长白山阔叶红松林物种多样性格局及其尺度效应

doi:10.11707/j.1001-7488.LYKX20240267

Abstract

Abstract:

Objective: This paper explores the pattern of species diversity and its scale effects in the Changbai Mountain broad-leaved Korean pine forest based on the individual species-area relationship (ISAR) model. The objective is to gain a deeper understanding of the community structure and the mechanisms maintaining species diversity in broad-leaved Korean pine forests, and to provide a scientific basis for biodiversity conservation and forest management. Method: This study utilized vegetation survey data from a 40-hectare fixed monitoring plot of a broad-leaved Korean pine forest and employed the ISAR model to analyze the impact of target tree species on neighborhood species richness at scales of 0?50 m. The significance of these effects was tested using homogeneous and heterogeneous Poisson?s null models. Furthermore, all tree individuals were categorized by diameter at breast height (DBH) into small-diameter class (5 cm≤DBH<20 cm), medium-diameter class (20cm≤ DBH<40 cm), and large-diameter class (DBH≥40 cm). The impact of individuals of different diameter classes on neighborhood species richness was analyzed in detail, with significance tested using the heterogeneous Poisson?s null model. Result: 1) The species diversity in the neighborhoods of dominant tree species is relatively low. 2) Habitat filtering is not significant at the scale of 0?10 m but significantly affects community species diversity structure at the scale of 11?50 m. 3) Within the scale range of 0?30 m, different tree species exhibit different patterns at varying research scales. At the scale of 31?50 m, most tree species predominantly act as diversity neutral species. 4) Individuals of large, medium, and small diameter classes promote neighborhood species diversity at the scale of 0?10 m, with the small-diameter class having an effect extending up to 14 m. At the scale of 21?50 m, small and medium-diameter individuals mainly exhibit facilitative effects, while large-diameter individuals predominantly show neutral effects. 5) The diversity structure of species within different diameter classes differs at the scale of 0?20 m, influenced by diameter class. However, at the scale of 21?50 m, no differences are observed, with neutral species dominating across all diameter classes. 6) At the scale of 0?10 m, the asymmetric competitive effect of larger-diameter individuals on species within smaller-diameter in the neighborhood is not significant. Asymmetric competition becomes evident at the scale of 14?20 m, with the effect becoming more pronounced as the diameter difference increases. Conclusion: The species diversity pattern of the Changbai Mountain broad-leaved Korean pine forest community is jointly influenced by habitat filtering, tree species characteristics, diameter structure, and interspecific competition, exhibiting significant scale effects. In forest management, it is important to consider ecological processes at different scales, rationally configure tree species and diameter structures, promote species niche differentiation, and reduce asymmetric competition in order to enhance forest biodiversity and resource utilization efficiency.

Key words: individual species-area relationship, habitat filtering, diameter class effect, species diversity

CLC Number:

S718.54

Xiaoyu Wu,Xiuhai Zhao. Patterns of Species Diversity and Itʼs Scale Effects in the Broad-Leaved Korean Pine Forests of Changbai Mountain[J]. Scientia Silvae Sinicae, 2025, 61(2): 40-49.

Figures/Tables 8

Table 1

Fig.1

Fig.2

Table 2

Table 3

Fig.3

Fig.4

Fig.5

References 0

	陈贝贝, 匡文浓, 姜　俊, 等. 长白山次生杨桦林优势更新幼苗空间分布及环境解释. 生态学报, 2021, 41 (11): 1- 7.
	Chen B B, Kuang W N, Jiang J, et al. Spatial distribution of dominant regeneration seedlings and environmental interpretations of secondary poplar-birch forest in Changbai Mountains, China. Acta Ecologica Sinica, 2021, 41 (11): 1- 7.
	陈　磊, 米湘成, 马克平. 生态位分化与森林群落物种多样性维持研究展望. 生命科学, 2014, 26 (2): 112- 117.
	Chen L, Mi X C, Ma K P. Niche differentiation and its consequence on biodiversity maintenance in forest communities. Chinese Bulletin of Life Sciences, 2014, 26 (2): 112- 117.
	陈仁飞, 姬明飞, 关佳威, 等. 植物对称性竞争与非对称性竞争研究进展及展望. 植物生态学报, 2015, 39 (5): 530- 540. doi: 10.17521/cjpe.2015.0051
	Chen R F, Ji M F, Guan J W, et al. Advances and prospects in plant symmetric and asymmetric competition. Chinese Journal of Plant Ecology, 2015, 39 (5): 530- 540. doi: 10.17521/cjpe.2015.0051
	范春楠, 张永鑫, 丁　易, 等. 吉林露水河阔叶红松林乔木植物群落结构与多样性. 北华大学学报(自然科学版), 2021, 22 (4): 443- 448.
	Fan C N, Zhang Y X, Ding Y, et al. Structure and diversity of Arbor plant community in broad-leaved Korean pine forest in Lushuihe town, Jilin Province. Journal of Beihua University (Natural Science), 2021, 22 (4): 443- 448.
	范春雨, 元正龙, 赵秀海. 吉林蛟河近熟林树种多样性格局尺度依赖性分析. 北京林业大学学报, 2014, 36 (6): 73- 79.
	Fan C Y, Yuan Z L, Zhao X H. Scale dependence of species diversity pattern in a near-mature forest in Jiaohe of Jilin Province. Journal of Beijing Forestry University, 2014, 36 (6): 73- 79.
	宫贵权, 黄忠良, 黄建雄, 等. 鼎湖山20公顷森林样地单个物种对群落的构建. 生态环境学报, 2011, 20 (6/7): 991- 995.
	Gong Q G, Huang Z L, Huang J X, et al. How individual species structure the community in Dinghushan 20 ha forest plot. Ecology and Environmental Sciences, 2011, 20 (6/7): 991- 995.
	郭屹立, 王　斌, 向悟生, 等. 广西弄岗北热带喀斯特季节性雨林监测样地种群空间点格局分析. 生物多样性, 2015, 23 (2): 183- 191.
	Guo Y L, Wang B, Xiang W S, et al. Spatial distribution of tree species in a tropical karst seasonal rainforest in Nonggang, Guangxi, southern China. Biodiversity Science, 2015, 23 (2): 183- 191.
	韩　大, 金光泽. 地形和竞争对典型阔叶红松林不同生长阶段树木胸径生长的影响. 北京林业大学学报, 2017, 39 (1): 9- 19.
	Han D, Jin G Z. Influences of topography and competition on DBH growth in different growth stages in a typical mixed broadleaved-Korean pine forest, northeastern China. Journal of Beijing Forestry University, 2017, 39 (1): 9- 19.
	强亚琪, 范春雨, 张春雨. 长白山暗针叶林群落物种多样性维持机制. 生态学报, 2023, 43 (5): 1884- 1891.
	Qiang Y Q, Fan C Y, Zhang C Y. Species diversity maintenance mechanism of dark coniferous forests community in Changbai Mountain. Acta Ecologica Sinica, 2023, 43 (5): 1884- 1891.
	田　锴, 陈　磊, 米湘成, 等. 亚热带常绿阔叶林木本植物幼苗分布格局及其对生境过滤的响应. 科学通报, 2013, 58 (34): 3561- 3569.
	Tian K, Chen L, Mi X C, et al. The effect of habitat filtering on tree seedling distribution in a subtropical evergreen broadleaf forest in China. Chinese Science Bulletin (Chinese Version), 2013, 58 (34): 3561- 3569.
	魏彦波, 程艳霞, 李金功, 等. 植物多样性促进种支配局域空间多样性结构. 北京林业大学学报, 2014, 36 (6): 66- 72.
	Wei Y B, Cheng Y X, Li J G, et al. Plant diversity accumulators govern local spatial diversity. Journal of Beijing Forestry University, 2014, 36 (6): 66- 72.
	闫满玉, 杜晓军, 赵爱花, 等. 河南宝天曼落叶阔叶林木本植物单物种-面积关系. 生物多样性, 2015, 23 (5): 630- 640. doi: 10.17520/biods.2015031
	Yan M Y, Du X J, Zhao A H, et al. Individual woody species-area relationship in a deciduous broad-leaved forest in Baotianman, Henan Province. Biodiversity Science, 2015, 23 (5): 630- 640. doi: 10.17520/biods.2015031
	张春雨. 通过种群互作阐释森林群落多样性格局. 北京林业大学学报, 2015, 36 (6): 60- 65.
	Zhang C Y. Explaining diversity patterns of forest community through species interactions. Journal of Beijing Forestry University, 2015, 36 (6): 60- 65.
	Bhandari S K, Veneklaas E J, McCaw L, et al. Individual tree growth in jarrah (Eucalyptus marginata) forest is explained by size and distance of neighbouring trees in thinned and non-thinned plots. Forest Ecology and Management, 2021, 494, 119364. doi: 10.1016/j.foreco.2021.119364
	Brown C, Burslem D F, Illian J B, et al. Multispecies coexistence of trees in tropical forests: spatial signals of topographic niche differentiation increase with environmental heterogeneity. Proceedings Biological Sciences, 2013, 280 (1764): 20130502.
	Chesson P. Mechanisms of maintenance of species diversity. Annual Review of Ecology and Systematics, 2000, 31, 343- 366. doi: 10.1146/annurev.ecolsys.31.1.343
	Das A J, Larson A J, Lutz J A. Individual species-area relationships in temperate coniferous forests. Journal of Vegetation Science, 2018, 29 (2): 317- 324. doi: 10.1111/jvs.12611
	Harms K E, Condit R, Hubbell S P, et al. Habitat associations of trees and shrubs in a 50-ha neotropical forest plot. Journal of Ecology, 2001, 89 (6): 947- 959. doi: 10.1111/j.1365-2745.2001.00615.x
	Illian J B, Møller J, Waagepetersen R P. Hierarchical spatial point process analysis for a plant community with high biodiversity. Environmental and Ecological Statistics, 2009, 16 (3): 389- 405. doi: 10.1007/s10651-007-0070-8
	Ishii H, Azuma W, Nabeshima E. 2013. The need for a canopy perspective to understand the importance of phenotypic plasticity for promoting species coexistence and light-use complementarity in forest ecosystems. Ecological Research, 28(2): 191-198.
	Landsberg J, Sands P. Physiological ecology of forest production: principles, processes and models. Tree Physiology, 2011, 31 (6): 680- 681. doi: 10.1093/treephys/tpr062
	Li Y F, He J A, Yu S F, et al. Spatial structures of different-sized tree species in a secondary forest in the early succession stage. European Journal of Forest Research, 2020, 139 (5): 709- 719. doi: 10.1007/s10342-020-01280-w
	Li Y F, Ye S M, Luo Y H, et al. Relationship between species diversity and tree size in natural forests around the Tropic of Cancer. Journal of Forestry Research, 2023, 34 (6): 1735- 1745. doi: 10.1007/s11676-023-01616-3
	Luu T C, Binkley D, Stape J L. Neighborhood uniformity increases growth of individual Eucalyptus trees. Forest Ecology and Management, 2013, 289, 90- 97. doi: 10.1016/j.foreco.2012.09.033
	Myers J A, Chase J M, Jiménez I, et al. Beta-diversity in temperate and tropical forests reflects dissimilar mechanisms of community assembly. Ecology Letters, 2013, 16 (2): 151- 157. doi: 10.1111/ele.12021
	Murphy H T, Bradford M G. 2022. The role of big trees and abundant species in driving spatial patterns of species richness in an Australian tropical rainforest. Ecology and Evolution. 12(9): e9324.
	Nakashizuka T. Species coexistence in temperate, mixed deciduous forests. Trends in Ecology & Evolution, 2001, 16 (4): 205- 210.
	Pretzsch H. 2009. Forest dynamics, growth, and yield. Berlin: Springer Berlin Heidelberg, 1-39.
	Rayburn A P, Wiegand T. Individual species-area relationships and spatial patterns of species diversity in a Great Basin, semi-arid shrubland. Ecography, 2012, 35 (4): 341- 347. doi: 10.1111/j.1600-0587.2011.07058.x
	Sercu B K, Baeten L, van Coillie F, et al. 2017. How tree species identity and diversity affect light transmittance to the understory in mature temperate forests. Ecology and Evolution. 7(24): 10861-10870.
	Shimatani K, Kubota Y. Quantitative assessment of multispecies spatial pattern with high species diversity. Ecological Research, 2004, 19 (2): 149- 163. doi: 10.1111/j.1440-1703.2003.00619.x
	Shi W, Zhang Q D, Sui X H, et al. The effects of habitat filtering and non-habitat processes on species spatial distribution vary across life stages. American Journal of Botany, 2018, 105 (9): 1469- 1476. doi: 10.1002/ajb2.1140
	Thorpe H C, Astrup R, Trowbridge A, et al. Competition and tree crowns: a neighborhood analysis of three boreal tree species. Forest Ecology and Management, 2010, 259 (8): 1586- 1596. doi: 10.1016/j.foreco.2010.01.035
	Vleminckx J, Salazar D, Fortunel C, et al. Divergent secondary metabolites and habitat filtering both contribute to tree species coexistence in the Peruvian Amazon. Frontiers in Plant Science, 2018, 9, 836. doi: 10.3389/fpls.2018.00836
	Wang X G, Wiegand T, Swenson N G, et al. Mechanisms underlying local functional and phylogenetic beta diversity in two temperate forests. Ecology, 2015, 96 (4): 1062- 1073. doi: 10.1890/14-0392.1
	Weiner J. Asymmetric competition in plant populations. Trends in Ecology & Evolution, 1990, 5 (11): 360- 364.
	Wiegand T, Savitri Gunatilleke C V, Gunatilleke I A, et al. How individual species structure diversity in tropical forests. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104 (48): 19029- 19033.
	Zhang C, Gao L, Zhao X. Spatial structures in a secondary forest in Changbai Mountains, Northeast China. Allgemeine Forst Und Jagdzeitung, 2009, 180 (3): 45- 55.
	Zhang C Y, Jin W B, Gao L S, et al. Scale dependent structuring of spatial diversity in two temperate forest communities. Forest Ecology and Management, 2014, 316, 110- 116. doi: 10.1016/j.foreco.2013.07.025
	Zhang C Y, Zhao X H, von Gadow K. Partitioning temperate plant community structure at different scales. Acta Oecologica, 2010, 36 (3): 306- 313. doi: 10.1016/j.actao.2010.02.003
	Zhang C Y, Zhao Y Z, Zhao X H, et al. Species-habitat associations in a northern temperate forest in China. Silva Fennica, 2012, 46 (4): 501- 519.
	Zhang H, Gao Y, Zheng X, et al. Neighborhood diversity promotes tree growth in a secondary forest: the interplay of intraspecific competition, interspecific competition, and spatial scale. Plants, 2024, 13 (14): 1994. doi: 10.3390/plants13141994

目标物种 Target species	平均胸径 Mean DBH/ cm	平均树高 Mean tree hight/m	总株数 Total plant count	密度 Density/ hm^?2	地上部分生物量 Aboveground biomass/(kg?hm²)	蓄积量 Volume/ (m³?hm^?2)
蒙古栎 Quercus mongolica*	59.3	21.3	1 297	32.4	157 749.6	77.52
紫椴 Tilia amurensis*	43.5	18.83	1 924	48.1	68 368.9	72.01
红松 Pinus koraiensis*	39	19.23	2 799	70	64 799.9	91.86
水曲柳 Fraxinus mandshurica*	54.3	21.15	602	15.1	62 579.3	36.49
硕桦 Betula costata*	41.3	20.12	489	12.2	15 564.7	15.52
色木槭 Acer mono	19.3	13.26	1 731	43.3	10 751.9	11.45
假色槭 Acer pseudosieboldianum	11.3	9.29	7 019	175.5	10 515.4	10.73
春榆 Ulmus davidiana var. japonica	34.7	16.45	176	4.4	6 692.1	5.12
东北槭 Acer mandshuricum	15.4	11.37	660	16.5	2 656.1	2.57
裂叶榆 Ulmus laciniata	17.2	12.02	343	8.6	2 109.9	2.22
青楷槭 Acer tegmentosum	9.4	8.71	1 521	38	1 441.4	1.56
小楷槭 Acer komarovii	7.5	7.58	2 480	62	1 231.3	1.31
水榆花楸 Sorbus alnifolia	10.5	9.57	324	8.1	933.8	0.84
朝鲜槐 Maackia amurensis	13.2	11.32	261	6.5	802.6	0.86
花楷槭 Acer ukurunduense	7.9	7.53	517	12.9	602.6	0.49
山荆子 Malus baccata	18.6	11.98	99	2.5	600.4	0.58
髭脉槭 Acer barbinerve	6.6	6.85	849	21.2	542.2	0.52
黑樱桃 Cerasus maximowiczii	8.5	8.24	724	18.1	458.4	0.51
暴马丁香 Syringa reticulata subsp. amurensis	8.4	7.61	534	13.4	330.0	0.37
毛榛 Corylus mandshurica	11	8.17	91	2.3	269.0	0.25
稠李 Prunus padus	7.5	7.84	185	4.6	82.6	0.10
其他26个树种Other 26 tree species （n<30）	34.5	12.91	156	3.9	9 856.5	6.49
全部树种合计Total of all tree species	21.2	12.35	24 780	619.5	418 938.4	339.35

尺度区间 Scale interval	多样性抑制种数量比例Quantity ratio of diversity inhibited species	多样性中性种数量比例Quantity ratio of diversity neutral species	多样性促进种数量比例Quantity ratio of diversity promoted species
0~10 m	1.11E?01	8.11E?02	1.93E?01
11~20 m	8.11E?02	1.00E?06^***	6.02E?06^***
21~30 m	1.01E?06^***	5.20E?08^***	2.66E?08^***
31~40 m	7.30E?07^***	8.99E?09^***	1.12E?09^***
41~50 m	6.99E?06^***	6.37E?09^***	4.37E?09^***
0~50 m	1.70E?11^***	4.36E?16^***	2.22E?16^***

物种Species	尺度 Scale / m
物种Species	0~5	6~10	11~15	16~20	21~25	26~30	31~35	36~40	41~45	46~50
蒙古栎 Quercus mongolica*	a	r	r	r	n	n	n	n	n	n
紫椴 Tilia amurensis*	a	n	r	r	n	n	n	a	a	n
红松 Pinus koraiensis*	a	r	r	r	r	r	n	n	n	n
水曲柳 Fraxinus mandshurica*	r	r	n	a	a	a	a	n	n	n
硕桦 Betula costata*	a	n	n	n	n	n	n	n	n	n
色木槭 Acer mono	a	a	a	a	a	a	n	n	n	n
假色槭 Acer pseudosieboldianum	r	r	r	r	r	n	a	a	a	a
春榆 Ulmus davidiana var. japonica	r	n	n	a	a	n	n	n	n	n
东北槭 Acer mandshuricum	r	r	n	n	n	n	n	n	n	n
裂叶榆 Ulmus laciniata	r	r	n	n	n	n	n	n	n	n
青楷槭 Acer tegmentosum	r	a	a	a	a	n	n	n	n	n
小楷槭 Acer komarovii	n	n	r	r	r	r	r	n	n	n
水榆花楸 Sorbus alnifolia	a	r	r	r	r	n	n	n	n	n
朝鲜槐 Maackia amurensis	n	n	n	a	a	n	n	n	n	n
花楷槭 Acer ukurunduense	r	r	n	n	n	n	n	n	n	n
山荆子 Malus baccata	n	a	a	a	a	a	a	n	n	n
髭脉槭 Acer barbinerve	r	r	n	n	r	r	r	n	n	n
黑樱桃 Cerasus maximowiczii	a	a	n	n	n	n	n	n	n	n
暴马丁香 Syringa reticulata subsp. amurensis	r	r	n	a	a	a	a	n	n	n
毛榛 Corylus mandshurica	r	n	n	n	n	n	n	n	n	n
稠李 Prunus padus	r	r	n	n	n	n	n	n	n	n
其他26个树种Other 26 tree species （n<30）	a	a	a	a	a	a	a	n	n	n
全部树种合计Total of all tree species	a	a	a	n	n	a	a	a	a	a

[1]	Runlu Yang,Juan Wang,Chunyu Zhang. Response of Carbon Storage to Logging Disturbance in Canopy Layer of Natural Secondary Coniferous-Broadleaved Mixed Forest in Northeast China [J]. Scientia Silvae Sinicae, 2024, 60(7): 17-27.
[2]	Huan Xiao, Baiketuerhan Yeerjiang,Chunyu Zhang,Xiuhai Zhao. Relationship between Forest Layer Community Structure and Productivity of Broad-Leaved Korean Pine Forest in Changbai Mountain [J]. Scientia Silvae Sinicae, 2024, 60(3): 57-64.
[3]	Shuai Liu,Dexu Zhang,An'an Zhang,Zhe Li,Wenxing Long,Runguo Zang,Zhidong Zhang,Yuan Chen,Guang Feng,Yukai Chen. Comparison of Plant Species Diversity between the Existing Natural Forest Habitat of Hainan Gibbon’s and the Potential Habitat in Pine Forest [J]. Scientia Silvae Sinicae, 2023, 59(7): 115-127.
[4]	Lin Yang,Zhongping Xiong,Xia Liu,Yishun Qian,Rui Yang,Xiu Han,Hua Fang,Zhenghui Xu. Species Diversity of Ants in the Middle of Tianshan Mountain, Xinjiang [J]. Scientia Silvae Sinicae, 2023, 59(6): 102-111.
[5]	Shuzi Zhang,Jianting Yin,Qiwen Ren,Shubin Zhang,Xin Wang,Liandi Li,Jun Bi. Effect of Dominant Species on Diversity Pattern of Neighbor Species in Coniferous-Broadleaved Mixed Forest in Northern Hebei Mountains [J]. Scientia Silvae Sinicae, 2022, 58(4): 32-39.
[6]	Shaoxian Huang,Hongxiang Wang,Hui Peng,Yaoyi Wang,Yuanfa Li,Shaoming Ye. Analysis of Second-Order Characteristics of Tree Species Dominance in an Old Growth Forest Community in Yachang Nature Reserve [J]. Scientia Silvae Sinicae, 2022, 58(4): 128-140.
[7]	Chen Liu,Chunyu Zhang,Xiuhai Zhao. Effects of Disturtance by Thinning on Productivity Stability of Conifer-Broadleaf Mixed Forest in Jiaohe, Jilin Province [J]. Scientia Silvae Sinicae, 2022, 58(3): 1-9.
[8]	Wei Zhang,Yuyou He,Ziwu Guo,Sheping Wang,Shuanglin Chen. Characteristics of Arbor Species Community Structure and Diversity in the Succession of Out-of-Management Phyllostachys edulis Forest [J]. Scientia Silvae Sinicae, 2022, 58(12): 12-20.
[9]	Xue Dong, Yonghua Li, Zhiming Xin, Ruibing Duan, bin Yao, Yanfeng Bao, Zhengguo Zhang, Yuan Liu. Patterns of Altitudinal Distribution of Species Diversity of Desert Gobi Shrub Communities in West Hexi Corridor of China [J]. Scientia Silvae Sinicae, 2021, 57(2): 168-178.
[10]	Rongrong Pang,Jieying Peng,Yan Yan. Factors Influencing Aboveground Biomass in the Secondary Forest of Quercus aliena var. acutiserrata in Taibai Mountain [J]. Scientia Silvae Sinicae, 2021, 57(10): 157-165.
[11]	Zongda Hu,Shirong Liu,Xingliang Liu,Mingxia Luo,Jing Hu,Yafei Li,Hao Yu,Dinghua Ou,Deyong Wu. Characterization of Soil Organic Carbon and Nitrogen Components in Three Natural Secondary Forests in Subalpine Regions of Western Sichuan, China [J]. Scientia Silvae Sinicae, 2020, 56(11): 1-11.
[12]	Lin Li,Shiguang Wei,Jiangming Ma,Wanhui Ye,Juyu Lian. Relative Effects of Habitat Heterogeneity and Dispersal Limitation on Species Diversity Maintenance in South Subtropical Evergreen Broad-Leaved Forest [J]. Scientia Silvae Sinicae, 2020, 56(10): 1-10.
[13]	Wang Wenjie, Du Hongju, Xiao Lu, Zhang Jianyu, Zhong Zhaoliang, Zhou Wei, Zhang Bo, Wang Hongyuan. Differences in Plant Composition and Forest Structure among of 3 Forest Types in Liangshui National Nature Reserve [J]. Scientia Silvae Sinicae, 2019, 55(9): 166-176.
[14]	He Huaijiang, Zhang Zhonghui, Zhang Chunyu, Hao Minhui, Yao Jie, Xie Zhe, Gao Haitao, Zhao Xiuhai. Short-Term Effects of Thinning Intensity on Stand Growth and Species Diversity of Mixed Coniferous and Broad-Leaved Forest in Northeastern China [J]. Scientia Silvae Sinicae, 2019, 55(2): 1-12.
[15]	Liu Luxia, Pang Yong, Ren Haibao, Li Zengyuan. Predict Tree Species Diversity from GF-2 Satellite Data in a Subtropical Forest of China [J]. Scientia Silvae Sinicae, 2019, 55(2): 61-74.

Patterns of Species Diversity and Itʼs Scale Effects in the Broad-Leaved Korean Pine Forests of Changbai Mountain

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 0

Related Articles 15

Recommended Articles

Metrics

Comments