Zhaohui Aleck Wang Meagan Gonneea Eagle Kevin D. Kroeger Neil K. Ganju Sophie N. Chu 2018 <p><span>The lateral export of carbon from coastal marshes&nbsp;</span><i>via</i><span>&nbsp;tidal exchange is a key component of the&nbsp;marsh&nbsp;carbon budget&nbsp;and coastal&nbsp;carbon cycles. However, the magnitude of this export has been difficult to accurately quantify due to complex tidal dynamics and seasonal cycling of carbon. In this study, we use&nbsp;</span><i>in situ</i><span>, high-frequency measurements of&nbsp;dissolved inorganic carbon&nbsp;(DIC) and&nbsp;water fluxes&nbsp;to estimate lateral DIC fluxes from a U.S. northeastern&nbsp;salt marsh. DIC was measured by a CHANnelized&nbsp;Optical Sensor&nbsp;(CHANOS) that provided an&nbsp;</span><i>in situ</i><span>&nbsp;concentration measurement at 15-min intervals, during periods in summer (July – August) and late fall (December). Seasonal changes in the marsh had strong effects on DIC concentrations, while tidally-driven water fluxes were the fundamental vehicle of marsh carbon export.&nbsp;Episodic events, such as groundwater discharge and mean sea water level changes, can impact DIC flux through altered DIC concentrations and&nbsp;water flow. Variability between individual tides within each season was comparable to mean variability between the two seasons. Estimated mean DIC fluxes based on a multiple linear regression (MLR) model of DIC concentrations and high-frequency water fluxes agreed reasonably well with those derived from CHANOS DIC measurements for both study periods, indicating that high-frequency, modeled DIC concentrations, coupled with continuous water flux measurements and a&nbsp;hydrodynamic model, provide a robust estimate of DIC flux. Additionally, an analysis of&nbsp;sampling strategies&nbsp;revealed that DIC fluxes calculated using conventional sampling frequencies (hourly to two-hourly) of a single&nbsp;tidal cycle&nbsp;are unlikely to capture a representative mean DIC flux compared to longer-term measurements across multiple tidal cycles with sampling frequency on the order of tens of minutes. This results from a disproportionately large amount of the net DIC flux occurring over a small number of tidal cycles, while most tides have a near-zero DIC export. Thus, high-frequency measurements (on the order of tens of minutes or better) over the time period of interest are necessary to accurately quantify tidal exports of carbon species from salt marshes.</span></p> application/pdf 10.1016/j.marchem.2018.08.005 en Elsevier Deciphering the dynamics of inorganic carbon export from intertidal salt marshes using high-frequency measurements article