A Simulation Model on the Competition for Light of Meadow-forming and Canopy-forming Aquatic Macrophytes at High and Low Nutrient Availability

A simulation model has been developed that focuses on the ability of two competing submersed macrophytes, meadow-forming and canopy-forming, to maintain their biomass under different environmental conditions. Vallisneria americana (American wildcelery) serves as the example for meadow-forming plants...

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Bibliographic Details
Main Authors: Best, Elly P., Kiker, Gregory A., Boyd, William A.
Other Authors: ENGINEER RESEARCH AND DEVELOPMENT CENTER VICKSBURG MS ENVIRONMENTAL LAB
Format: Text
Language:English
Published: 2004
Subjects:
Biology
*NUTRIENTS
*AQUATIC PLANTS
NITROGEN
FRESH WATER
SUSPENDED SEDIMENTS
PHOSPHORUS
UNDERWATER LIGHT
PLANTS(BOTANY)
TEMPERATE REGIONS
SHALLOW DEPTH
MACROPHYTES
POTAMOGETON PECTINATUS
VALLISNERIA AMERICANA
Zannichellia palustris
Online Access:http://www.dtic.mil/docs/citations/ADA428026
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA428026
Description
Summary:A simulation model has been developed that focuses on the ability of two competing submersed macrophytes, meadow-forming and canopy-forming, to maintain their biomass under different environmental conditions. Vallisneria americana (American wildcelery) serves as the example for meadow-forming plants and Stuckenia pectinata (until recently known as Potamogeton pectinatus or sago pondweed) for canopy-forming plants. The model can be used to predict changes in species composition of submersed vegetation as a result of changes in the availability of resources in shallow freshwater bodies. In the model, the two plant species compete for light and exhibit different species-specific relationships between plant tissue nitrogen (N):phosphorus (P) ratio and plant biomass production. The latter species-specific relationships have not been determined in V. americana and P. pectinatus, and, therefore, for calibration of the model, the specific relationships between plant tissue N:P ratio and reduction in plant biomass production of Zannichellia palustris and Elodea canadensis were used. The latter species have habitat preferences similar to those of V. americana and P. pectinatus. Competition for light proved to be a far more important determinant of species composition than the availabilities of N and P in the sediment. Intraspecific competition for light did not occur in V. americana in a temperate climate, but it was observed at densities > 8-9 plants m-2 in a more southern climate. It occurred in P. pectinatus at plant densities >4-5 plants m-2. Coexistence of both species occurred only at V. americana:P. pectinatus plant density ratios of 28:2 to 26:4 plants m-2 in the absence of N and P limitation of growth, irrespective of climate (temperate and more southern climates tested). At density ratios higher than 28:2, V. americana excludes P. pectinatus, and at density ratios lower than 26:4, P. pectinatus excludes V. americana.

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