TY - JOUR
T1 - Integrated carbon budget models for the everglades terrestrial-coastal-oceanic gradient
T2 - Current status and needs for inter-site comparisons
AU - Troxler, Tiffany G.
AU - Gaiser, Evelyn
AU - Barr, Jordan
AU - Fuentes, Jose D.
AU - Jaffé, Rudolf
AU - Childers, Daniel L.
AU - Colado-Vides, Ligia
AU - Rivera-Monroy, Victor H.
AU - Castañeda-Moya, Edward
AU - Anderson, William
AU - Chambers, Randy
AU - Chen, Meilian
AU - Coronado-Molina, Carlos
AU - Davis, Stephen E.
AU - Engel, Victor
AU - Fitz, Carl
AU - Fourqurean, James
AU - Frankovich, Tom
AU - Kominoski, John
AU - Madden, Chris
AU - Malone, Sparkle L.
AU - Oberbauer, Steve F.
AU - Olivas, Paulo
AU - Richards, Jennifer
AU - Saunders, Colin
AU - Schedlbauer, Jessica
AU - Scinto, Leonard J.
AU - Sklar, Fred
AU - Smith, Tom
AU - Smoak, Joseph M.
AU - Starr, Gregory
AU - Twilley, Robert R.
AU - Whelan, Kevin
PY - 2013/9
Y1 - 2013/9
N2 - Recent studies suggest that coastal ecosystems can bury significantly more C than tropical forests, indicating that continued coastal development and exposure to sea level rise and storms will have global biogeochemical consequences. The Florida Coastal Everglades Long Term Ecological Research (FCE LTER) site provides an excellent subtropical system for examining carbon (C) balance because of its exposure to historical changes in freshwater distribution and sea level rise and its history of significant long-term carbon-cycling studies. FCE LTER scientists used net ecosystem C balance and net ecosystem exchange data to estimate C budgets for riverine mangrove, freshwater marsh, and seagrass meadows, providing insights into the magnitude of C accumulation and lateral aquatic C transport. Rates of net C production in the riverine mangrove forest exceeded those reported for many tropical systems, including terrestrial forests, but there are considerable uncertainties around those estimates due to the high potential for gain and loss of C through aquatic fluxes. C production was approximately balanced between gain and loss in Everglades marshes; however, the contribution of periphyton increases uncertainty in these estimates. Moreover, while the approaches used for these initial estimates were informative, a resolved approach for addressing areas of uncertainty is critically needed for coastal wetland ecosystems. Once resolved, these C balance estimates, in conjunction with an understanding of drivers and key ecosystem feedbacks, can inform cross-system studies of ecosystem response to long-term changes in climate, hydrologic management, and other land use along coastlines.
AB - Recent studies suggest that coastal ecosystems can bury significantly more C than tropical forests, indicating that continued coastal development and exposure to sea level rise and storms will have global biogeochemical consequences. The Florida Coastal Everglades Long Term Ecological Research (FCE LTER) site provides an excellent subtropical system for examining carbon (C) balance because of its exposure to historical changes in freshwater distribution and sea level rise and its history of significant long-term carbon-cycling studies. FCE LTER scientists used net ecosystem C balance and net ecosystem exchange data to estimate C budgets for riverine mangrove, freshwater marsh, and seagrass meadows, providing insights into the magnitude of C accumulation and lateral aquatic C transport. Rates of net C production in the riverine mangrove forest exceeded those reported for many tropical systems, including terrestrial forests, but there are considerable uncertainties around those estimates due to the high potential for gain and loss of C through aquatic fluxes. C production was approximately balanced between gain and loss in Everglades marshes; however, the contribution of periphyton increases uncertainty in these estimates. Moreover, while the approaches used for these initial estimates were informative, a resolved approach for addressing areas of uncertainty is critically needed for coastal wetland ecosystems. Once resolved, these C balance estimates, in conjunction with an understanding of drivers and key ecosystem feedbacks, can inform cross-system studies of ecosystem response to long-term changes in climate, hydrologic management, and other land use along coastlines.
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U2 - 10.5670/oceanog.2013.51
DO - 10.5670/oceanog.2013.51
M3 - Article
AN - SCOPUS:84881522533
SN - 1042-8275
VL - 26
SP - 98
EP - 107
JO - Oceanography
JF - Oceanography
IS - 3
ER -