Assessing Chromophoric Dissolved Organic Matter (CDOM) Distribution, Stocks, and Fluxes in Apalachicola Bay Using Combined Field, VIIRS Ocean Color, and Model Observations

Authors

Ishan D. Joshi, Louisiana State University
Eurico J. D'Sa, Louisiana State University
Christopher L. Osburn, North Carolina State University
Thomas S. Bianchi, University of Florida
Dong S. Ko, Naval Research Laboratory, Stennis Space Centre, MS
Diana Oviedo-Vargas, North Carolina State University
Ana Arellano, University of FloridaFollow
Nicholas D. Ward, University of Florida

Document Type

Article

Publication Date

2017

Keywords

Apalachicola Bay, Atmospheric-correction, Carbon stocks & fluxes, CDOM algorithm, DOC, VIIRS

Digital Object Identifier (DOI)

https://doi.org/10.1016/j.rse.2017.01.039

Abstract

Understanding the role of estuarine-carbon fluxes is essential to improve estimates of the global carbon budget. Dissolved organic matter (DOM) plays an important role in aquatic carbon cycling. The chromophoric fraction of DOM (CDOM) can be readily detected via in situ and remotely-sensed optical measurements. DOM properties, including CDOM absorption coefficient at 412 nm (a_g412) and dissolved organic carbon (DOC) concentrations were examined in Apalachicola Bay, a national estuarine research reserve located in the northeast Gulf of Mexico, using in situ and satellite observations during the spring and fall of 2015. Synoptic and accurate representation of estuarine-scale processes using satellite ocean color imagery necessitates the removal of atmospheric contribution (~ 90%) to signals received by satellite sensors to successfully link to in situ observations. Three atmospheric correction schemes (e.g., Standard NIR correction, Iterative NIR correction, and SWIR correction) were tested first to find a suitable correction scheme for the VIIRS imagery in low to moderately turbid Apalachicola Bay. The iterative NIR correction performed well, and validation showed high correlation (R² = 0.95, N = 25) against in situ light measurements. A VIIRS-based CDOM algorithm was developed (R² = 0.87, N = 9) and validated (R² = 0.76, N = 20, RMSE = 0.29 m^{− 1}) against in situ observations. Subsequently, a_g412 was used as a proxy of DOC in March (DOC = 1.08 + 0.94 × a_g412, R² = 0.88, N = 13) and in November (DOC = 1.61 + 1.33 × a_g412, R² = 0.83, N = 24) to derive DOC maps that provided synoptic views of DOC distribution, sources, and their transport to the coastal waters during the wet and dry seasons. The estimated DOC stocks were ~ 3.71 × 10⁶ kg C in March and ~ 4.07 × 10⁶ kg C in November over an area of ~ 560 km². Volume flux (out of the bay) almost doubled for March 24 (735 m³ s^{− 1}) relative to November 4 (378 m³ s^{− 1}). However, estimates of DOC fluxes exported out of the bay from model-derived currents and satellite-derived DOC were only marginally greater in March (0.163 × 10⁶ kg C d^{− 1}) than in November (0.124 × 10⁶ kg C d^{− 1}) and reflected greater DOC stocks in the fall. The combination of satellite-, field-, and model-based observations revealed the strong linkage between the Apalachicola River plume, a major source of DOM, and the overall hydrodynamic forcing that controlled distributions of CDOM abundance, DOC concentration, stocks, and fluxes in the bay.

Was this content written or created while at USF?

No

Citation / Publisher Attribution

Remote Sensing of Environment, v. 191, p. 359-372

Scholar Commons Citation

Joshi, Ishan D.; D'Sa, Eurico J.; Osburn, Christopher L.; Bianchi, Thomas S.; Ko, Dong S.; Oviedo-Vargas, Diana; Arellano, Ana; and Ward, Nicholas D., "Assessing Chromophoric Dissolved Organic Matter (CDOM) Distribution, Stocks, and Fluxes in Apalachicola Bay Using Combined Field, VIIRS Ocean Color, and Model Observations" (2017). Marine Science Faculty Publications. 1440.
https://digitalcommons.usf.edu/msc_facpub/1440