Elevational gradient pattern of woody plant community structure and diversity in the Qinling Mountains

doi:10.17520/biods.2024239

Abstract

Abstract:

Aims: Plant community structure and diversity patterns research is valuable for revealing the mechanism of biodiversity maintenance. The Qinling Mountains are in the transition zone at the north-south climate dividing line where the flora and fauna meet. This region is an important platform for studying the plant community structure and diversity distribution pattern in the transition zone.

Methods: According to standards of Center for Tropical Forest Science (CTFS), the Smithson Institute for Tropical Research, we establish ten 1 ha (100 m × 100 m) long-term positional monitoring plots from 800 m to 2,600 m in the middle part of the southern slope of the Qinling Mountains. We conduct community surveys using our plots with the Qinling Huangguan forest plot as the core. Initially, we analyze the elevation gradient pattern of the species composition, systematic characters, diameter class structure, spatial distribution of dominant species, and species diversity of woody plants with diameter at breast height (DBH) ≥ 1 cm.

Results: (1) We investigate a total of 208 seed plant species belonging to 50 families and 109 genera. The genera in the temperate zone account for 69.7% of the total number of genera, and the temperate zone is obvious. With increasing elevation, rare and occasional species and the composition of families, genera and species of the plant community show a unimodal pattern of increasing first and then decreasing. The dominant species of the community has obvious turnover along the elevational gradient, and the middle elevation shows the transitional nature of broad-leaved oak and coniferous fir forests. (2) The overall structure of DBH size class of all woody plant individuals generally shows an inverse “J” type. In terms of elevation, except for the bimodal distribution of woody plants at 1,600 m and 2,000 m, the rest of the elevation showed an inverted “J” shape, and the community structure is generally more stable. The spatial point pattern of dominant species at different elevations shows an aggregated distribution within the 1-10 m scale, which gradually changes to random and uniform distribution as the scale increased. With increasing elevation and removal of habitat heterogeneity, the scale range of aggregated distributions decreases and the scale range of random distributions increases. (3) In increasing elevation species richness shows a significant unimodal distribution pattern with the peak occurring between 1,200 m and 1,400 m. Changes in Shannon-Wiener diversity index, Simpson dominance index, Pielou evenness index along the elevational gradient shows a significant bimodal pattern, with both peaks occurring in 1,000-1,200 m, and 2,000-2,200 m. β diversity (Bray-Curtis index and Jaccard index) shows a unimodal trend along the elevational gradient.

Conclusion: Our study forms the foundation for the construction of long-term monitoring and a basic database of forests in the subtropical-warm temperate transition zone. This research provides a theoretical basis for the conservation of biodiversity in this transition zone and for sustainable forest management.

Key words: Qinling Mountains, community structure, spatial distribution, species diversity, elevation

Fangfang Wu, Na Liu, Chunmei He, Zuoqiang Yuan, Zhanqing Hao, Qiulong Yin. Elevational gradient pattern of woody plant community structure and diversity in the Qinling Mountains[J]. Biodiv Sci, 2024, 32(12): 24239.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2024239

https://www.biodiversity-science.net/EN/Y2024/V32/I12/24239

Figures/Tables 8

References 94

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	样地编号 Plot no.
	P1	P2	P3	P4	P5	P6	P7	P8	P9	P10
海拔 Elevation (m)	800	1,000	1,200	1,400	1,600	1,800	2,000	2,200	2,400	2,600
坡度 Slope (°)	32	23	32	29	26	24	13	24	25	16
坡向 Aspect (°)	254	210	327	267	156	190	317	307	268	186
最大胸径 Maximun diameter at breast height (cm)	56.0	57.5	78.0	71.8	66.7	55.0	62.1	58.2	53.9	58.5
平均胸径 Mean diameter at breast height (cm)	8.13	8.07	7.11	5.76	14.25	11.35	13.90	5.99	6.72	22.49
胸高断面积之和 Sum of basal area (m²)	30.28	53.54	33.37	39.61	48.83	57.95	28.74	28.83	12.75	23.48
立木密度 Stand density (ind./km²)	3,562	3,869	3,488	5,033	1,981	3,078	1,193	3,878	1,708	503
种数 No. of species (S)	39	53	80	79	57	60	46	49	39	18
属数 No. of genera	33	46	54	59	43	41	31	30	26	13
科数 No. of families	23	29	35	35	26	26	18	20	16	8
Shannon-Wiener多样性指数 Shannon-Wiener diversity index (H')	1.83	3.00	3.09	3.01	2.92	3.26	3.03	2.86	2.33	1.52
Simpson优势度指数 Simpson dominance index (D)	0.76	0.93	0.93	0.90	0.90	0.93	0.94	0.91	0.83	0.68
Pielou均匀度指数 Pielou evenness index (E)	0.49	0.76	0.70	0.69	0.72	0.80	0.79	0.73	0.64	0.52

	样地编号 Plot no.
	P1	P2	P3	P4	P5	P6	P7	P8	P9	P10
海拔 Elevation (m)	800	1,000	1,200	1,400	1,600	1,800	2,000	2,200	2,400	2,600
坡度 Slope (°)	32	23	32	29	26	24	13	24	25	16
坡向 Aspect (°)	254	210	327	267	156	190	317	307	268	186
最大胸径 Maximun diameter at breast height (cm)	56.0	57.5	78.0	71.8	66.7	55.0	62.1	58.2	53.9	58.5
平均胸径 Mean diameter at breast height (cm)	8.13	8.07	7.11	5.76	14.25	11.35	13.90	5.99	6.72	22.49
胸高断面积之和 Sum of basal area (m²)	30.28	53.54	33.37	39.61	48.83	57.95	28.74	28.83	12.75	23.48
立木密度 Stand density (ind./km²)	3,562	3,869	3,488	5,033	1,981	3,078	1,193	3,878	1,708	503
种数 No. of species (S)	39	53	80	79	57	60	46	49	39	18
属数 No. of genera	33	46	54	59	43	41	31	30	26	13
科数 No. of families	23	29	35	35	26	26	18	20	16	8
Shannon-Wiener多样性指数 Shannon-Wiener diversity index (H')	1.83	3.00	3.09	3.01	2.92	3.26	3.03	2.86	2.33	1.52
Simpson优势度指数 Simpson dominance index (D)	0.76	0.93	0.93	0.90	0.90	0.93	0.94	0.91	0.83	0.68
Pielou均匀度指数 Pielou evenness index (E)	0.49	0.76	0.70	0.69	0.72	0.80	0.79	0.73	0.64	0.52

分布区类型 Distribution area types	属数 No. of genera (%)
1. 世界分布 Cosmopolitan	2 (1.8)
2. 泛热带分布 Pantropic	8 (7.3)
3. 热带亚洲和热带美洲间断分布 Tropical Asia and Tropical American disjuncted	5 (4.6)
4. 旧世界热带分布 Old World Tropic	2 (1.8)
5. 热带亚洲至热带澳大利亚分布 Tropical Asia and Tropical Australia	3 (2.8)
6. 热带亚洲分布 Tropical Asia	6 (5.5)
热带小计 Tropical subtotal (2-6)	24 (22.1)
7. 北温带分布 North Temperate	43 (39.4)
8. 东亚和北美间断分布 East Asia and North America disjuncted	13 (11.9)
9. 旧世界温带分布 Old World Temperate	3 (2.8)
10. 温带亚洲分布 Temperate Asia	1 (0.9)
11. 地中海、西至中亚分布 Mediterranean, West Asia to Central Asia	1 (0.9)
12. 东亚分布 East Asia	15 (13.8)
温带小计 Temperate subtotal (7-12)	76 (69.7)
13. 特有分布 Endemic to China	7 (6.4)
合计 Total	109 (100.0)

分布区类型 Distribution area types	属数 No. of genera (%)
1. 世界分布 Cosmopolitan	2 (1.8)
2. 泛热带分布 Pantropic	8 (7.3)
3. 热带亚洲和热带美洲间断分布 Tropical Asia and Tropical American disjuncted	5 (4.6)
4. 旧世界热带分布 Old World Tropic	2 (1.8)
5. 热带亚洲至热带澳大利亚分布 Tropical Asia and Tropical Australia	3 (2.8)
6. 热带亚洲分布 Tropical Asia	6 (5.5)
热带小计 Tropical subtotal (2-6)	24 (22.1)
7. 北温带分布 North Temperate	43 (39.4)
8. 东亚和北美间断分布 East Asia and North America disjuncted	13 (11.9)
9. 旧世界温带分布 Old World Temperate	3 (2.8)
10. 温带亚洲分布 Temperate Asia	1 (0.9)
11. 地中海、西至中亚分布 Mediterranean, West Asia to Central Asia	1 (0.9)
12. 东亚分布 East Asia	15 (13.8)
温带小计 Temperate subtotal (7-12)	76 (69.7)
13. 特有分布 Endemic to China	7 (6.4)
合计 Total	109 (100.0)