木林子大样地两个青冈属优势种的点格局对比

doi:10.11707/j.1001-7488.20181001

摘要/Abstract

摘要： [目的]基于同一生境范围内的大量数据，对比2个青冈属优势种的分布格局，分析亚热带常绿落叶阔叶混交林中，生境异质性和密度制约效应的作用机制及种间差异，为进一步揭示群落构建规则在群落物种多样性维持机制中的作用奠定基础。[方法]基于木林子国家级自然保护区15 hm²大样地，选择群落优势种群中数量最多、分布广泛、形态相似且同属的多脉青冈和小叶青冈，在剔除高度聚集的根蘖株个体后，将2个种分为小树（1 cm ≤ DBH<10 cm）、中树（10 cm ≤ DBH<20 cm）和大树（DBH ≥ 20 cm），运用点格局分析中的成对相关函数g（r）以及4个点格局零模型（完全空间随机模型、异质泊松模型、先决条件模型和随机标签模型），分析生境异质性在0~150 m尺度上和密度制约在0~30 m尺度上对树木空间格局的影响。[结果]生境异质性在r>20 m尺度上明显促进了多脉青冈和小叶青冈聚集分布，但小叶青冈在112~150 m尺度上对生境异质性的作用不敏感；多脉青冈和小叶青冈在相同发育阶段的空间格局在1~150 m尺度上关联强度g₁₂（r）≈1，主要表现为无关联或负关联，但在1 m距离内，2个树种在小树、中树阶段倾向于相互聚集，大树阶段不能共存；密度制约的自疏效应在0~30 m尺度上均未表现，距离制约仅在多脉青冈小树阶段有轻度表现，但在多脉青冈和小叶青冈的小树到中树阶段，均在0~10 m尺度表现出明显的密度制约稀疏效应；多脉青冈与小叶青冈大树均在1 m距离内对同种小树和中树表现出庇护作用，大树在1~10 m距离内导致了同种小树稀疏，此外，小树、中树的分布格局在0~30 m尺度上与同种大树多为无关联。[结论]多脉青冈和小叶青冈种群内，密度制约的自疏效应、稀疏效应和距离制约效应的作用机制基本一致，不同的是多脉青冈小树倾向于远离大树，而小叶青冈小树在小尺度上轻度聚集在大树周围。多脉青冈和小叶青冈在小尺度上能较好地共存，在中大尺度上，生境异质性是2个树种在样地中大量共存的重要基础。

关键词: 同属比较, 生境异质性, 密度制约, 稀疏效应, 自疏效应

Abstract: [Objective] Based on massive data of two dominant species of Cyclobalanopsis in the same habitat, habitat heterogeneity anddensity-dependent effectsin subtropical evergreen-deciduous broadleaved mixed forest were analyzed to reveal interspecific differences andunderlining mechanism by comparing the distribution patterns of the two species, which laid the foundation to further reveal the role of community composition in maintenance mechanism of community species diversity.[Methods] Cyclobalanopsis multinervis (CYMU) and Cyclobalanopsis myrsinifolia (CYMY) were selected due totheir enormous abundances, extensive distributions, morphological similarity and of same genus in Mulinzi National Nature Reserve with 15 hm² large dynamic forest plot. After removing highly concentrated tillering plants, the twospecies were divided into three developmental phases:small trees (1 cm ≤ DBH< 10 cm), mediumtrees (10 cm ≤ DBH< 20 cm), andlarge trees (DBH ≥ 20 cm). The effects of habitat heterogeneity at 0-150 m anddensity-dependent effectsat 0-30 m on tree spatial pattern were analyzed using pairwise correlation functions g(r) and four models in point pattern analysis (completely spatial randomness, heterogeneous Poisson, antecedent condition and random labeling).[Results] The CYMU and CYMY were significantly aggregated on the scale of r>20 m because of habitat heterogeneity, nevertheless, CYMY were insensitive to habitat heterogeneity on the scale of 112-150 m. And the correlation of spatial pattern of CYMU and CYMY in the same developmental phase was g₁₂(r)≈1 on the scale of 1-150 m, which could be characterized as no correlation or negative correlation. While, two species tended to gather mutually at the small tree and mediumtree phases within 1 m and could not coexist at big tree phase. The thinning of density-dependent effects was not detected on the 0-30 m scale but had a slight effect on CYMU at its small tree phase, however, they all showed obvious density-limiting sparse effects at 0-10 m scale at the phase of small trees to medium-trees of CYMU and CYMY. Comparing CYMU and CYMY, the distribution pattern of small trees or mediumtrees showed no association to congeneric big trees on 0-30 m scales and big trees all showed Nurse Effect to congeneric small trees and medium-trees within 1 m, Moreover, the growing of big trees led to the sparsity of the congeneric small trees within 1-10 m.[Conclusions] In the populations of CYMU and CYMY, the mechanisms of thinning density dependent, self-thinning density dependent and distance dependent were basically the same. The difference was that small trees of CYMU tended to stay away from big trees, while small trees of CYMY gathered slightly around big trees on a small scale. CYMU and CYMY could coexist wellon a small scale, and habitat heterogeneity was the important basis for widespread coexistence for the two species on medium and large scale. Our researchresults could provide guidance for community restoration, diversity protection andforest management insubtropical evergreen-deciduous broadleaved mixed forest of Mulinzi Nature Reserve.

Key words: comparison of congener, habitat heterogeneity, density-dependent effects, self-thinning, thinning

中图分类号:

S718.5

陈俊, 艾训儒, 姚兰, 陈思艺. 木林子大样地两个青冈属优势种的点格局对比[J]. 林业科学, 2018, 54(10): 1-10.

Chen Jun, Ai Xunru, Yao Lan, Chen Siyi. Point Pattern Analysis of Two Species of Cyclobalanopsis in Large Plot in Mulinzi Nature Reserve[J]. Scientia Silvae Sinicae, 2018, 54(10): 1-10.

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