South-Central Section - 50th Annual Meeting - 2016

Paper No. 9-2
Presentation Time: 1:50 PM

ASSESSMENT OF MUD-CAPPED DREDGE PIT EVOLUTION OFFSHORE LOUISIANA: IMPLICATIONS TO SAND EXCAVATION AND COASTAL RESTORATION


XU, Kehui, Department of Oceanography and Coastal Science, Louisiana State University, 2165 Energy, Coast and Environment Building, Baton Rouge, LA 70803, MINER, Mike, Marine Minerals Program, Bureau of Ocean Energy Management, Gulf of Mexico Region, New Orleans, LA 70123, BENTLEY, Samuel J., Coastal Studies Institute, Louisiana State University, Baton Rouge, LA 70803, LI, Chunyan, Oceanography and Coastal Science, Louisiana State University, 208 Howe Russell Geoscience Complex, Baton Rouge, LA 70803, OBELCZ, Jeff, Louisiana State University and O'CONNOR, Meg, Coastal Studies Institute, Louisiana State University, E235 Howe-Russell Geoscience Complex, Baton Rouge, LA 70803, kxu@lsu.edu

The shelf offshore Louisiana is characterized by a dominantly muddy seafloor with a paucity of restoration-quality sand proximal to shore. Discrete sand deposits associated with ancient rivers that incised the shelf during lower sea-level positions occur close to shore. These shelf channel sands have been targeted for coastal restoration projects resulting in significant cost savings over more distal deposits. Several recent projects targeted shelf paleo-fluvial deposits comprising relatively deep (10 m) channel sands underlying a muddy overburden. Because of contrasting characteristics of cohesive mud vs. non-cohesive sand and potential modern fluvial mud supply from the Mississippi and Atchafalaya River, long term pit evolution is poorly understood relative to their more common sand-only counterparts. Alterations to seafloor topography from dredging shelf sediment resources can potentially affect oil and gas infrastructure or other resources of concern (i.e. historic shipwrecks) located proximal to dredge pits. Site-specific data required to make accurate predictions and empirical measurements to test and validate predictive models were only available for Peveto Channel offshore Holly Beach, Louisiana. Here we present new geophysical and geological data (bathymetry, sidescan, subbottom, and radionuclide of sediment cores) and physical oceanographic observations (hydrodynamics and sediment dynamics) collected at Raccoon Island (dredged in 2013) dredge pit in Louisiana. These field data collections along with pre-existing data provide a time-series to capture evolution at Raccoon Island post-excavation. Conceptual morphological models will be developed for dredge pit evolution and testing effectiveness of setback buffers protecting pipelines, habitats, and cultural resources. Our results will increase decision making ability regarding safety and protecting environmental and cultural resources, and better management of valuable sand resources.