Northeastern Section - 43rd Annual Meeting (27-29 March 2008)

Paper No. 7
Presentation Time: 10:30 AM

A GEOMORPHIC PROCESS-RESPONSE MODEL FOR THE MISSISSIPPI RIVER CHENIER PLAIN, USA: A NEW PERSPECTIVE


MCBRIDE, Randolph A., Geology & Earth Science Program, Dept. of Environmental Science & Policy, George Mason University, 3055 David King Hall, MS 5F2, 4400 University Drive, Fairfax, VA 22030, TAYLOR, Matthew J., Dept. of Geography, University of Denver, 2050 East Iliff Avenue, Denver, CO 80208 and BYRNES, Mark R., Applied Coastal Research & Engineering, Inc, 766 Falmouth Road, Suite A-1, Mashpee, MA 02649, rmcbride@gmu.edu

Using 28 topographic profiles, air-photo interpretation, and historical shoreline-change data, coastal processes were evaluated along the Mississippi River Chenier Plain to explain the geomorphology of primary landforms. The Louisiana Chenier Plain is located west and downdrift of the Mississippi River. This late-Holocene, microtidal, storm-dominated coast is 200 km long, ≤30 km wide, and composed of mud deposits capped by marsh interspersed with thin sand- and shell-rich ridges ("cheniers") that are ≤4 m high.

Most Chenier-Plain ridges represent open-Gulf paleoshorelines. Past shoreline morphodynamics allow ridges to be classified as transgressive, regressive, or laterally accreted. As such, a geomorphic hierarchy of landforms is devised relative to dominant coastal process. To understand long-term evolution of the Chenier Plain, modern tidal-inlet processes operating at Sabine, Calcasieu, and Mermentau Passes were examined relative to the inlet-stability ratio. Prior to human modification and stabilization efforts, the former Mermentau River entrance is classified as wave-dominated, Sabine Pass as tide-dominated, and Calcasieu Pass as tide-dominated to mixed.

Hoyt (1969) presented the first depositional model for chenier genesis and mudflat progradation. However, Hoyt's model oversimplifies Chenier-Plain evolution because it omits ridges created by non-transgressive processes. Thus, the geologic evolution of the Chenier Plain is more complex than Mississippi River channel avulsions, and it involved not only chenier ridges (transgressive), but also beach ridges (regressive) and spits (laterally accreted).

We [McBride, R.A., Taylor, M.J., & Byrnes, M.R., 2007. Coastal morphodynamics & Chenier-Plain evolution in southwestern Louisiana, USA: A geomorphic model. Geomorphology, 88(3-4): 367-422] developed a six-stage geomorphic process-response model to explain Chenier-Plain evolution as a function of: 1) the balance between sediment supply and energy dissipation associated with Mississippi River channel avulsions, 2) local sediment reworking and lateral transport, 3) tidal-entrance dynamics and sediment trapping, and 4) possibly higher-than-present stands of Holocene sea level. Hence, development of transgressive, regressive, and laterally-accreted ridges typically occurred contemporaneously along the same shoreline at different locations.