东北主要树种幼树叶片功能性状对模拟氮沉降的响应

doi:10.11707/j.1001-7488.LYKX20240511

摘要/Abstract

摘要：

目的: 以东北森林10个主要树种幼树为研究对象，探讨其叶片功能性状对氮添加的响应差异，旨在阐明不同树种对氮沉降的适应策略，为该地区森林生态系统氮沉降管理提供科学依据。方法: 在吉林舒兰生物多样性控制试验样地，以东北森林常见的10个主要树种（白桦、红松、胡桃楸、怀槐、黄檗、蒙古栎、色木槭、水曲柳、紫椴和云杉）2~3年生幼树为对象，进行氮添加对叶片功能性状影响的试验。试验于2021—2022年夏天用喷施尿素(CH₄N₂O)来模拟氮沉降，共设置3个氮沉降梯度，其浓度分别为 0（CK对照）、50（LN低氮）和100 kg ·hm^?2a^?1（HN高氮）。在每年最后一次氮添加后采取叶片样本，测定8个叶片功能性状指标（叶面积、比叶面积、叶干物质含量、叶碳含量、叶氮含量、叶磷含量、叶氮磷比和叶碳氮比）并进行比较。结果: 1）植物叶片功能性状对不同氮添加处理均表现出显著响应（P<0.05），叶氮含量、比叶面积和叶磷含量在氮添加下显著增加，叶干物质含量、叶氮磷比和叶碳氮比则显著减少（P<0.05）。叶片功能性状间也存在相关性，比叶面积与叶面积和叶氮含量显著正相关（P<0.05），但与叶干物质含量显著负相关（P<0.05）。2）不同树种的植物叶片功能性状对氮添加的响应不同，例如只有白桦、红松和黄檗的叶面积对氮添加有显著响应（P<0.05），其他树种均无显著变化，但所有树种的叶磷含量都对氮添加显著响应（P<0.05）。3）不同类型的树种采取不同的生存策略。以白桦、胡桃楸为代表的阔叶树种通过增加叶氮含量和比叶面积，提升光合效率，以促进快速的生长；而针叶树种红松和云杉则生长相对缓慢，维持较高的叶干物质含量。结论: 氮添加对不同树种幼树叶片功能性状的有差异化影响，在氮添加下，该地幼树叶片资源获取型功能性状如比叶面积增加；阔叶树种通过提高叶片氮含量和比叶面积以增强资源获取能力，而针叶树种则调整叶干物质含量强化资源保守策略，从而适应氮富集环境。这些发现为理解氮沉降对森林生态系统的影响提供了重要依据，并为合理选择氮利用率较高的树种等森林管理实践提供指导。

关键词: 氮沉降, 功能性状, 叶经济谱, 变异

Abstract:

Objective: Taking the seedlings of 10 main tree species in the Northeast Forest as the research object, this study explores the response differences of leaf functional traits to nitrogen addition. The aim is to clarify the adaptation strategies of different tree species to nitrogen deposition and provide a scientific basis for nitrogen deposition management in the forest ecosystem of this region. Method: In the biodiversity control experimental plot in Shulan, Jilin, a study was conducted to investigate the effects of nitrogen addition on leaf functional traits of 2-to 3-year-old saplings from 10 major tree species commonly found in northeastern forests, namely Betula platyphylla, Pinus koraiensis, Juglans mandshurica, Maackia amurensis, Phellodendron amurense, Quercus mongolica, Acer pictum subsp. mono, Fraxinus mandshurica , Tilia amurensis, and Picea asperata. The experiment was carried out from summer 2021 to 2022, where urea (CH₄N₂O) was applied to simulate nitrogen deposition. Three nitrogen deposition gradients were established with concentrations of 0 (CK), 50 (low nitrogen), and 100 kg·hm^?2a^?1 (high nitrogen). Leaf samples were collected after the last nitrogen application each year, and eight leaf functional traits (leaf area, specific leaf area, leaf dry matter content, leaf carbon content, leaf nitrogen content, leaf phosphorus content, leaf nitrogen-to-phosphorus ratio, and leaf carbon-to-nitrogen ratio) were measured and compared. Result: 1）The leaf functional traits of plants exhibited significant responses to different nitrogen addition treatments, with leaf nitrogen content, specific leaf area, and leaf phosphorus content significantly increasing under nitrogen addition, while leaf dry matter content, leaf nitrogen-to-phosphorus ratio, and leaf carbon-to-nitrogen ratio significantly decreased. There were also correlations among leaf functional traits; specific leaf area was significantly positively correlated with leaf area and leaf nitrogen content, but negatively correlated with leaf dry matter content. 2）The response of leaf functional traits to nitrogen addition varied among different tree species. For example, only the leaf area of B. platyphylla, P. koraiensis, and P. amurense showed significant responses to nitrogen addition, while other species showed no significant changes; however, all species exhibited significant responses in leaf phosphorus content to nitrogen addition.3）Different types of tree species adopted distinct survival strategies. Broadleaf species represented by B. platyphylla and J. mandshurica increased leaf nitrogen content and specific leaf area to enhance photosynthetic efficiency for rapid growth, whereas the coniferous species P. koraiensis , and P. asperata exhibited relatively slow growth while maintaining higher leaf dry matter content. Conclusion: This study demonstrates that nitrogen addition exerts differential effects on leaf functional traits across tree species. Under nitrogen enrichment, resource-acquisition-related functional traits, such as specific leaf area , were enhanced in seedlings of the region. Broadleaf species exhibited increased leaf nitrogen content and specific leaf area to improve resource acquisition, whereas conifer species adjusted leaf dry matter content to strengthen resource conservation strategies, thereby adapting to nitrogen-rich environments. These findings provide critical insights into the impacts of nitrogen deposition on forest ecosystems and offer practical guidance for forest management, such as selecting tree species with higher nitrogen-use efficiency. The results further contribute to theoretical understanding of nitrogen deposition effects on forest ecosystems and provide a scientific basis for ecological management practices addressing nitrogen deposition.

Key words: nitrogen deposition, functional traits, leaf economics spectrum, variation

中图分类号:

白涵,郝珉辉,何怀江,张新娜,张春雨,赵秀海. 东北主要树种幼树叶片功能性状对模拟氮沉降的响应[J]. 林业科学, 2025, 61(5): 23-32.

Han Bai,Minhui Hao,Huaijiang He,Xinna Zhang,Chunyu Zhang,Xiuhai Zhao. Response of Seedling Leaf Functional Traits to Simulated Nitrogen Deposition for the Major Tree Species of Northeast China[J]. Scientia Silvae Sinicae, 2025, 61(5): 23-32.

图/表 3

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