Hydrological gradients and functional diversity of plants drive ecosystem processes in Poyang Lake wetland

Functional trait approaches have greatly improved the mechanistic understanding of the impacts of biodiversity in ecosystem. We evaluated how hydrological gradients (i.e., soil water content and elevation) affected the taxonomic diversity, functional identity, and functional diversity and assessed h...

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Bibliographic Details
Published in:Ecohydrology 2018-06, Vol.11 (4), p.n/a
Main Authors: Fu, Hui, Lou, Qian, Dai, Taotao, Yuan, Guixiang, Huang, Zhenrong, Ge, Dabing, Zou, Dongsheng, Li, Wei, Liu, Qiaolin, Wu, Aiping, Guo, Chunjing, Zhong, Jiayou, Fang, Shaowen, Hu, Jianmin
Format: Article
Language:English
Subjects:
above‐ground biomass
Aquatic ecosystems
Biodiversity
Biomass
Communities
complementary effects
Composition
Distribution
Divergence
Dominant species
Duration
Ecological function
Elevation
Flowering
functional diversity
Functionally gradient materials
Gradients
hydrological gradients
Hydrology
Lakes
Leaves
Moisture content
Plant diversity
Plants (botany)
Poyang Lake
selection effects
Soil
Soil water
Taxonomy
Water content
Wetlands
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Summary:Functional trait approaches have greatly improved the mechanistic understanding of the impacts of biodiversity in ecosystem. We evaluated how hydrological gradients (i.e., soil water content and elevation) affected the taxonomic diversity, functional identity, and functional diversity and assessed how changes in these measures of diversity ultimately drove variations in above‐ground biomass (AGB). Results showed that a combination of hydrological gradients and functional trait composition (i.e., the community weighted means, the single‐trait functional diversity and the multiple‐trait functional diversity) better explained variations (40.8%) of AGB. No significant relationships between taxonomic diversity and AGB were observed. The dominant species became taller with thicker stem, and co‐occurring species showed greater divergent distribution of stem diameter towards higher soil water content. As elevation increased, the dominant plant had thinner leaves with later onset of flowering and longer flowering duration, and co‐occurring species showed less divergent distribution of lamina thickness and leaf dry‐mass content. Our results highlighted that the positive biodiversity–ecosystem functioning relations were largely attributed to the co‐operations of selection and complementary effects, as evidences showed that the dominant trait values (i.e., community weighted mean of shoot height) and trait diversity (i.e., functional evenness) improved biomass production of wetland plants.
ISSN:1936-0584
1936-0592
DOI:10.1002/eco.1950