臭氧胁迫下叶片与细根凋落物分解的生态化学计量特征差异

doi:10.17521/cjpe.2025.0229

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臭氧胁迫下叶片与细根凋落物分解的生态化学计量特征差异

侯霄帆, 马辰涵, 孙语倩, 高钰涵, 李品

北京林业大学林木资源高效生产全国重点实验室，森林培育与保护教育部重点实验室，干旱半干旱地区森林培育及生态系统研究国家林草局重点实验室, 北京 100083 中国

收稿日期:2025-06-18 修回日期:2025-10-28
基金资助:
国家自然科学基金(32271673); 北京林业大学5-5工程研究创新团队项目(BLRC2023B06)

Differential ecological stoichiometry of leaf and fine root litter decomposition under ozone stress

HOU Xiaofan, MA Chenhan, SUN Yuqian, GAO Yuhan, LI Pin

State Key Laboratory of Efficient Production of Forest Resources、The Key Laboratory for Silviculture and Conservation of Ministry of Education, Key Laboratory for Silviculture and Forest Ecosystem of State Forestry and Grassland Administration, Beijing forestry university 100083, China

Received:2025-06-18 Revised:2025-10-28
Supported by:
Supported by the National Natural Science Foundation of China(32271673); and the 5·5 Engineering Research & Innovation Team Project of Beijing Forestry University(BLRC2023B06); the National Natural Science Foundation of China(32271673); the 5·5 Engineering Research & Innovation Team Project of Beijing Forestry University(No: BLRC2023B06)

摘要/Abstract

摘要： 大气臭氧(O₃)浓度升高显著影响植物元素分配，进而调控凋落物分解过程，但叶片与细根凋落物的生态化学计量特征如何响应O₃胁迫仍不清楚。本研究旨在揭示O₃升高对凋落叶与细根分解过程中碳(C)、氮(N)、磷(P)计量特征的影响及其调控机制。依托北京延庆O₃-FACE平台，以栾树(Koelreuteria paniculata)和茶树(Camellia sinensis)为研究对象，设置环境空气(NF)和加O₃处理(NF60，环境空气+60 ppb O₃)，开展为期12个月的凋落物分解实验，测定不同分解阶段(T0、T1、T3、T12)凋落物C、N、P含量及其计量比(C/N、C/P、N/P)的动态变化。O3处理显著改变了凋落物初始化学计量结构及分解残留特征。NF60处理下，栾树叶片初始C/N升高7.6%，N/P下降17.7%，分解12个月后残留率增加10.3%；茶树细根P含量上升11.1%，C/P下降14.5%，表现出更强的P重分配能力。凋落物残留率与C/N、C/P、N/P显著相关(P < 0.05)。分解过程中，栾树和茶树叶片N/P比分别升高43.6%–68.0%和52.9%–59.3%，表明分解后期P限制增强，符合“生长速率假说”与“N:P阈值假说”。O3通过诱导“高C/低P”的计量结构，加剧微生物营养限制，延缓碳矿化速率，且叶片与细根响应呈现显著差异。栾树叶片分解受P限制更明显，而茶树细根通过P重分配维持较高分解效率。研究揭示了植物器官对O₃胁迫的差异化适应策略，为全球变化背景下凋落物分解的化学计量调控机制提供了新见解。

关键词: 生态化学计量, 凋落物分解, 臭氧胁迫, C/N/P, 叶片与细根

Abstract: Aims Elevated atmospheric ozone (O₃) concentrations significantly affect plant nutrient allocation, thereby regulating litter decomposition. However, the stoichiometric responses of leaf and fine root litters to O₃ stress remain unclear. This study aimed to investigate how elevated O₃ influences the dynamics and regulatory mechanisms of carbon (C), nitrogen (N), and phosphorus (P) stoichiometry during the decomposition of leaf and fine root litter. Methods A 12-month decomposition experiment was conducted using Koelreuteria paniculata and Camellia sinensis at the O₃-FACE platform in Yanqing, Beijing. Two O₃ treatments were applied: ambient air (NF) and elevated O₃ (NF60, ambient air + 60 ppb O₃). At four decomposition stages (T0, T1, T3, and T12), we measured litter C, N, and P concentrations and stoichiometric ratios (C/N, C/P, N/P). Important findings Elevated O₃ significantly altered the initial stoichiometric structure and residual characteristics of the litter. Under NF60, the initial C/N ratio of K. paniculata leaves increased by 7.6%, while N/P decreased by 17.7%, leading to a 10.3% increase in residue mass after 12 months. For C. sinensis fine roots, P concentration increased by 11.1% and C/P decreased by 14.5%, indicating enhanced P redistribution. Litter residue was significantly correlated with C/N, C/P, and N/P ratios (P < 0.05). During decomposition, the N/P ratio in K. paniculata and C. sinensis leaves increased by 43.6%–68.0% and 52.9%–59.3%, respectively, suggesting strengthened phosphorus limitation in later stages, consistent with the “Growth Rate Hypothesis” and the “N:P Threshold Hypothesis.” Elevated O₃ induces a “high-C/low-P” stoichiometric pattern, exacerbating microbial nutrient limitation and slowing carbon mineralization. Leaves and fine roots exhibit contrasting responses: K. paniculata leaves are more constrained by P availability, while C. sinensis fine roots maintain higher decomposition efficiency through enhanced P redistribution. These findings highlight organ-specific adaptive strategies to O₃ stress and provide novel insights into stoichiometric regulation of litter decomposition under global change.

Key words: Ecological stoichiometry, Litter decomposition, Ozone stress, C/N/P, Leaves and fine roots

侯霄帆, 马辰涵, 孙语倩, 高钰涵, 李品. 臭氧胁迫下叶片与细根凋落物分解的生态化学计量特征差异. . DOI: 10.17521/cjpe.2025.0229

HOU Xiaofan, MA Chenhan, SUN Yuqian, GAO Yuhan, LI Pin. Differential ecological stoichiometry of leaf and fine root litter decomposition under ozone stress. Chinese Journal of Plant Ecology. DOI: 10.17521/cjpe.2025.0229

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2025.0229

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