Water management infrastructure alters plant species composition, functional diversity and soil condition in a livestock‐impaired mosaic of wetlands

Aims Wetlands are key ecosystems due to their economic, social and environmental contributions. Because of their highly productive habitats and their dependence on hydro‐meteorologic regimes, they are threatened worldwide by land use and climate change. In most wetlands, intensification of productiv...

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Bibliographic Details
Published in:Applied vegetation science 2022-10, Vol.25 (4), p.n/a
Main Authors: Aquino, Diego Sebastian, Gavier‐Pizarro, Gregorio Ignacio, Quintana, Rubén Darío
Format: Article
Language:English
Subjects:
Amplification
Aquatic ecosystems
Biodiversity
Climate change
Compacted soils
Composition
Flora
functional traits
global change
hydromorphic soils
Infrastructure
Introduced species
Invasive species
Land use
Livestock
livestock raising
Nutrient dynamics
Paraná River delta
Periodicity
Plant communities
Plant diversity
plant functional groups
Plant populations
Plant species
Plants (botany)
Polders
Redundant components
Soil compaction
Soil conditions
Soil contamination
Soil fertility
Soil quality
Species composition
Species diversity
Species richness
Structure-function relationships
Sustainability
Sustainable practices
Taxonomy
Water management
water management infrastructure
wetland plants
Wetlands
Wildlife conservation
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Summary:Aims Wetlands are key ecosystems due to their economic, social and environmental contributions. Because of their highly productive habitats and their dependence on hydro‐meteorologic regimes, they are threatened worldwide by land use and climate change. In most wetlands, intensification of productive activities has been mostly accompanied by the implementation of a water management infrastructure, disrupting water and nutrient dynamics. Our aim was to analyze whether intensification of livestock raising erodes the structure and function of plant communities, as well as the quality and fertility of soils in wetlands. Location Non‐insular portion of the Lower Delta of the Paraná River, Argentina. Methods Plant communities were characterized on the basis of their floristic composition, structural and functional diversity. Soil samples were also collected to assess soil fertility, texture and quality. Generalized mixed linear models were used to contrast these attributes across livestock management practices characterized by differing water management infrastructure (polders and channelizations) and livestock type (bovine, bubaline). Results Remarkably fertile hydromorphic soils supported a structurally rich and functionally diverse species composition. Nevertheless, most dominant populations were terrestrial, perennial, invasive species, partially adapted to conditions of temporary flooding. Polderized livestock fields exhibited not only the lowest quality, least fertile, most compacted soils, but also lower species richness and diversity, as well as the lowest values in all non‐redundant components of functional diversity. Channelized livestock fields exhibited lower species richness and taxonomic diversity as well as reduced soil quality and fertility, yet an overall increase in most non‐redundant components of functional diversity. Conclusions Promoting the loss of native flora, water management infrastructure impairs the sustainability of anthropic activities and thwarts biodiversity conservation efforts. Traditional and sustainable practices that embrace the periodicity of the flood pulse are required to preserve the taxonomic and functional diversity of plant communities, as well as the quality and fertility of soils. In the context of livestock raising intensification, fertile hydromorphic soils support structurally rich and functionally diverse plant communities. Water management infrastructures promote the disappearance and intensification of the flo
ISSN:1402-2001
1654-109X
DOI:10.1111/avsc.12698