Biophysical Controls on Soil Carbon Cycling in a Northern Hardwood Forest

IF 3.4 2区 环境科学与生态学 Q2 ECOLOGY Ecosystems Pub Date : 2023-12-26 DOI:10.1007/s10021-023-00890-w
Patrick R. Hodgson, Madison L. Annis, Angela Hsuan Chen, Molly R. Fraser, Dan J. Lee, Aaron I. Stanton, Jason Racela, Allison L. Gill
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Abstract

Soil organic matter (SOM) is a major global carbon (C) pool vulnerable to ongoing warming, as microbial SOM decomposition and CO2 respiration are sensitive to temperature. We characterized the edaphic characteristics that explain variation in soil C concentration, cycling, and temperature sensitivity (Q10) across two sites of differing elevation, forest community composition, and mineral parent material at Hopkins Memorial Forest, Williamstown, Massachusetts, USA. We found that the upper site maintained significantly higher surface soil C concentration, despite similar litterfall inputs across sites. We found large differences in the fraction of total soil C that is protected from microbial decomposition, with enhanced physical protection in macroaggregate-rich, upper site soils. Upper site plots maintain a higher relative abundance of plants producing lignin-rich litter, which may fuel aggregate formation and SOM protection. Experimental addition of glucose, vanillin, and lignin substrates produced broadly conserved respiratory responses across sites, suggesting that microbial communities maintain similar decomposition capacity, although lignin addition induced slightly elevated respiration responses in upper relative to lower site plots. Seasonal Q10 of soil respiration was higher at the upper site and increased with soil potassium (K+) availability across plots, potentially reflecting K+ constraints on autotrophic and heterotrophic metabolic activity. Our findings suggest that variation in the extent of physical protection of soil C, particularly through macroaggregate formation, is an important mechanism for long-term soil C storage at the site. Despite enhanced SOM physical protection at the upper site, the higher temperature sensitivity of soil respiration may reduce soil C in the context of future warming.

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北方阔叶林土壤碳循环的生物物理控制因素
土壤有机质(SOM)是全球主要的碳(C)库,容易受到持续变暖的影响,因为土壤有机质的微生物分解和二氧化碳呼吸对温度很敏感。我们研究了美国马萨诸塞州威廉斯敦霍普金斯纪念森林两个不同海拔高度、森林群落组成和矿物母质的地点的土壤碳浓度、循环和温度敏感性(Q10)变化的土壤特性。我们发现,尽管不同地点的降尘量相似,但上部地点的地表土壤碳浓度明显更高。我们发现,受微生物分解保护的土壤总碳含量存在很大差异,在富含大颗粒的上部土壤中,物理保护作用更强。上部地块中产生富含木质素的枯落物的植物相对数量较多,这可能会促进聚合体的形成和对 SOM 的保护。在实验中添加葡萄糖、香兰素和木质素基质会在不同地点产生大致相同的呼吸反应,这表明微生物群落保持着相似的分解能力,尽管添加木质素会导致上部地块的呼吸反应略高于下部地块。上部地块土壤呼吸作用的季节性 Q10 值较高,并且随着各地块土壤钾(K+)供应量的增加而增加,这可能反映了 K+ 对自养和异养代谢活动的限制。我们的研究结果表明,土壤碳物理保护程度的变化,特别是通过大团聚体的形成,是该地点土壤碳长期储存的一个重要机制。尽管上部地点的 SOM 物理保护作用增强,但土壤呼吸作用对温度的敏感性较高,在未来气候变暖的情况下可能会减少土壤碳储量。
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来源期刊
Ecosystems
Ecosystems 环境科学-生态学
CiteScore
8.20
自引率
2.70%
发文量
71
审稿时长
1.7 months
期刊介绍: The study and management of ecosystems represent the most dynamic field of contemporary ecology. Ecosystem research bridges fundamental ecology and environmental ecology and environmental problem-solving, and spans boundaries of scale, discipline and perspective. Ecosystems features a distinguished team of editors-in-chief and an outstanding international editorial board, and is seen worldwide as a vital home for publishing significant research as well as editorials, mini-reviews and special features.
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