Abstract
This paper describes a study of nutrient dynamics in 12 tidal and non-tidal freshwater riverine wetlands in The Netherlands, Belgium, and Maryland (USA). The purpose of the study was to investigate the relationships between nutrient cycling processes in riverine wetlands that were geographically separated, that were dominated by different types of vegetation, and that had different hydrodynamics. We also compared restored and natural riverine wetlands. The results showed distinct differences in interstitial water chemistry between the sites in Maryland and Europe. No such regional differences were found in the soil variables, except for soil phosphorus, which was higher in The Netherlands. Soil organic matter, total nitrogen and phosphorus content, and bulk density were higher in tidal freshwater wetland soils. Forested wetland soils had higher organic matter and total nitrogen and lower bulk density and total phosphorus than soils from wetlands dominated by herbaceous species. Restored wetlands had lower soil organic matter and total soil nitrogen and phosphorus than similar types of natural riverine wetlands. There were no differences in nutrient-related process rates nor plant nutrient concentrations in tidal versus non-tidal riverine wetlands. Lower nitrogen and phosphorus concentrations in plants at the restored sites suggest that nutrient uptake by vegetation may be poorly coupled to rates of nutrient cycling during early stages of vegetation development. A principal components analysis of the data identified groupings of soil and water variables that were similar to those that had been previously identified when we applied the same methods to peatlands that were also geographically widely separated. Results of the study demonstrate that the techniques that we have been using are robust and repeatable. They are especially useful for making general comparisons of nitrogen and phosphorus cycling, when there are limitations on the number of wetland that can be sampled. The approach that we have developed may also be used to calibrate and refine nutrient cycling models that are incorporated into wetland assessment procedures.
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Literature cited
Bowden, W. B. 1984. Nitrogen and phosphorus in the sediments of a tidal, freshwater marsh in Massachusetts. Estuaries 7:108–118.
Bowden, W. B. 1986. Nitrification, nitrate reduction, and nitrogen immobilization in a tidal freshwater marsh sediment. Ecology 67: 88–99.
Brinson; M. M. (1993). A Hydrogeomorphic Classification for Wetlands. US Army Engineers Waterways Experiment Station, Vicksburg, MS, USA.
Brinson, M. M., R. D. Smith, D. F. Whigham, L. C. Lee, R. D. Rheinhardt, and W. L. Nutter. 1998. Progress in development of the hydrogeomorphic approach for assessing the functioning of wetlands. p. 393–406. In A. J. McComb and J. A. Davis (eds.) Wetlands for the Future. Gleneagles Publishing, Adelaide, Australia.
De Klein, C. A. M. and R. S. P. van Logtestijn. 1994. Denitrification in the top soil of managed grasslands in The Netherlands in relation to soil type and fertilizer level. Plant and Soil 163:33–44.
Dogterom, J., P. J. Van der Wiele, and P. H. L. Buijs. 1998. Diffuse loadings as a yet unsolved problem for receiving water bodies. p. 211–228. In P. H. Nienhuis, R. S. E. W. Leuven, and A. M. J. Ragas (eds.), New Concepts for Sustainable Management of River Basins. Backhuys Publishers, Leiden, The Netherlands.
Erisman, J. W. 1991. Acid deposition in the Netherlands. Rijksin-stituut voor Volksgezondheid en Milieuhygiëne, Bilthoven. RIVM Report nr. 723001002:1–72.
Findlay, S., K. Howe, and H. K. Austin 1990. Comparison of detritus dynamics in two tidal freshwater wetlands. Ecology 71:288–295.
Galatowitsch, S. M. and A. G. van der Valk. 1996. Vegetation and environmental conditions in recently restored wetlands in the Prairie Pothole region of the U.S.A. Vegetatio 126:89–100.
Harrison, A. F., P. M. Latter, and D. W. H. Walton. 1988. Cotton strip assay: an index of decomposition in soils. Institute of Terrestrial Ecology, Grange-over-Sands, UK.
Isermann, K. 1993. Terrestrial, continental, and global aspects of C, N, P and S emissions from agricultural ecosystems. p. 79–121. In R. Wollast and F. T. Mackenzie (eds.) Interactions of C, N. P. and S Biogeochemical Cycles and Global Change. NATO ASI series. Volume 14. Springer-Verlag. New York, NY, USA.
Jordan, T. E. and D. E. Weller. 1996. Human contribution to terrestrial nitrogen flux. BioScience 46:655–664.
Jordan, T. E., D. L. Correll, and D. E. Weller. 1997a. Relating nutrient discharges from watersheds to land use and stream flow variability. Water Resources Research 33:2579–2590.
Jordan, T. E., D. L. Correll, and D. E. Weller. 1997b. Effects of agriculture on discharges of nutrients from Coastal Plain water-sheds of Chesapeake Bay. Journal of Environmental Quality 26: 836–848.
Jordan, T. E., D. L. Correll, and D. E. Weller. 1997c. Nonpoint source discharges of nutrients from Piedmont watersheds of Chesapeake Bay. Journal of the American Water Resources Association 33:631–645.
Maltby, E. 1988. Use of cotton strip assay in wetland and upland environments—an international perspective. p. 140–156. In A. F. Harrison, P. M. Latter, and D. W. H. Walton (eds.) Cotton Strip Assay: an Index of Decomposition in Soils. Institute of Terrestrial Ecology, Grange-over-Sands, UK.
Maltby, E., D. V. Hogan, and R. J. McInnes. 1996. Functional analysis of European wetland ecosystems—Phase 1 (FAEWE). European Commission, Office for Official Publications of the European Communities. Luxembourg. EUR 16132.
Middleton, B. 1999. Wetland Restoration. Flood Pulsing and Disturbance Dynamics. John Wiley & Sons, Inc., New York, NY, USA.
Mitsch, W. J., X. Wu, R. W. Nairn, P. E. Weihe, N. Wang, R. Deal, and C. E. Boucher. 1998. Creating and restoring wetlands. A whole ecosystem experiment in self-design. BioScience 48:1019–1030.
Odum, W. E. 1988. Comparative ecology of tidal freshwater and salt marshes. Annual Review Ecology and Systematics 19:147–176.
Odum, W. E., T. J. Smith III, J. K. Hoover, and C. C. McIvor. 1984. The Ecology of Tidal Freshwater Marshes of the United States East Coast: A Community Profile, U.S. Fish and Wildlife Service, Washington, DC, USA. FWS/OBS-87/17.
Page, A. C., R. H. Miller, and D. R. Keeney. 1982. Methods of soil analyses, Part 2, Chemical and Microbiological Properties. American Society of Agronomy, Madison, WI, USA.
Patrick, Jr., W. H., D. S. Mikkelsen, and B. R. Wells. 1985. Plant nutrient behavior in flooded soil. p. 197–228. In O. P. Engelstad (ed.) Fertilizer Technology and Use. Soil Science Society of America Inc., Madison, WI, USA.
Radford, A. E., H. E. Ahles, and C. R. Bell. 1968. Manual of the Vascular flora of the Carolinas. The University of North Carolina Press, Chapel Hill, NC, USA.
Richardson, C. J. and P. E. Marshall. 1986. Processes controlling movement, storage and export of phosphorus in a fen peatland. Ecological Monographs 56:279–302.
SAS. 1985. SAS/STAT guide for personal computers. SAS Institute, Cary, NC, USA.
Simpson, R. L., R. E. Good, M. A. Leck, and D. F. Whigham. 1983. The ecology of freshwater tidal wetlands. BioScience 33:255–259.
Stauffer, A. L. and R. B. Brooks. 1997. Plant and soil responses to salvaged marsh surface and organic matter amendments at a created wetland in central Pennsylvania. Wetlands 17:90–105.
Van der Meijden, R., E. J. M. Arnold, F. Adema, E. J. Weeda, and C. L. Plate. 1984. Standaardlijst van de Nederlandse flora 1983. Rijksherbarium, Leiden, The Netherlands.
Van Dijk, G., L. van Liere, W. Admiraal, B. A. Bannink, and J. J. Cappon. 1994. Present state of the water quality of European rivers and implications for management. The Science of the Total Environment 1994:1–9.
Van Oorschot, M. M. P., E. Robbemont, M. Boerstal, M. van Strien, and M. van Kerkhoven-Schmitz. 1997. Effects of enhanced nutrient availability on plant and soil nutrient dynamics in two English riverine ecosystems. Journal of Ecology 85:167–179.
Verhoeven, J. T. A., E. Maltby, and M. B. Schmitz. 1990. Nitrogen and phosphorus mineralization in fens and bogs. Journal of Ecology 78:713–726.
Verhoeven, J. T. A., D. F. Whigham, M. van Kerkhoven, J. O’Neill, and E. Maltby. 1994. A comparative study of nutrient-related processes in geographically separated wetlands: towards a science base for functional assessment procedures. p. 91–106. In J. W. Mitsch (ed.) Global Wetlands; Old World and New. Elsevier, Amsterdam, The Netherlands.
Verhoeven, J. T. A., A. Keuter, R. van Logtestijn, M. B. van Kerkhoven, and M. Wassen. 1996. Control of local nutrient dynamics in mires by regional and climatic factors: a comparison of Dutch and Polish sites. Journal of Ecology 84:647–656.
Whigham, D. F., R. L. Simpson, R. E. Good, and F. Sickels. 1989. Decomposition and nutrient-metal dynamics of litter in freshwater tidal wetlands. p. 167–187. In R. R. Sharitz and J. W. Gibbons (eds.), Freshwater Wetlands and Wildlife. USDOE Office of Scientific and Technical Information. Oak Ridge, TN, USA. U. S. Department of Energy Symposium Series No. 61.
Wilson, R. F. and W. J. Mitsch. 1996. Functional assessment of five wetlands constructed to mitigate wetland losses in Ohio, U.S.A. Wetlands:436–451.
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Verhoeven, J.T.A., Whigham, D.F., van Logtestijn, R. et al. A comparative study of nitrogen and phosphorus cycling in tidal and non-tidal riverine wetlands. Wetlands 21, 210–222 (2001). https://doi.org/10.1672/0277-5212(2001)021[0210:ACSONA]2.0.CO;2
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DOI: https://doi.org/10.1672/0277-5212(2001)021[0210:ACSONA]2.0.CO;2