Effects of tending on the functional traits and functional diversity of woody plants in a secondary tropical lowland rain forest

doi:10.17520/biods.2014174

Abstract

Abstract:

Secondary forests occupy a large and growing proportion of tropical forest coverage. Combined with the rapid decrease in primary forests, this expansion leads to increasing importance of secondary forests for biodiversity conservation and maintenance of regional ecological resources. However, in many instances the function and productivity of secondary forests are relatively low compared with old growth forests. Therefore, it may prove important to enhance the recovery rate and related ecosystem services of these forests through forest tending practices. Here, we explored the effects of tending measures on the functional traits and functional diversity of woody plants in a secondary tropical lowland rain forest in Bawangling forest region on Hainan Island. We conducted a tending practice in 60 plots (50 m × 50 m) in 2012. We logged trees which hindered the growth of the target species in 30 plots and the others were control. Then we analyzed the impact of tending on community functional traits and functional diversity with ANOVA. Our results showed that specific leaf area, leaf dry matter content, leaf nitrogen content and leaf potassium content significantly decreased at the community level with tending, but woody density and the maximum potential height significantly increased. Leaf chlorophyll content, leaf phosphorus content did not change significantly after tending. Functional richness decreased significantly, and functional evenness and functional divergence significantly increased, while functional dispersion did not change significantly after tending. Our results point to the various ways in which tending can change the trajectory of a secondary forest as it succeeds towards an old growth forest. .

Key words: succession, functional key species, functional diversity, forest recovery

Xinghui Lu, Runguo Zang, Yi Ding, Jihong Huang, Xiusen Yang, Yadong Zhou. Effects of tending on the functional traits and functional diversity of woody plants in a secondary tropical lowland rain forest[J]. Biodiv Sci, 2015, 23(1): 79-88.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2014174

https://www.biodiversity-science.net/EN/Y2015/V23/I1/79

Figures/Tables 5

References 41

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指数 Index	计算公式 Formula	变量说明 Variables	参考文献 References
功能丰富度 Functional richness	$F{{R}_{ic}}=\frac{S{{F}_{ci}}}{{{R}_{c}}}$	SF_ci为群落i内物种所占据的生态位空间; R_c为特征c的绝对值范围 SF_ci is the niche space filled by the species within the community; R_c is the absolute range of the character.	Mason et al., 2005
功能均匀度 Functional evenness	$FEve=\frac{\sum\limits_{i=1}^{S-1}{min(PEWi\frac{1}{S-1})-\frac{1}{S-1}}}{1-\frac{1}{S-1}}$	S为物种丰富度; PEW_i为物种i的局部加权均匀度 S is the number of species; PEW_iis the partial weighted evenness of species i.	Villéger et al., 2008
功能分离度 Functional divergence	$F{{D}_{iv}}=\frac{2}{\pi }arctan{{[5\times \sum\limits_{i=1}^{N}{[(ln{{C}_{i}}-\overline{lnx}})}^{2}}\times {{A}_{i}}]]$	C_i为第i项功能特征的数值; A_i为第i项功能特征的相对丰富度; lnx为物种特征值自然对数的加权平均 C_i is the character value for the i^th functional character category; A_i is the proportional abundance of the i^th functional character category; lnx is the abundance-weighted mean of the natural logarithm of character values for the categories.	Mason et al., 2005
功能离散度 Functional dispersion	$F{{D}_{is}}=\frac{\sum{{{a}_{j}}{{z}_{j}}}}{\sum{{{a}_{j}}}}$	a_j为物种j的多度; z_j为物种j到加权质心的距离 a_jis the abundance of species j; z_j is the distance of species j to centroid c.	Laliberté & Legendre, 2010

指数 Index	计算公式 Formula	变量说明 Variables	参考文献 References
功能丰富度 Functional richness	$F{{R}_{ic}}=\frac{S{{F}_{ci}}}{{{R}_{c}}}$	SF_ci为群落i内物种所占据的生态位空间; R_c为特征c的绝对值范围 SF_ci is the niche space filled by the species within the community; R_c is the absolute range of the character.	Mason et al., 2005
功能均匀度 Functional evenness	$FEve=\frac{\sum\limits_{i=1}^{S-1}{min(PEWi\frac{1}{S-1})-\frac{1}{S-1}}}{1-\frac{1}{S-1}}$	S为物种丰富度; PEW_i为物种i的局部加权均匀度 S is the number of species; PEW_iis the partial weighted evenness of species i.	Villéger et al., 2008
功能分离度 Functional divergence	$F{{D}_{iv}}=\frac{2}{\pi }arctan{{[5\times \sum\limits_{i=1}^{N}{[(ln{{C}_{i}}-\overline{lnx}})}^{2}}\times {{A}_{i}}]]$	C_i为第i项功能特征的数值; A_i为第i项功能特征的相对丰富度; lnx为物种特征值自然对数的加权平均 C_i is the character value for the i^th functional character category; A_i is the proportional abundance of the i^th functional character category; lnx is the abundance-weighted mean of the natural logarithm of character values for the categories.	Mason et al., 2005
功能离散度 Functional dispersion	$F{{D}_{is}}=\frac{\sum{{{a}_{j}}{{z}_{j}}}}{\sum{{{a}_{j}}}}$	a_j为物种j的多度; z_j为物种j到加权质心的距离 a_jis the abundance of species j; z_j is the distance of species j to centroid c.	Laliberté & Legendre, 2010

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