东北温带森林类型和发育阶段的树种多样性−地上生物量关系分异性

doi:10.11707/j.1001-7488.LYKX20250710

摘要/Abstract

摘要：

目的: 分析东北温带森林树种多样性与地上生物量的关系随森林类型和发育阶段的变化规律，揭示生态位互补效应和质量比效应在其中的作用机制，为通过优化树种组成提升东北林区次生林质量的经营实践提供科学依据。方法: 基于吉林省国家森林资源连续清查样地数据，采用线性混合效应模型，在控制气候、土壤和林分因子的基础上，分析不同森林类型（阔叶纯林、阔叶混交林和针阔混交林）和发育阶段下树种多维多样性（物种丰富度、功能多样性、谱系多样性和群落加权平均性状值）对地上生物量的影响。应用广义可加模型，揭示多样性效应随森林发育阶段的动态变化，并借助结构方程模型，解析环境因子、森林类型、发育阶段和林分密度对树种多样性与地上生物量关系的直接和间接影响。结果: 1）在3类温带森林中，物种丰富度、功能多样性和谱系多样性均对地上生物量具有显著正效应，群落加权平均性状值则表现出显著的正向或负向影响，表明生态位互补效应和质量比效应在温带森林地上生物量积累过程中共同发挥作用。2）树种多样性对地上生物量的影响随森林发育阶段变化呈现显著的森林类型依赖性。3类森林的多样性（物种丰富度、功能多样性、谱系多样性）效应均从幼龄林到成熟林阶段表现为递减趋势；阔叶纯林和针阔混交林的群落加权平均性状值效应（质量比效应）均在幼龄林、成熟林和过熟林较高，阔叶混交林的群落加权平均性状值效应随森林发育阶段变化无明显趋势。阔叶混交林和针阔混交林在成熟林和过熟林阶段的群落加权平均性状值效应均大于功能多样性效应。3）结构方程模型分析表明，环境因素（气候、土壤）、林分特征、森林类型和发育阶段共同调控森林生物多样性和地上生物量，其中森林类型和发育阶段通过调控林分密度和生物多样性间接影响地上生物量。结论: 在东北温带森林中，物种丰富度、功能多样性、谱系多样性和群落加权平均性状值均对地上生物量具有显著影响，但其影响强度因森林类型和发育阶段而异。在森林管理和生态恢复实践中，应依据具体森林类型和发育阶段分类实施精准管理：幼龄林阶段，除增加树种多样性外，还应着重培育资源获取能力强的树种；成熟林阶段，则应注重发展和保留具有长寿、保守性状的优势树种，注重目标树培育。

关键词: 树种多样性, 功能多样性, 群落加权平均性状值, 温带森林, 地上生物量, 发育阶段

Abstract:

Objective: This study aims to investigate the relationship between tree species diversity and aboveground biomass in temperate forests of northeast China with the changes of forest types and developmental stages, and to reveal the underlying mechanisms of niche complementarity and mass ratio effects, providing a scientific basis for improving the quality of secondary forests in northeast China through optimizing tree species composition. Method: Based on data from the National Forest Continuous Inventory plots in Jilin Province, linear mixed-effects models were employed to analyze the effects of multidimensional diversity (species richness, functional diversity, phylogenetic diversity) and the community-weighted mean (CWM) of functional traits on aboveground biomass across different forest types (broad-leaved forests, broad-leaved mixed forests, coniferous broad-leaved mixed forests) and developmental stages, while controlling for climatic, soil, and stand factors. Generalized additive models were used to reveal the dynamic changes in diversity effects with forest development stages, and structural equation modeling was applied to analyze the direct and indirect effects of environmental factors, forest types, developmental stages, and stand density on the relationship between tree species diversity and aboveground biomass. Result: 1) Across the three temperate forest types, species richness, functional diversity, and phylogenetic diversity all had significant positive effects on aboveground biomass. Simultaneously, the CWM, representing tree functional traits, also exhibited significant positive or negative effects. This indicates that both niche complementarity effect and the mass ratio effects operate in tandem during aboveground biomass accumulation in these temperate forests. 2) The influence of tree species diversity on aboveground biomass exhibited significant forest type dependency across different developmental stages. In the three types of forests, diversity effects (including species richness, functional diversity, and phylogenetic diversity) generally showed a decreasing trend from the young forest stage to the mature forest stage. Specifically, the community-weighted mean trait values effect (i.e., the mass ratio effect) of pure broad-leaved forests and coniferous broad-leaved mixed forests was higher in both young forests and mature/over-mature forests. In contrast, there was no significant trend in the community weighted average trait value effect of coniferous broad-leaved mixed forests across different forest developmental stages. Notably, in mature and over-mature forests, the community-weighted mean trait values effect exceeded the functional diversity effect in both broad-leaved forests and coniferous broad-leaved mixed forests. 3) Structural equation modeling indicated that environmental factors (climate, soil), stand characteristics, and forest types/developmental stages jointly regulated forest biodiversity and aboveground biomass. Specifically, forest type and developmental stage were able to indirectly influence aboveground biomass by regulating stand density and biodiversity. Conclusion: In the temperate forests of northeast China, species richness, functional diversity, phylogenetic diversity, and the community-weighted mean of functional traits all significantly influence aboveground biomass, but the strength of their effects varies with forest type and developmental stage. Therefore, forest management and ecological restoration practices should implement precise management strategies tailored to the specific forest type and its developmental stage. In young forests, in addition to increasing tree species diversity, emphasis should be placed on cultivating species with strong resource acquisition abilities. In mature forests, priority should be given to developing and retaining dominant species with long-lived and conservative traits, and attentions should be paid to the target-tree cultivation practices.

Key words: tree species diversity, functional diversity, community-weighted mean traits values, temperate forest, aboveground biomass, developmental stages

中图分类号:

S718.5

高文强,雷相东,何潇,李玉堂. 东北温带森林类型和发育阶段的树种多样性−地上生物量关系分异性[J]. 林业科学, 2026, 62(4): 55-67.

Wenqiang Gao,Xiangdong Lei,Xiao He,Yutang Li. Variability in Tree Species Diversity-Aboveground Biomass Relationship in Temperate Forest Types and Developmental Stages in Northeast China[J]. Scientia Silvae Sinicae, 2026, 62(4): 55-67.

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发育阶段 Developmental stage	样地数量 Number of plots	林分平均年龄 Stand average age/a
发育阶段 Developmental stage	样地数量 Number of plots	阔叶纯林 Broad-leaved pure forest	阔叶混交林 Broad-leaved mixed forest	针阔混交林 Coniferous and broad-leaved mixed forest
幼龄林 Young forest	220	23 (5~30)	25 (4~30)	23 (5~30)
中龄林 Middle-aged forest	459	42 (6~50)	42 (6~50)	42 (7~50)
近熟林 Near-mature forest	843	62 (6~70)	61 (6~70)	60 (5~70)
成熟林 Mature forest	525	81 (9~100)	81 (8~100)	85 (8~100)
过熟林 Over-mature forest	345	126 (16~168)	125 (16~203)	134 (22~202)

指标Index	计算公式Formula
物种丰富度Species richness (S)	S=N_s
功能多样性Functional diversity (FD)	$ \text{FD}=\dfrac{\displaystyle\sum\limits_{i=1}^n（w_i\times d_i）}{\displaystyle\sum\limits_{i=1}^nw_i} $
群落加权平均性状值 Community weighted mean trait values (CWM)	$ \mathrm{CWM}=\displaystyle\sum\limits_{i=1}^nP_i\times T_i $
谱系多样性Phylogenetic diversity (PD)	$ \text{PD}=\displaystyle \sum \limits_{i=1}^{n}{L}_{i} $

树种功能性状 Tree species functional traits	单位 Units	平均值 ± 标准差 Mean value ± standard deviation
最大树高Maximum tree height	m	23.824±11.061
叶面积Leaf area	m²	0.003±0.005
比叶面积Specific leaf area	m²·kg^?1	19.904±10.168
单位面积叶质量 Leaf dry mass per unit area	kg·m^?2	0.084±0.069
叶碳含量 Leaf carbon content	g·kg^?1	422.288±84.501
叶氮含量Leaf nitrogen content	g·kg^?1	18.914±7.422
叶磷含量Leaf phosphorus content	g·kg^?1	1.786±0.753
木材密度Wood density	g·cm^?3	0.512±0.121

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