Abstract
This study quantified relationships between forest composition and flooding gradients on the Roanoke River floodplain, North Carolina. Because flooding is highly variable in time and space, the research was designed to determine the specific hydrological parameters that control woody species abundance on the landscape scale. I specifically tested the importance of spring vs. yearly flood duration, as well as flood duration during hydrologically wet vs. dry years. Field vegetation samples of woody species composition were integrated with spatial data from a Landsat Thematic Mapper (TM) classification and a flood simulation model derived in part from synthetic aperture radar (SAR) imagery. Flood simulations were output and summarized for the periods 1912–1950 (before dams were constructed on the river) and 1965–1996 (after all of the dams were completed). Tenth percentile (dry), median, and 90th percentile (wet) hydroperiod (flood duration) regimes were generated for the spring and year, both pre- and post-dam. Detrended correspondence analysis (DCA) was used to ordinate the plot data, and correlation/regression between ordination axis scores and the flood variables were used to explore the relationships between flooding and species composition. Nineteenth percentile hydroperiod (i.e., wet conditions) correlated most strongly with DCA axis 1 (r>0.9), indicating that inundation during extremely wet years strongly controls species composition on the floodplain. The results were used to quantitatively determine the niche width for both species and mapped vegetation classes in terms of number of days flooded annually and during the spring growth period. The results suggest that spring hydroperiod is an important mechanism that may drive competitive sorting along the flooding gradient, especially during the early years of succession (i.e., pre-dam, which represents the period during which most of the forests sampled were established), and that annual hydroperiod affects the relative dominance of species as the forests mature.
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References
Angelov, M. N., Sung, S. S., Doong, R. L., Harms, W. R., Kormanik, P. P. & Black, J. C. 1996. Long-and short-term flooding effects on survival and sink-source relationships of swamp-adapted tree species. Tree Physiol. 16: 477-484.
Austin, M. P. & Smith, T. M. 1989. A new model for the continuum concept. Vegetatio 83: 35-47.
Beven, K. J. & Kirkby, M. J. 1979. A physically based, variable contribution area model of basin hydrology. Hydrol. Sci. Bull. 24: 43-69.
Dobson, M. C., Ulaby, F. T. & Pierce, L. E. 1995. Land-cover classification and estimation of terrain attributes using synthetic aperture radar. Remote Sensing Environ. 51: 199-214.
Dobson, M. C., Pierce, L. E. & Ulaby, F. T. 1996. Knowledge-based land-cover classification using ERS-1/JERS-1 SAR composites. IEEE Trans. Geosci. Remote Sensing 34: 83-99.
Gauch, H. G. & Whittaker, R. H. 1972. Coenocline simulation. Ecology 53: 446-451.
Grosenbaugh, L. R. 1952. Plotless timber estimates-new, fast, easy. J. Forestry 50: 32-37.
Grossman, D. H. et al. 1998. International classification of ecological communities: Terrestrial vegetation of the United States. Volume I. The national vegetation classification system: Development, status and applications. The Nature Conservancy, Arlington, VA.
Hess, L. L., Melack, J. M. & Simonett, D. S. 1990. Radar detection of flooding beneath the forest canopy: a review. Int. J. Remote Sensing 11: 1313-1325.
Hook, D. D. 1984. Waterlogging tolerance of lowland tree species of the South. Southern J. Appl. Forestry 8: 136-149.
Justice, C. O. & Townshend, J. R. G. 1981. Integrating ground data with remote sensing. Pp. 38-58. In: Townshend, J. R. G. (ed.), Terrain analysis and remote sensing. Allen and Unwin, Boston.
Kartesz, J. T. 1994. A synonymized checklist of the vascular flora of the United States, Canada, and Greenland, 2 edition. Timber Press, Portland.
Kellison, M. C., Young, M. J., Braham, R. R. & Jones, E. J. 1998. Major alluvial floodplains. In: Messina, M. G. & Conner, W. H. (eds), Southern Forested Wetlands: ecology and management. Lewis Publishers, Boca Raton, FL.
Lindsey, A. A., Barton, J. D. & Miles, S. R. 1958. Field efficiencies of forest sampling methods. Ecology 39: 428-444.
Lynch, J. M. 1981. Roanoke river preserve design project. North Carolina natural heritage program and the North Carolina nature conservancy, Raleigh, NC.
McKnight, J. S., Hook, D. D., Langdon, O. G. & Johnson, R. L. 1981. Flood tolerance and related characteristics of trees of the bottomland forests of the southern United States. Pp. 29-69. In: Clark, J. R. & Benforado, J. (eds), Wetlands of bottomland hardwood forests. Elsevier, Amsterdam.
McNab, W. H. 1993. A topographic index to quantify the effect of mesoscale landform on site productivity. Can. J. Forest Res. 23: 1100-1107.
Megonigal, J. P., Conner, W. H., Kroeger, S. & Sharitz, R. R. 1997. Aboveground production in Southeastern floodplain forests: A test of the subsidy-stress hypothesis. Ecology 78: 370-384.
Middleton, B. 1999. Wetland restoration, flood pulsing, and disturbance dynamics. John Wiley and Sons, New York.
Mitsch, W. J., Taylor, J. R. & Benson, K. B. 1991. Estimating primary productivity of forested wetland communities in different hydrologic landscapes. Landsc. Ecol. 5: 75-92.
Pearlstine, L., McKellar, H. & Kitchens, W. 1985. Modelling the impacts of a river diversion on bottomland forest communities in the Santee River floodplain, South Carolina. Ecol. Model. 29: 283-302.
Peet, R. K., Wentworth, T. R. & White, P. S. 1998. A flexible, multipurpose method for recording vegetation composition and structure. Castanea 63: 262-274.
Rice, S. K. & Peet, R. K. 1997. Vegetation of the lower roanoke river floodplain. The Nature Conservancy, Durham, NC.
Richards, J. A., Woodgate, P. W. & Skidmore, A. K. 1987. An explanation of enhanced radar backscatter from flooded forests. Int. J. Remote Sensing 8: 1093-1100.
Sharitz, R. R. & Mitsch, W. J. 1993. Southern floodplain forests. Pp. 311-372. In: Martin, W. H., Boyce, S. G. & Echternacht, A. C. (eds), Biodiversity of the Southeastern United States: lowland terrestrial communities. John Wiley and Sons, New York.
Streng, D. R., Glitzenstein, J. S. & Harcombe, P. A. 1989. Woody seedling dynamics in an east Texas floodplain. Ecol. Monog. 59: 177-204.
ter Braak, C. J. F. 1995. Ordination. Pp. 91-173. In: Jongman, R. H. G., ter Braak, C. J. F. & Van Tongeren, O. F. R. (eds), Data analysis in community and landscape ecology. Cambridge University Press, Cambridge.
ter Braak, C. J. F. 1996. Unimodal models to relate species to environment. DLO-Agricultural Mathematics Group, Wageningen, The Netherlands.
ter Braak, C. J. F. & Šmilauer, R. 1998. CANOCO Reference Manual and User's Guide to Canoco for Windows: Software for Canonical Community Ordination (version 4). Microcomputer Power, Ithaca, NY.
Townsend, P. A. 1997. Environmental gradients and vegetation patterns on the Roanoke River floodplain, North Carolina. Ph.D. Dissertation. University of North Carolina, Chapel Hill.
Townsend, P. A. & Walsh, S. J. 1998. Modeling floodplain inundation using an integrated GIS with radar and optical remote sensing. Geomorphology 21: 295-312.
Townsend, P. A. 2000. A quantitative fuzzy approach to assess mapped vegetation classifications for ecological applications. Remote Sensing Environ. 72: 253-267.
Townsend, P. A. 2001a. Mapping seasonal flooding in forested wetlands using multi-temporal Radarsat SAR. Photogram. Engi. Remote Sensing 67: 857-864.
Townsend, P. A. 2001b. Relationships between forest structure and the detection of flood inundation in forested wetlands using Cband SAR. Int. J. Remote Sensing (in press).
Townsend, P. A. 2001c. Estimating forest structure in wetlands using multi-temporal SAR. Remote Sensing Environ. (in press).
Townsend, P. A. & Foster, J. R. 2001. Deriving synthetic hydroperiod regimes using imaging radar. Water Res. Res. (in review).
Townsend, P. A. & Walsh, S. J. 2001. Remote sensing of forested wetlands: application of multitemporal and multispectral satellite imagery to determine plant community composition and structure in Southeastern USA. Plant Ecol. (in press).
Visser, J. M. & Sasser, C. E. 1995. Changes in tree species composition, structure and growth in a bald cypress-water tupelo swamp forest. Forest Ecol. Manage. 72: 119-129.
Wang, Y., Hess, L. L., Filoso, S. & Melack, J. M. 1995. Understanding the radar backscattering from flooded and nonflooded Amazonian forests: Results from canopy backscatter modeling. Remote Sensing Environ. 54: 324-332.
Weakley, A. S., Patterson, K. D., Landaal, S. & Pyne, M., editors. 1998. International classification of ecological communities: terrestrial vegetation of the Southeastern United States. The Nature Conservancy, Chapel Hill, NC.
Wharton, C. H., Kitchens, W. M., Pendleton, E. C. & Sipe, T. W. 1982. The ecology of bottomland hardwood swamps of the Southeast: a community profile. FWS/OBS-81/37, U.S. Fish and Wildlife Service, Biological Services Division, Washington, DC.
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Townsend, P.A. Relationships between vegetation patterns and hydroperiod on the Roanoke River floodplain, North Carolina. Plant Ecology 156, 43–58 (2001). https://doi.org/10.1023/A:1011996822576
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DOI: https://doi.org/10.1023/A:1011996822576