Carbon and nitrogen addition-derived enzyme activities in topsoil but nitrogen availability in subsoil controls the response of soil organic carbon decomposition to warming.

IF 8.2 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Science of the Total Environment Pub Date : 2024-11-01 Epub Date: 2024-08-02 DOI:10.1016/j.scitotenv.2024.175261

Shaobo Yang, Xuechao Zhao, Zhaolin Sun, Liang Wang, Peng Tian, Qingkui Wang

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Abstract

Subsoil stores the majority of soil organic carbon (SOC), and plays a vital role in the global carbon cycle in terrestrial ecosystems and in regulating climate change. Response of SOC decomposition to temperature warming (TR) is a crucial parameter to predict SOC dynamics under global warming. However, it remains unknown how TR varies across the whole soil profile and responds to exogenous C and N inputs. To assess this, we designed a novel incubation system to measure SOC-derived CO₂ efflux across the whole soil column (i.e., 60 cm length), allowing manual addition of ¹³C-labeled glucose and ammonium nitrate, and incubated it under ambient or warmed temperatures (+4 °C). We found that C addition significantly increased TR in 0-20 cm, 20-40 cm and 40-60 cm by 64.3 %, 68.1 % and 57.2 %, respectively. However, the combined addition of C and N decreased TR by 11.1 % - 15.3 % compared to without anything addition (CK) in the whole soil profile. The effect of N on TR ranged from -22.8 % to -40.4 % in the whole soil profile, and was significantly lower in topsoil than in subsoil. Furthermore, sole N addition significantly promoted TR compared to CK by 79.0 % and 94.7 % in 20-40 cm and 40-60 cm subsoil, only 9.8 % in 0-20 cm topsoil. These results together suggested that TR is sensitive to increasing C availability in the whole soil profile and increasing N availability in 20-60 cm subsoil. Random forest model indicated that soil enzyme activities (explained 21.3 % of the variance) and DOC (explained 11.1 % of the variance) dominantly governed TR in topsoil, but N availability displayed a predominant control of TR in subsoil. Overall, our results suggested that increased C and N availability under climate warming scenarios could further increase the risk of carbon loss especially in subsoil with substrate deficiency, but labile C (e.g., root exudation) input under climate warming and N enrichment could reduce SOC decomposition and benefit for C sequestration by decreasing TR.

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表层土壤的碳和氮添加酶活性以及底层土壤的氮可用性控制着土壤有机碳分解对气候变暖的反应。

底土储存着大部分土壤有机碳（SOC），在陆地生态系统的全球碳循环和调节气候变化中发挥着重要作用。SOC 分解对温度升高（TR）的响应是预测全球变暖下 SOC 动态的关键参数。然而，TR 在整个土壤剖面上的变化以及对外源碳和氮输入的响应如何，仍然是一个未知数。为了评估这一问题，我们设计了一种新型培养系统，用于测量整个土壤柱（即 60 厘米长）中 SOC 衍生的二氧化碳流出量，允许手动添加 13C 标记的葡萄糖和硝酸铵，并在环境温度或升温温度（+4 °C）下进行培养。我们发现，添加 C 能明显增加 0-20 厘米、20-40 厘米和 40-60 厘米处的 TR，增幅分别为 64.3%、68.1% 和 57.2%。然而，在整个土壤剖面中，与不添加任何东西（CK）相比，C 和 N 的联合添加使 TR 降低了 11.1 % - 15.3 %。在整个土壤剖面中，氮对 TR 的影响从-22.8 % 到-40.4 % 不等，表层土壤的影响明显低于底层土壤。此外，与 CK 相比，在 20-40 厘米和 40-60 厘米的底土中，单独添加氮能显著提高 TR，分别提高 79.0 % 和 94.7 %，而在 0-20 厘米的表土中仅提高 9.8 %。这些结果共同表明，TR 对增加整个土壤剖面中的碳供应量和增加 20-60 厘米底土中的氮供应量很敏感。随机森林模型表明，土壤酶活性（解释了 21.3% 的方差）和 DOC（解释了 11.1% 的方差）对表层土壤的 TR 起主导作用，但氮的供应量对底层土壤的 TR 起主导作用。总之，我们的研究结果表明，在气候变暖的情况下，碳和氮供应量的增加可能会进一步增加碳损失的风险，尤其是在基质缺乏的底土中；但在气候变暖和氮富集的情况下，可溶性碳（如根系渗出）的输入可能会减少SOC的分解，并通过降低TR而有利于碳固存。

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

Science of the Total Environment 环境科学-环境科学

CiteScore

17.60

自引率

10.20%

发文量

8726

审稿时长

2.4 months

期刊介绍： The Science of the Total Environment is an international journal dedicated to scientific research on the environment and its interaction with humanity. It covers a wide range of disciplines and seeks to publish innovative, hypothesis-driven, and impactful research that explores the entire environment, including the atmosphere, lithosphere, hydrosphere, biosphere, and anthroposphere. The journal's updated Aims & Scope emphasizes the importance of interdisciplinary environmental research with broad impact. Priority is given to studies that advance fundamental understanding and explore the interconnectedness of multiple environmental spheres. Field studies are preferred, while laboratory experiments must demonstrate significant methodological advancements or mechanistic insights with direct relevance to the environment.