Lignin chemistry of wetland soil profiles in two contrasting basins of the Louisiana Gulf coast

Abstract

Recent studies indicate that loss of soil organic matter (SOM) from coastal wetlands can contribute to the hypoxia in the northern Gulf of Mexico along the Louisiana coast. In this study, coastal marsh soil profiles of two contrasting basins were investigated for lignin composition in order to assess organic matter source and degradation status under these different wetland formations. The Atchafalaya Basin is undergoing land building whereas the Barataria Basin is experiencing land loss. Lignin monomers were extracted using alkaline CuO oxidation followed by gas chromatography–mass spectrometry characterization. Marsh soil profiles from the Barataria Basin showed strong lignin storage with two-fold higher lignin contents (sum of vanillyl, syringyl, and cinnamyl phenols, Λ8) than those in the Atchafalaya Basin. Source SOM inputs in the Barataria Basin were non-woody angiosperms, whereas in the Atchafalaya Basin inputs were non-woody angiosperms and some gymnosperm inputs. Principal component analysis (PCA) showed that different soil environmental factors dominated the status of soil organic matter degradation. Soil pH was negatively related to the lignin degradation in the Atchafalaya Basin, whereas high total N contents inhibited lignin degradation in the Barataria Basin. Increasing electrical conductivity inhibited organic matter degradation in the low salinity wetlands of the Atchafalaya Basin, but positively influenced lignin decomposition in the higher salinity marsh soil profiles of Barataria Basin. Despite SOM in the Barataria Basin being more degraded than in the Atchafalaya, the nearly 10-fold greater amount of organic carbon (C) in the Barataria, coupled with net land loss, indicates that it is greater source of oxygen-consuming organic C, thus contributes more to the hypoxia in the Gulf.