Deciphering the Intricate Control of Minerals on Deep Soil Carbon Stability and Persistence in Alaskan Permafrost

IF 10.8 1区 环境科学与生态学 Q1 BIODIVERSITY CONSERVATION
Yi-Xuan Guo, Guang-Hui Yu, Shuijin Hu, Chao Liang, Andreas Kappler, Mark Torre Jorgenson, Laodong Guo, Georg Guggenberger
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Abstract

Understanding the fate of organic carbon in thawed permafrost is crucial for predicting climate feedback. While minerals and microbial necromass are known to play crucial roles in the long-term stability of organic carbon in subsoils, their exact influence on carbon persistence in Arctic permafrost remains uncertain. Our study, combining radiocarbon dating and biomarker analyses, showed that soil organic carbon in Alaskan permafrost had millennial-scale radiocarbon ages and contained only 10%–15% microbial necromass carbon, significantly lower than the global average of ~30%–60%. This ancient carbon exhibited a weak correlation with reactive minerals but a stronger correlation with mineral weathering (reactive iron to total iron ratio). Peroxidase activity displayed a high correlation coefficient (p < 10−6) with Δ14C and δ13C, indicating its strong predictive power for carbon persistence. Further, a positive correlation between peroxidase activity and polysaccharides indicates that increased peroxidase activity may promote the protection of plant residues, potentially by fostering the formation of mineral-organic associations. This protective role of mineral surfaces on biopolymers was further supported by examining 1451 synchrotron radiation infrared spectra from soil aggregates, which revealed a strong correlation between mineral OH groups and organic functional groups at the submicron scale. An incubation experiment revealed that increased moisture contents, particularly within the 0%–40% range, significantly elevated peroxidase activity, suggesting that ancient carbon in permafrost soils is vulnerable to moisture-induced destabilization. Collectively, this study offers mechanistic insights into the persistence of carbon in thawed permafrost soils, essential for refining permafrost carbon-climate feedbacks.

Abstract Image

Abstract Image

破解矿物质对阿拉斯加永久冻土层深层土壤碳稳定性和持久性的复杂控制
了解融化永冻土中有机碳的归宿对于预测气候反馈至关重要。众所周知,矿物质和微生物尸体对底土中有机碳的长期稳定性起着至关重要的作用,但它们对碳在北极永久冻土中的持久性的确切影响仍不确定。我们的研究结合了放射性碳年代测定和生物标志物分析,结果表明阿拉斯加永冻土中的土壤有机碳具有千年尺度的放射性碳年代,仅含有10%-15%的微生物尸体碳,大大低于全球约30%-60%的平均水平。这种古碳与活性矿物的相关性较弱,但与矿物风化(活性铁与总铁的比率)的相关性较强。过氧化物酶活性与 Δ14C 和 Δ13C 的相关系数很高(p < 10-6),表明过氧化物酶活性对碳的持久性有很强的预测能力。此外,过氧化物酶活性与多糖之间的正相关性表明,过氧化物酶活性的增加可能会促进矿物有机结合体的形成,从而促进对植物残留物的保护。通过研究土壤聚集体的 1451 同步辐射红外光谱,进一步证实了矿物表面对生物聚合物的保护作用。培养实验表明,水分含量的增加,尤其是在 0%-40% 的范围内,会显著提高过氧化物酶的活性,这表明永冻土中的古碳很容易受到水分引起的不稳定的影响。总之,这项研究从机理上揭示了碳在解冻的永久冻土中的持久性,这对完善永久冻土碳-气候反馈至关重要。
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来源期刊
Global Change Biology
Global Change Biology 环境科学-环境科学
CiteScore
21.50
自引率
5.20%
发文量
497
审稿时长
3.3 months
期刊介绍: Global Change Biology is an environmental change journal committed to shaping the future and addressing the world's most pressing challenges, including sustainability, climate change, environmental protection, food and water safety, and global health. Dedicated to fostering a profound understanding of the impacts of global change on biological systems and offering innovative solutions, the journal publishes a diverse range of content, including primary research articles, technical advances, research reviews, reports, opinions, perspectives, commentaries, and letters. Starting with the 2024 volume, Global Change Biology will transition to an online-only format, enhancing accessibility and contributing to the evolution of scholarly communication.
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