Relationships between tree diversity and biomass/productivity and their influence factors in a lower subtropical evergreen broad-leaved forest

doi:10.17520/biods.2021014

Abstract

Abstract:

Aim The relationship between biodiversity and ecosystem function contribute to productivity, both directly and indirectly. Therefore, it is a critical issue of ecology. The aim of this study is to quantitatively explore the relationship between tree diversity and biomass or productivity of subtropical natural forest ecosystems in late successional stages.
Methods Based on long-term community surveys of topographies and soil nutrients from permanent forest ecosystems in the subtropical evergreen broad-leaved forest, we analyzed the relationship between tree diversity and productivity/biomass and their influencing factors. In this analysis, the correlations between tree diversity and each factor were evaluated using a Pearson correlation analysis. The single and shared effects of each factor were quantified by variance partitioning analysis (VPA). In addition, the relationships between soil nutrients and topographies and their effects on productivity and biomass were further evaluated, either directly or indirectly, through species and structural diversity by using a structural equation model (SEM).
Result Species diversity displayed a negative correlation with biomass and a positive correlation with productivity. Contrarily, structural diversity was positively correlated with biomass and negatively correlated with productivity. The effects of environment factors on tree diversity and biomass/productivity were varied. Specifically, soil moisture had a significant effect on productivity, species diversity was correlated with soil nutrients and topographies, and structural diversity was strongly related to soil nutrients. The variance partitioning analysis results indicated that the single effect of structural diversity explained the largest portion of variance in biomass (35.39%) and productivity (5.21%), followed by the shared effect of structural and species diversity on biomass (13.66%) and productivity (3.53%). Soil nutrients and topographies explained less variation in productivity and biomass. The structural equation results analysis indicated that structural diversity had a direct positive effect on biomass, and biomass had a strong direct negative effect on productivity. Structural diversity indirectly reduced productivity by increasing biomass. Soil nutrients and topographies were mainly affected by biomass, while productivity indirectly affected tree species and structural diversity.
Conclusions These results indicate that (1) species diversity had the greatest direct effect on productivity, and structural diversity had the greatest direct effect on biomass in southern subtropical evergreen broad-leaved forests; (2) species diversity explained productivity better than structural diversity, while structural diversity explained biomass accumulation better than species diversity; and (3) both species diversity and structural diversity can be affected by soil nutrients and topographies.

Key words: biomass, productivity, soil nutrients, species diversity, structural diversity, topographies

Jie Zhu, Anchi Wu, Shun Zou, Xin Xiong, Shizhong Liu, Guowei Chu, Qianmei Zhang, Juxiu Liu, Xuli Tang, Junhua Yan, Deqiang Zhang, Guoyi Zhou. Relationships between tree diversity and biomass/productivity and their influence factors in a lower subtropical evergreen broad-leaved forest[J]. Biodiv Sci, 2021, 29(11): 1435-1446.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021014

https://www.biodiversity-science.net/EN/Y2021/V29/I11/1435

Figures/Tables 5

References 64

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变量 Variables	范围 Range	平均值 Mean	标准偏差 SD
物种丰富度 Species richness (R)	6.00-21.50	12.86	3.69
Shannon-Wiener多样性指数 Shannon-Wiener diversity index (H')	1.23-2.68	2.07	0.31
Simpson多样性指数 Simpson diversity index (D)	0.62-0.91	0.82	0.06
Pielou均匀度指数 Pielou evenness index (E)	0.59-0.98	0.82	0.08
胸高断面积标准偏差 Basal area standard deviation (SD_ba)	14.83-4,696.75	333.41	678.16
胸高断面积变异系数 Basal area coefficient of variation (CV_ba)	86.49-2,069.74	486.98	371.29
胸高断面积基尼系数 Basal area Gini coefficient (GC_ba)	0.55-1.00	0.82	0.10
树高标准偏差 Height standard deviation (SD_h)	1.49-8.40	4.14	1.77
树高变异系数 Height coefficient of variation (CV_h)	28.73-147.37	79.32	30.73
树高基尼系数 Height Gini coefficient (GC_h)	0.18-0.54	0.35	0.08
坡度(南北) Slop degree (Northsouth) (S_NS) (°)	0.00-89.61	10.52	11.86
坡度(东西) Slop degree(Eastwest) (S_EW) (°)	4.72-39.00	26.79	5.78
相对高差(南北) Relative dispersion (Northsouth) (RD_NS) (m)	0.00-3.07	0.95	0.83
相对高差(东西) Relative dispersion (Eastwest) (RD_EW) (m)	0.39-4.09	2.58	0.62
相对海拔 Relative altitude (RA) (m)	4.50-66.20	33.42	15.47
土壤含水量 Water content (WC)	0.20-0.30	0.24	0.02
pH值 pH value	3.74-4.05	3.85	0.06
有机碳 Organic carbon (C) (mg/g)	18.79-42.75	26.18	4.37
全氮 Total nitrogen (TN) (mg/g)	1.61-3.62	2.14	0.33
铵态氮 Ammonium nitrogen (NH₄⁺) (mg/g)	0.00-0.01	0.01	0.00
速效磷 Available phosphorus (AP) (mg/g)	0.00-0.01	0.00	0.00
速效钾 Available potassium (AK) (mg/g)	0.08-0.23	0.12	0.03

变量 Variables	范围 Range	平均值 Mean	标准偏差 SD
物种丰富度 Species richness (R)	6.00-21.50	12.86	3.69
Shannon-Wiener多样性指数 Shannon-Wiener diversity index (H')	1.23-2.68	2.07	0.31
Simpson多样性指数 Simpson diversity index (D)	0.62-0.91	0.82	0.06
Pielou均匀度指数 Pielou evenness index (E)	0.59-0.98	0.82	0.08
胸高断面积标准偏差 Basal area standard deviation (SD_ba)	14.83-4,696.75	333.41	678.16
胸高断面积变异系数 Basal area coefficient of variation (CV_ba)	86.49-2,069.74	486.98	371.29
胸高断面积基尼系数 Basal area Gini coefficient (GC_ba)	0.55-1.00	0.82	0.10
树高标准偏差 Height standard deviation (SD_h)	1.49-8.40	4.14	1.77
树高变异系数 Height coefficient of variation (CV_h)	28.73-147.37	79.32	30.73
树高基尼系数 Height Gini coefficient (GC_h)	0.18-0.54	0.35	0.08
坡度(南北) Slop degree (Northsouth) (S_NS) (°)	0.00-89.61	10.52	11.86
坡度(东西) Slop degree(Eastwest) (S_EW) (°)	4.72-39.00	26.79	5.78
相对高差(南北) Relative dispersion (Northsouth) (RD_NS) (m)	0.00-3.07	0.95	0.83
相对高差(东西) Relative dispersion (Eastwest) (RD_EW) (m)	0.39-4.09	2.58	0.62
相对海拔 Relative altitude (RA) (m)	4.50-66.20	33.42	15.47
土壤含水量 Water content (WC)	0.20-0.30	0.24	0.02
pH值 pH value	3.74-4.05	3.85	0.06
有机碳 Organic carbon (C) (mg/g)	18.79-42.75	26.18	4.37
全氮 Total nitrogen (TN) (mg/g)	1.61-3.62	2.14	0.33
铵态氮 Ammonium nitrogen (NH₄⁺) (mg/g)	0.00-0.01	0.01	0.00
速效磷 Available phosphorus (AP) (mg/g)	0.00-0.01	0.00	0.00
速效钾 Available potassium (AK) (mg/g)	0.08-0.23	0.12	0.03

类型 Class	成分 Component	特征值 Eigenvalue	方差贡献率 Contribution rate of variance (%)	方差累积贡献率 Cumulative contribution rate of variance (%)
物种多样性 Species diversity	1	2.93	73.45	73.45
	2	1.02	25.52	98.97
	3	0.03	0.76	99.73
	4	0.01	0.27	100
结构多样性 Structural diversity	1	4.22	70.37	70.37
	2	0.93	15.54	85.91
	3	0.47	7.78	93.69
	4	0.25	4.19	97.88
	5	0.07	1.11	98.99
	6	0.06	1.01	100
地形 Topography	1	2.77	55.35	55.35
地形 Topography	2	1.49	29.77	85.12
	3	0.61	12.13	97.25
	4	0.13	2.66	99.91
	5	0.00	0.09	100
土壤养分 Soil nutrients	1	3.51	50.17	50.17
土壤养分 Soil nutrients	2	1.37	19.62	69.79
	3	0.84	11.98	81.77
	4	0.65	9.22	90.99
	5	0.42	6.05	97.04
	6	0.13	1.89	98.93
	7	0.07	1.07	100

类型 Class	成分 Component	特征值 Eigenvalue	方差贡献率 Contribution rate of variance (%)	方差累积贡献率 Cumulative contribution rate of variance (%)
物种多样性 Species diversity	1	2.93	73.45	73.45
	2	1.02	25.52	98.97
	3	0.03	0.76	99.73
	4	0.01	0.27	100
结构多样性 Structural diversity	1	4.22	70.37	70.37
	2	0.93	15.54	85.91
	3	0.47	7.78	93.69
	4	0.25	4.19	97.88
	5	0.07	1.11	98.99
	6	0.06	1.01	100
地形 Topography	1	2.77	55.35	55.35
地形 Topography	2	1.49	29.77	85.12
	3	0.61	12.13	97.25
	4	0.13	2.66	99.91
	5	0.00	0.09	100
土壤养分 Soil nutrients	1	3.51	50.17	50.17
土壤养分 Soil nutrients	2	1.37	19.62	69.79
	3	0.84	11.98	81.77
	4	0.65	9.22	90.99
	5	0.42	6.05	97.04
	6	0.13	1.89	98.93
	7	0.07	1.07	100