吸增加与土壤温度呈非线性正相关。3个室的甲烷通量均与温度呈线性关系，即土壤温度的升高增强了CH4的吸收。在两个透明室（有植被和没有植被）中，N2O通量对土壤温度的正依赖性非常弱。土壤CO2通量的贡献估算表明，夜间微生物呼吸对草地生态系统呼吸总量的贡献在46.7% ~ 77.9%之间。土壤通过与植物无关的甲烷氧化菌的扩散和氧化吸收的甲烷的日平均份额在5.3 ~ 48.3%之间；白天变小，晚上增大。无植被土壤对N2O总通量的贡献可达92.3%。研究结果扩大了人们对气候变化条件下土壤-空气气体交换的认识。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Emission and Sink of Greenhouse Gases in the Grassland Ecosystem of Southern Taiga of Western Siberia: Estimates of the Contribution of Soil Flux Component from Observations of 2023

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Emission and Sink of Greenhouse Gases in the Grassland Ecosystem of Southern Taiga of Western Siberia: Estimates of the Contribution of Soil Flux Component from Observations of 2023

Modern changes in the global climate are accompanied by rising air and soil temperatures. How do they affect soil respiration and should we expect a change in greenhouse gas emissions? These questions cannot be answered without studying the soil–air gas exchange. In this work, we analyze greenhouse gas fluxes at the soil–air interface measured at the Fonovaya Observatory in 2023 with the use of three chambers, transparent and opaque chambers on soil areas with vegetation and a transparent chamber on soil without vegetation. A stable CO₂ and CH₄ sink throughout the growing season is shown. For carbon dioxide, on the contrary, a weak positive flux was observed. A steady sink of N₂O from the atmosphere occurred from May to mid-August; its value attained −600 mg m⁻² h⁻¹ in June and July; the methane flux (sink) attained −0.08 mg m⁻² h⁻¹. The nitrous oxide flux fluctuated about zero with the daily average within ± 0.02 mg m⁻² h⁻¹. For CO₂, a nonlinear positive relationship between the increase in vegetation respiration and soil temperature is revealed. Linear temperature dependence is found for methane fluxes in all three chambers, that is, an increase in soil temperature enhances CH₄ absorption. N₂O fluxes show very weak positive dependence on the soil temperature in both transparent chambers (with and without vegetation). The estimates of the contribution of CO₂ fluxes from the soil show that microbial respiration can contribute from 46.7 to 77.9% to the total grassland ecosystem respiration during nighttime. The daily average share of methane absorption by soil due to diffusion and oxidation by methanotrophs not associated with plants varies from 5.3 to 48.3%; it becomes smaller during the daytime and increases at night. The contribution of soil without vegetation to the total N₂O flux can attain 92.3%. The results expand knowledge about the soil–air gas exchange under changing climate conditions.

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来源期刊

Atmospheric and Oceanic Optics OPTICS-

CiteScore

2.40

自引率

42.90%

发文量

期刊介绍： Atmospheric and Oceanic Optics is an international peer reviewed journal that presents experimental and theoretical articles relevant to a wide range of problems of atmospheric and oceanic optics, ecology, and climate. The journal coverage includes: scattering and transfer of optical waves, spectroscopy of atmospheric gases, turbulent and nonlinear optical phenomena, adaptive optics, remote (ground-based, airborne, and spaceborne) sensing of the atmosphere and the surface, methods for solving of inverse problems, new equipment for optical investigations, development of computer programs and databases for optical studies. Thematic issues are devoted to the studies of atmospheric ozone, adaptive, nonlinear, and coherent optics, regional climate and environmental monitoring, and other subjects.