Journal
SCIENCE OF THE TOTAL ENVIRONMENT
Volume 485, Issue -, Pages 518-527Publisher
ELSEVIER
DOI: 10.1016/j.scitotenv.2014.03.121
Keywords
Hydrologic manipulation; Dissolved organic carbon; Absorbance; Fluorescence; Freshwater diversion; Lake Pontchartrain; Pulsing
Categories
Funding
- National Science Foundation [CHE-0547982, CHE-1045973, DEB-0833225, EAR-1139997]
- USDA [CSRESS: 2009-3520105819, CSRESS: 2009-65107-05926]
- Louisiana Sea Grant
- Louisiana Board of Regents Fellowship
- Louisiana Board of Regents' Economic Development Assistantship
- Department of Energy Office of Science Graduate Fellowship Program (DOE SCGF)
- American Recovery and Reinvestment Act
- ORISE-ORAU [DE-ACO5-060R23100]
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The Mississippi River Flood of 2011 prompted the opening of the Bonnet Cure Spillway (BCS) in southeastern Louisiana to protect the City of New Orleans. The BCS diverted approximately 21.9 km(3) of river water into the oligohaline Lake Pontchartrain Estuary over the course of 43 days. We characterized estuarine dissolved organic matter (DOM) dynamics before, during, and after the diversion in order to better understand the biogeochemical dynamics associated with these immense freshwater inflows. Dissolved organic carbon (DOC) exhibited a large degree of variability during and after the period of elevated primary productivity that occurred following the diversion. Furthermore, DOC analysis provides limited insight into carbon cycling during these dynamic periods. In order to overcome the limitations of DOC, spectroscopic methods were used to gain insights into chemical composition dynamics. Both ultraviolet visible (A(254), A(350), SUVA(254), spectral slope, and normalized UV/Vis) and fluorescence spectroscopy (excitation emission matrices and fluorescence and biological indices) were used to study the compositional changes of DOM over time. Collectively, our results document a perturbation in DOM chemistry in Lake Pontchartrain due to the diversion and a subsequent return toward pre-diversion conditions. Immediate increases in A(350) indicate that BCS freshwater contained elevated concentrations of lignin of terrestrial origin. Ensuing declines in A(350), along with changes in the fluorescence and biological indices, indicate that DOM rapidly became more microbial in composition. Our results provide insights into estuarine DOM dynamics relevant to systems receiving flood pulses of freshwater due to either hydrologic manipulation or precipitation events. (C) 2014 Elsevier B.V. All rights reserved.
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