Predicting landscape effects of Mississippi River diversions on soil organic carbon sequestration
March 8, 2017
It contains supporting data from the wetland morphology modeling to support the analysis on the landscape effects of Mississippi River diversions in the context of sea-level rise on soil organic carbon (SOC) sequestration along coastal Louisiana wetlands.
Citation Information
Publication Year | 2017 |
---|---|
Title | Predicting landscape effects of Mississippi River diversions on soil organic carbon sequestration |
DOI | 10.5066/F72R3PWW |
Authors | Hongqing Wang, Gregory D Steyer, Brady Couvillion, Holly J Beck, John M. Rybczyk, Victor H. Rivera-Monroy, Ken W Krauss, Jenneke M. Visser |
Product Type | Data Release |
Record Source | USGS Asset Identifier Service (AIS) |
USGS Organization | Wetland and Aquatic Research Center - Gainesville, FL |
Rights | This work is marked with CC0 1.0 Universal |
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Predicting landscape effects of Mississippi River diversions on soil organic carbon sequestration
Large Mississippi River (MR) diversions (peak water flow >1416 m3/s and sediment loads >165 kg/s) have been proposed as part of a suite of coastal restoration projects and are expected to rehabilitate and rebuild wetlands to alleviate the significant historic wetland loss in coastal Louisiana. These coastal wetlands are undergoing increasing eustatic sea‐level rise, land subsidence, climate change
Authors
Hongqing Wang, Gregory D. Steyer, Brady Couvillion, Holly J. Beck, John M Rybczyk, Victor H. Rivera-Monroy, Ken W. Krauss, Jenneke M. Visser
Related Content
Predicting landscape effects of Mississippi River diversions on soil organic carbon sequestration
Large Mississippi River (MR) diversions (peak water flow >1416 m3/s and sediment loads >165 kg/s) have been proposed as part of a suite of coastal restoration projects and are expected to rehabilitate and rebuild wetlands to alleviate the significant historic wetland loss in coastal Louisiana. These coastal wetlands are undergoing increasing eustatic sea‐level rise, land subsidence, climate change
Authors
Hongqing Wang, Gregory D. Steyer, Brady Couvillion, Holly J. Beck, John M Rybczyk, Victor H. Rivera-Monroy, Ken W. Krauss, Jenneke M. Visser