Highlights
- This is the first study on porewater carbonate chemistry in Louisiana marshes.
- The TA and DIC in the marsh porewaters are among the highest ever reported.
- Higher porewater TA and DIC in the salt marsh may be caused by sulfate reduction.
- Coastal marshes have the potential to contribute to coastal acidification.
Abstract
Dissolved inorganic carbon (DIC) and total alkalinity (TA) are fundamental components of carbonate systems that control pH and buffering capacity of a water body. Three coastal marshes with contrasting salinities in Barataria Basin, Louisiana, USA, were sampled five times between December 2018 and October 2019 to understand seasonal changes in porewater carbonate chemistry and its impact on surrounding water bodies. Porewater DIC and TA increased with depth irrespective of marsh type and ranged from 4.47 to 31.61 mmol/kg and from 1.78 to 28.56 mmol/kg, respectively. The salt marsh had higher porewater DIC and TA compared to the lower salinity intermediate and brackish marshes, probably due to sulfate reduction in the salt marsh. However, it is likely that denitrification is also an important anaerobic respiration pathway in these marshes because of high nitrate concentrations in this region and low porewater TA/DIC ratios in all three marshes. Porewater TA and DIC concentrations were generally higher during warmer months than colder months. However, the marsh flooding regime had a profound influence on TA and DIC concentrations by changing the redox potential of the marsh soil. Porewater TA/DIC ratios in all three marshes were generally less than 1, while surface water TA/DIC ratios were around 1, suggesting that export of DIC and TA from coastal marshes has the potential to contribute to coastal acidification.
He S., Maiti K., Swarzenski C. M., Elsey-Quirk T., Groseclose G. N. & Justic D., 2022. Porewater chemistry of Louisiana marshes with contrasting salinities and its implications for coastal acidification. Estuarine, Coastal and Shelf Science: 268: 107801. doi: 10.1016/j.ecss.2022.107801. Article (subscription required).
