Effects of water table position and plant functional group on plant community, aboveground production, and peat properties in a peatland mesocosm experiment (PEATcosm)

AIMS: Our objective was to assess the impacts of water table position and plant functional type on peat structure, plant community composition and aboveground plant production. METHODS: We initiated a full factorial experiment with 2 water table (WT) treatments (high and low) and 3 plant functional...

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Bibliographic Details
Published in:Plant and soil 2015-02, Vol.387 (1-2), p.277-294
Main Authors: Potvin, Lynette R, Kane, Evan S, Chimner, Rodney A, Kolka, Randall K, Lilleskov, Erik A
Format: Article
Language:English
Subjects:
Agricultural production
Biomedical and Life Sciences
botanical composition
climate
Climate change
Community composition
Ecology
Environmental aspects
Ericaceae
Flowers & plants
Life Sciences
Peat
Peatlands
Plant communities
Plant Physiology
Plant populations
Plant production
Plant Sciences
Plant-soil relationships
Plant-water relationships
Polytrichum
primary productivity
Regular Article
Soil Science & Conservation
Sphagnum
Sphagnum rubellum
Subsidence
Vegetation cover
Water
Water balance
Water table
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Summary:AIMS: Our objective was to assess the impacts of water table position and plant functional type on peat structure, plant community composition and aboveground plant production. METHODS: We initiated a full factorial experiment with 2 water table (WT) treatments (high and low) and 3 plant functional groups (PFG: sedge, Ericaceae, sedge and Ericaceae- unmanipulated) in twenty-four 1 m³intact peatland mesocosms. We measured vegetation cover, aboveground plant production, and peat subsidence to analyze interactive PFG and WT effects. RESULTS: Sphagnum rubellum cover increased under high WT, while Polytrichum cover increased with low WT and in sedge only PFGs. Sphagnum production was greatest with high WT, while vascular plant production was greater in low WT treatments. There was an interactive WT x PFG effect on Ericaceae production. Lowered WT resulted in significant peat surface change and increased subsidence. There were significant PFG and WT effects on net peat accumulation, with the lowest rates of accumulation, high and low WT, in sedge only PFGs. CONCLUSIONS: The shift in water balance leading to lowered water table position predicted with changing climate could impact plant community composition and production, and would likely result in the subsidence of peat.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-014-2301-8