Estuaries and Coasts

, Volume 36, Issue 6, pp 1165–1180 | Cite as

Influence of Wind-Driven Inundation and Coastal Geomorphology on Sedimentation in Two Microtidal Marshes, Pamlico River Estuary, NC

  • David LagomasinoEmail author
  • D. Reide Corbett
  • J. P. Walsh


Marsh sediment accumulation is predominately a combination of in situ organic accumulation and mineral sediment input during inundation. Within the Pamlico River Estuary (PRE), marsh inundation is dependent upon event (e.g., storms) and seasonal wind patterns due to minimal astronomical tides (<10 cm). A better understanding of the processes controlling sediment deposition and, ultimately, marsh accretion is needed to forecast marsh sustainability with changing land usage, climate, and sea level rise. This study examines marsh topography, inundation depth, duration of inundation, and wind velocity to identify relationships between short-term deposition (tile-based) and long-term accumulation (210Pb and 137Cs) recorded within and adjacent to the PRE. The results of this study indicate (1) similar sedimentation patterns between the interior marsh and shore-side marsh at different sites regardless of elevation, (2) increased sedimentation (one to two orders of magnitude, 0.04–4.54 g m−2 day−1) within the interior marsh when the water levels exceeded the adjacent topography (e.g., storm berm), and (3) that short-term sea level changes can have direct effects on sediment delivery to interior marshes in wind-driven estuarine systems.


Marsh Sedimentation Accumulation Inundation Microtidal Berm Geomorphology 



We would like to thank the NC RENaissance Computing Institute, the USGS, and the Department of Geological Sciences at East Carolina University for providing financial support of this research. Special thanks to the faculty, staff, and graduate students that helped in the laboratory and the field.


  1. Amein, M., and D.S. Airan. 1976. Mathematical modeling of circulation and hurricane surge in Pamlico Sound, North Carolina. Raleigh, NC: NC Sea Grant Program.Google Scholar
  2. Appleby, P.G., and F. Oldfield. 1978. The calculation of lead-210 dates assuming a constant rate of supply of unsupported 210Pb to the sediment. Catena 5: 1–8.CrossRefGoogle Scholar
  3. Bellucci, L.G., M. Frignani, J.K. Cochran, S. Albertazzi, L. Zaggia, G. Cecconi, and H. Hopkins. 2007. 210Pb and 137Cs as chronometers for salt marsh accretion in the Venice Lagoon—links to flooding frequency and climate change. Journal of Environmental Radioactivity 97: 85–102.CrossRefGoogle Scholar
  4. Bricker-Urso, S., S.W. Nixon, J.K. Cochran, D.J. Hirschberg, and C. Hunt. 1989. Accretion rates and sediment accumulation in Rhode Island salt marshes. Estuaries 12: 300–317.CrossRefGoogle Scholar
  5. Cahoon, D.R., J.W. Day, D.J. Reed, and R.S. Young (eds.). 1998. Global climate change and sea-level rise: estimating the potential for submergence of coastal wetlands. Washington, DC: USGS, Biological Resources Division.Google Scholar
  6. Cahoon, D.R., and D.J. Reed. 1995. Relationships among marsh surface topography, hydroperiod, and soil accretion in a deteriorating Louisiana salt marsh. Journal of Coastal Research 11: 357–369.Google Scholar
  7. Cahoon, D.R., and R. Turner. 1989. Accretion and canal impacts in a rapidly subsiding wetland II. Feldspar marker horizon technique. Estuaries and Coasts 12: 260–268.CrossRefGoogle Scholar
  8. Callaway, J.C., R.D. DeLaune, and W.H. Patrick. 1997. Sediment accretion rates from four coastal wetlands along the Gulf of Mexico. Journal of Coastal Research 13: 181–191.Google Scholar
  9. Childers, D.L., and J.W. Day. 1990. Marsh–water column interactions in 2 Louisiana estuaries. 1. Sediment dynamics. Estuaries and Coasts 13: 393–403.CrossRefGoogle Scholar
  10. Christiansen, T., P.L. Wiberg, and T.G. Milligan. 2000. Flow and sediment transport on a tidal salt marsh surface. Estuarine, Coastal and Shelf Science 50: 315–331.CrossRefGoogle Scholar
  11. Ciavola, P., C. Organo, L.L. Vintro, and P.I. Mitchell. 2002. Sedimentation processes on intertidal areas of the Lagoon of Venice: identification of exceptional flood events (Acqua Alta) using radionuclides. Journal of Coastal Research 36: 139–147.Google Scholar
  12. Costanza, R., R. d’Arge, R. de Groot, S. Farber, M. Grasso, B. Hannon, K. Limburg, S. Naeem, R.V. O’Neill, J. Paruelo, R.G. Raskin, P. Sutton, and M. van den Belt. 1997. The value of the world’s ecosystem services and natural capital. Nature 387: 253–260.CrossRefGoogle Scholar
  13. Cowart, L., J.P. Walsh, and D.R. Corbett. 2010 Analyzing estuarine shoreline change: a case study of Cedar Island, North Carolina. Journal of Coastal Research 26(5): 817–830.Google Scholar
  14. Craft, C.B., E.D. Seneca, and S.W. Broome. 1993. Vertical accretion in microtidal regularly and irregularly flooded estuarine marshes. Estuarine, Coastal and Shelf Science 37: 371–386.CrossRefGoogle Scholar
  15. Darke, A.K., and J.P. Megonigal. 2003. Control of sediment deposition rates in two mid-Atlantic Coast tidal freshwater wetlands. Estuarine, Coastal and Shelf Science 57: 255–268.CrossRefGoogle Scholar
  16. Currin, C.A., P.C. Delano, and L.M. Valdes-Weaver. 2008. Utilization of a citizen monitoring protocol to assess the structure and function of natural and stabilized fringing salt marshes in North Carolina. Wetlands Ecology and Management 16(2): 97–118.CrossRefGoogle Scholar
  17. Day, J.W., F. Scarton, A. Rismondo, and D. Are. 1998. Rapid deterioration of a salt marsh in Venice Lagoon, Italy. Journal of Coastal Research 14: 583–590.Google Scholar
  18. Delaney, T.P., J.W. Webb, and T.J. Minello. 2000. Comparison of physical characteristics between created and natural estuarine marshes in Galveston Bay, Texas. Wetlands Ecology and Management 8: 343–352.CrossRefGoogle Scholar
  19. DeLaune, R.D., R.H. Baumann, and J.G. Gosselink. 1983. Relationships among vertical accretion, coastal submergence, and erosion in a Louisiana Gulf Coast marsh. Journal of Sedimentary Research 53: 147–157.Google Scholar
  20. DeLaune, R.D., J.A. Nyman, and W.H. Patrick. 1994. Peat collapse, ponding and wetland loss in a rapidly submerging coastal marsh. Journal of Coastal Research 10: 1021–1030.Google Scholar
  21. Dillard, S. 2008. Resuspension events and seabed dynamics in the Neuse River Estuary, NC. Master’s thesis, East Carolina University.Google Scholar
  22. Flynn, W.W. 1968. The determination of low levels of polonium-210 in environmental materials. Analytical Chimica Acta 43: 221–227.CrossRefGoogle Scholar
  23. Frey, R.W., and P.B. Basan (eds.). 1978. Coastal salt marshes. New York: Springer.Google Scholar
  24. Friedrichs, C.T., and J.E. Perry. 2001. Tidal salt marsh morphodynamics. Journal of Coastal Research 27: 7–37.Google Scholar
  25. Giffin, D., and D.R. Corbett. 2003. Evaluation of sediment dynamics in coastal systems via short-lived radioisotopes. Journal of Marine Systems 42: 83–96.CrossRefGoogle Scholar
  26. Giorgi, F., Hewitson, B., Christiansen, J., Hulme, M., von Storch, H., Whetton, P., Jones, R., Mearns, L., Fu, C. (Eds.), 2001. Regional climate information—evaluation and projections. Cambridge: Cambridge University Press.Google Scholar
  27. Goldenberg, S.B., C.W. Landsea, A.M. Mestas-Nuñez, and W.M. Gray. 2001. The recent increase in Atlantic hurricane activity: causes and implications. Science 293: 474–479.CrossRefGoogle Scholar
  28. Goodbred, S.L., and A.C. Hine. 1995. Coastal storm deposition: salt-marsh response to a severe extratropical storm, March 1993, west-central Florida. Geology 23: 679–682.CrossRefGoogle Scholar
  29. Hardaway, C.S. 1980. Shoreline erosion and its relationship to the geology of the Pamlico River Estuary. Master’s thesis, East Carolina University.Google Scholar
  30. Hatton, R.S., R.D. DeLaune, and W.H. Patrick. 1983. Sedimentation, accretion, and subsidence in marshes of Barataria Basin, Louisiana. Limnology and Oceanography 28: 494–502.CrossRefGoogle Scholar
  31. Hine, A.C. 1979. Mechanism of berm development and resulting beach growth along a barrier spit complex. Sedimentology 26: 333–351.CrossRefGoogle Scholar
  32. Heiri, O., A.F. Lotter, and G. Lemcke. 2001. Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. Journal of Paleolimnology 25: 101–110.CrossRefGoogle Scholar
  33. Horton, B.P., D.R. Corbett, S.J. Culver, R.J. Edwards, and C. Hillier. 2006. Modern saltmarsh diatom distributions of the Outer Banks, North Carolina, and the development of a transfer function for high resolution reconstructions of sea level. Estuarine, Coastal and Shelf Science 69: 381–394.CrossRefGoogle Scholar
  34. Jackson, N.L. 1995. Wind and waves: influence of local and non-local waves on mesoscale beach behavior in estuarine environments. Annals of the Association of American Geographers 85: 21–37.Google Scholar
  35. Kastler, J.A., and P.L. Wiberg. 1996. Sedimentation and boundary changes of Virginia salt marshes. Estuarine, Coastal and Shelf Science 42: 683–700.CrossRefGoogle Scholar
  36. Kemp, A.C., B.P. Horton, D.R. Corbett, S.J. Culver, R.J. Edwards, and O. van de Plassche. 2009. The relative utility of foraminifera and diatoms for reconstructing Late Holocene sea-level change in North Carolina, USA. Quaternary Research 71: 9–21.CrossRefGoogle Scholar
  37. Knutson, T.R., J.L. McBride, J. Chan, K. Emanuel, G. Hollar, C. Landsea, I. Held, J.P. Kossin, A.K. Srivastava, and M. Sugi. 2010. Tropical cyclones and climate change. Nature Geoscience 3:157–163.Google Scholar
  38. Kolker, A.S., S.L. Goodbred Jr., S. Hameed, and J.K. Cochran. 2009. High-resolution records of the response of coastal wetland systems to long-term and short-term sea-level variability. Estuarine, Coastal and Shelf Science 84: 493–508.CrossRefGoogle Scholar
  39. Kolker, A.S., and S. Hameed. 2007. Meteorologically driven trends in sea level rise. Geophysical Research Letters 34:23. doi: 10.1029/2007GL031814.Google Scholar
  40. Le Hir, P., Y. Monbet, and F. Orvain. 2007. Sediment erodability in sediment transport modelling: can we account for biota effects? Continental Shelf Research 27: 1116–1142.CrossRefGoogle Scholar
  41. Leonard, L.A., and M.E. Luther. 1995. Flow hydrodynamics in tidal marsh canopies. Limnology and Oceanography 40: 1474–1484.CrossRefGoogle Scholar
  42. Luettich, R.A., S.D. Carr, J.V. Reynolds-Fleming, C.W. Fulcher, and J.E. McNinch. 2002. Semi-diurnal seiching in a shallow, micro-tidal lagoonal estuary. Continental Shelf Research 22: 1669–1681.CrossRefGoogle Scholar
  43. Mattheus, C.R., A.B. Rodriguez, B.A. McKee, and C.A. Currin. 2010. Impact of land-use change and hard structures on the evolution of fringing marsh shorelines. Estuarine, Coastal and Shelf Science 88(3): 365–376.CrossRefGoogle Scholar
  44. McCaffery, R.J., and J. Thomson. 1980. A record of the accumulation of sediment and trace metals in a Connecticut salt marsh. In Advances in geophysics, estuarine physics and chemistry: studies in Long Island Sound, ed. B. Saltzman, 165–237. New York: Academic.CrossRefGoogle Scholar
  45. Morris, J.T., P.V. Sundareshwar, C.T. Nietch, B. Kjerfve, and D.R. Cahoon. 2002. Responses of coastal wetlands to rising sea levels. Ecology 83(10): 2869–2877.CrossRefGoogle Scholar
  46. Mitsch, W.J., and J.G. Gosselink. 2000. Wetlands. New York: Wiley.Google Scholar
  47. Möller, I., T. Spencer, J.R. French, D.J. Leggett, and M. Dixon. 1999. Wave transformation over salt marshes: a field and numerical modelling study from North Norfolk, England. Estuarine, Coastal and Shelf Science 49: 411–426.Google Scholar
  48. Mwamba, M.J., and R. Torres. 2002. Rainfall effects on marsh sediment redistribution, North Inlet, South Carolina, USA. Marine Geology 189: 267–287.CrossRefGoogle Scholar
  49. Neubauer, S.C., I.C. Anderson, J.A. Constantine, and S.A. Kuehl. 2002. Sediment deposition and accretion in a Mid-Atlantic (U.S.A.) tidal freshwater marsh. Estuarine, Coastal and Shelf Science 54: 713–727.CrossRefGoogle Scholar
  50. Neumeier, U., and P. Ciavola. 2004. Flow resistance and associated sedimentary processes in a Spartina maritima salt-marsh. Journal of Coastal Research 20: 435–447.CrossRefGoogle Scholar
  51. Nittrouer, C.A., R.W. Sternberg, R. Carpenter, and J.T. Bennett. 1979. The use of Pb-210 geochronology as a sedimentological tool: application to the Washington continental shelf. Marine Geology 31: 297–316.CrossRefGoogle Scholar
  52. Nyman, J.A., R.J. Walters, R.D. Delaune, and W.H. Patrick. 2006. Marsh vertical accretion via vegetative growth. Estuarine, Coastal and Shelf Science 69: 370–380.CrossRefGoogle Scholar
  53. Pasternack, G.B., and G.S. Brush. 1998. Sedimentation cycles in a river-mouth tidal freshwater marsh. Estuaries and Coasts 21: 407–415.CrossRefGoogle Scholar
  54. Pasternack, G.B., and G.S. Brush. 2001. Seasonal variations in sedimentation and organic content in five plant associations on a Chesapeake Bay tidal freshwater delta. Estuarine, Coastal and Shelf Science 53: 93–106.CrossRefGoogle Scholar
  55. Perillo, G.M.E., E.P.D. Santos, and M.C. Piccolo. 2003. An inexpensive instrument for sediment erosion-accumulation rate measurement in intertidal environments. Wetlands Ecology and Management 11: 195–198.CrossRefGoogle Scholar
  56. Pietrafesa, L.J., Janowitz, G.S., Chao, T., Wiesberg, R.H., Askari, F., Noble, E. 1986. The physical oceanography of Pamlico Sound. NC Sea Grant Program, Raleigh, NC, p. 125.Google Scholar
  57. Reed, D.J. 1989. Patterns of sediment deposition in subsiding coastal salt marshes, Terrebonne Bay, Louisiana: the role of winter storms. Estuaries and Coasts 12: 222–227.CrossRefGoogle Scholar
  58. Redfield, A.C. 1972. Development of a New England salt marsh. Ecological Monographs 42(2): 201–237.CrossRefGoogle Scholar
  59. Riggs, S.R., Ames, D.V. 2003. Drowning of North Carolina: sea-level rise and estuarine dynamics. NC Sea Grant Program, Raleigh, NC, p. 152.Google Scholar
  60. Simmons, C.E. 1993. Sediment characteristics of North Carolina streams. USGS Water-Supply Paper 2364.Google Scholar
  61. Stevenson, J.C., L.G. Ward, and M.S. Kearney. 1988. Sediment transport and trapping in marsh systems: Implications of tidal flux studies. Marine Geology 80: 37–59.CrossRefGoogle Scholar
  62. Stumpf, R.P. 1983. The process of sedimentation on the surface of a salt marsh. Estuarine, Coastal and Shelf Science 17: 495–508.CrossRefGoogle Scholar
  63. Temmerman, S., G. Govers, S. Wartel, and P. Meire. 2003. Spatial and temporal factors controlling short-term sedimentation in a salt and freshwater tidal marsh, Scheldt estuary, Belgium, SW Netherlands. Earth Surface Processes and Landforms 28: 739–755.CrossRefGoogle Scholar
  64. Thomas, S., and P.V. Ridd. 2004. Review of methods to measure short time scale sediment accumulation. Marine Geology 207: 95–114.CrossRefGoogle Scholar
  65. van Wijnen, H.J., and J.P. Bakker. 2001. Long-term surface elevation change in salt marshes: a prediction of marsh response to future sea-level rise. Estuarine, Coastal and Shelf Science 52: 381–390.CrossRefGoogle Scholar
  66. Voulgaris, G., and S.T. Meyers. 2004. Net effect of rainfall activity on salt-marsh sediment distribution. Marine Geology 207: 115–129.CrossRefGoogle Scholar
  67. Ward, L.G., M.S. Kearney, and J.C. Stevenson. 1998. Variations in sedimentary environments and accretionary patterns in estuarine marshes undergoing rapid submergence, Chesapeake Bay. Marine Geology 151: 111–134.CrossRefGoogle Scholar
  68. Wells, J.T., and S.Y. Kim. 1989. Sedimentation in the Albemarle–Pamlico lagoonal system: synthesis and hypotheses. Marine Geology 88: 263–284.CrossRefGoogle Scholar

Copyright information

© Coastal and Estuarine Research Federation 2013

Authors and Affiliations

  • David Lagomasino
    • 1
    • 2
    Email author
  • D. Reide Corbett
    • 3
    • 4
  • J. P. Walsh
    • 3
    • 4
  1. 1.Southeast Environmental Research CenterMiamiUSA
  2. 2.Department of Earth and EnvironmentFlorida International UniversityMiamiUSA
  3. 3.Department of Geological SciencesEast Carolina UniversityGreenvilleUSA
  4. 4.Institute for Coastal Science & PolicyGreenvilleUSA

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