阿根廷 Chaco-Pampean 平原土壤二氧化碳动态过程:同位素地球化学方法

IF 1.4 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
Sanci Romina, Panarello Héctor
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引用次数: 0

摘要

在气候变化的背景下,二氧化碳地表排放量的大小和空间变异性,以及涉及从土壤向大气释放二氧化碳的过程,都是与气候变化相关的问题。这项研究评估了不同土壤性质和环境条件(PL 和 PA 单位)的查科潘潘平原(阿根廷)无扰动土壤中植被、有机物和土壤气体的二氧化碳通量和 13C/12C 比率。各层土壤有机物分解的同时,总有机碳的δ13C(δ13C-TOC)值随深度增加而富集。上层土壤剖面 ~ 约 0-15 厘米处的δ13C-TOC 值与该地区的植物群落相似(~-33 至 -29‰),而地层 A 以下的δ13C-TOC 变化更大,直到 ~ -24‰。在较深地层(约 50-60 厘米),δ13C-TOC 和土壤 δ13C-CO2相似(约-24 至 26‰)。在表层,由于扩散过程的影响,δ13C-TOC 和 δ13C-CO2显示出更大的差异(直到 ~ 4‰)。PL 和 PA 单元的水平 A 层(约 0-20 厘米)含有最丰富的 δ13C-CO2 值(约 -15-17 ‰),这是因为大气中的二氧化碳渗透到了土壤空气中。来源(大气 δ13C-CO2 和土壤 CO2)之间的简单双成分混合模型证实了这一过程。从同位素角度看,二氧化碳通量反映了 C3 植物的生物降解(源)、扩散运输和二氧化碳交换(大气/土壤)。土壤含水量似乎是扩散过程和二氧化碳地表排放量(12-60 g-m-2-d-1)的决定性因素。根据充气孔隙度参数和土壤氡梯度模型估算的二氧化碳扩散系数证实了这一情况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Processes involving soil CO2 dynamic in a sector of Chaco-Pampean plain, Argentina: An isotope geochemical approach

Processes involving soil CO2 dynamic in a sector of Chaco-Pampean plain, Argentina: An isotope geochemical approach

The magnitude and spatial variability of CO2 surface emissions and processes involving CO2 released to the atmosphere from the soils are relevant issues in the context of climate change. This work evaluated CO2 fluxes and 13C/12C ratio of vegetation, organic matter, and soil gases from no disturbed soils of Chaco Pampean Plain (Argentina) with different soil properties and environmental conditions (PL and PA units). Soil organic decomposition from individual layers was accompanied by δ13C of total organic carbon (δ13C-TOC) values more enriched to depth. δ13C-TOC values in the upper soil profile ~ ca. 0–15 cm were like the plant community of this area (~−33 to −29 ‰) while δ13C-TOC varied stronger bellow horizon A, till ~ −24‰. Both δ13C-TOC and soil δ13C-CO2 were similar (~ −24 to 26 ‰) at deeper horizons (~ 50–60 cm). Toward the superficial layers, δ13C-TOC and δ13C-CO2 showed more differences (till ~ 4 ‰), due influence of the diffusion process. Horizon A layer (~ 0–20 cm) from both PL and PA units contained the most enriched δ13C-CO2 values (~ −15–17 ‰) because atmospheric CO2 permeated the soil air. A simple two-component mixing model between sources (atmospheric δ13C-CO2 and soil CO2) confirmed that process. Isotopically, CO2 fluxes reflected the biodegradation of C3 plants (source), diffusive transport, and CO2 exchange (atmosphere/soil). Soil moisture content appeared as a determining factor in the diffusion process and the magnitude of CO2 surface emissions (12–60 g·m−2·d−1). That condition was confirmed by CO2 diffusion coefficients estimated by air-filled porosity parameters and soil radon gradient model.

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来源期刊
Acta Geochimica
Acta Geochimica GEOCHEMISTRY & GEOPHYSICS-
CiteScore
2.80
自引率
6.20%
发文量
1134
期刊介绍: Acta Geochimica serves as the international forum for essential research on geochemistry, the science that uses the tools and principles of chemistry to explain the mechanisms behind major geological systems such as the Earth‘s crust, its oceans and the entire Solar System, as well as a number of processes including mantle convection, the formation of planets and the origins of granite and basalt. The journal focuses on, but is not limited to the following aspects: • Cosmochemistry • Mantle Geochemistry • Ore-deposit Geochemistry • Organic Geochemistry • Environmental Geochemistry • Computational Geochemistry • Isotope Geochemistry • NanoGeochemistry All research articles published in this journal have undergone rigorous peer review. In addition to original research articles, Acta Geochimica publishes reviews and short communications, aiming to rapidly disseminate the research results of timely interest, and comprehensive reviews of emerging topics in all the areas of geochemistry.
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