Modeling ecosystem responses to prescribed fires in a phosphorus-enriched Everglades wetland: II. Phosphorus dynamics and community shift in response to hydrological and seasonal scenarios

► Fires could be used to manage plant composition in natural wetlands. ► Fires conducted under the low-water-depth condition are more influential. ► February fires are stronger than July fires in shifting plant community structure. Fires have been proposed as one of the important options to manage a...

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Bibliographic Details
Published in:Ecological modelling 2011-12, Vol.222 (23), p.3942-3956
Main Authors: Xu, Xiaofeng, Tian, Hanqin, Pan, Zhijian, Thomas, Cassondra R.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Biomass
botanical composition
Cladium jamaicense
Communities
community structure
Dynamics
ecosystems
Everglades
Fire
fire regime
Fires
Fundamental and applied biological sciences. Psychology
General aspects
General aspects. Techniques
Hydrology
Methods and techniques (sampling, tagging, trapping, modelling...)
Phosphorus
plant communities
Plant competition
Plants (organisms)
Surface water
Synecology
Typha domingensis
Wetland ecosystem model (WEM)
Wetlands
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Summary:► Fires could be used to manage plant composition in natural wetlands. ► Fires conducted under the low-water-depth condition are more influential. ► February fires are stronger than July fires in shifting plant community structure. Fires have been proposed as one of the important options to manage and restore degraded wetlands through changing nutrient regimes; however, their effects on nutrient dynamics and community shift have not been studied sufficiently. In this study, wetland ecosystem model (WEM) was enhanced by incorporating plant competition, and applied to a moderately phosphorus-enriched area in the Everglades with a mixed cattail ( Typha domingensis) and sawgrass ( Cladium jamaicense) community. The WEM model was first validated by comparing simulated results against field observations, and applied to evaluate the effects of multiple surface fires on phosphorus (P) dynamics and the structure of a mixed cattail and sawgrass community. The simulation results indicated that a single fire could substantially alter the P dynamics in surface water for nearly two months, while multiple fires within a two-year interval, regardless of season, could cause a shift of plant community structure, expressed as a desirable increase in sawgrass and a decrease in cattail. After the successive fires, the biomass and composition of recovering plant community did not reach the pre-fire level within six years. Regardless of season, the fires conducted under the low-water-depth condition, compared with the high-water-depth condition, yielded stronger effects on P dynamics in soil, surface water, porewater, and on the plant community composition. Regardless of water depths, February fires, compared to July fires, caused a stronger shift in plant community structure expressed as a decrease in cattail biomass and an increase in sawgrass biomass. Regardless of seasons and water depths, fires caused a short-term increase and long-term decline in total phosphorus (TP) concentration in soil, surface water, and porewater. These results might suggest that the winter fires, under low-water-depth appear to be the best fire management option for accelerating recovery of a cattail-dominated wetland to a sawgrass-dominated wetland. In the proposed fire and hydrological regimes, four fires at two-year intervals generated the maximum suppressing effect on cattail, and the maximum stimulating effect on sawgrass. The results of this study support the concept that fire could be used as
ISSN:0304-3800
1872-7026
DOI:10.1016/j.ecolmodel.2011.09.003