Organic Matter Polymerization by Disulfide Bonding Near the Chemocline in Cariaco Basin

The preservation of organic carbon in sediments as kerogen is an essential pathway in the global carbon cycle, but the chemical reactions involved in kerogen formation remain poorly understood. Previous researchers have found that many sediments deposited under euxinic conditions contain sulfur-bearing non-polar lipids as well as disulfide bonds among lipid and carbohydrate monomers. It remains unclear, however, when during organic matter decomposition and diagenesis these different sulfur-bearing structures form, and how different environmental conditions affect the extent of organic matter sulfurization. We investigate organic sulfurization processes armed with a technique for measuring the sulfur-isotopic compositions of individual organosulfur compounds by coupled gas chromatography - inductively coupled plasma mass spectrometry. Organic compounds were extracted from sediments and water column sediment traps from Cariaco Basin, a euxinic basin in the Caribbean Sea. We measured the sulfur-isotopic compositions of both non-polar lipids and of derivatized disulfide-bound compounds from eight sediment trap profiles and a six-meter-long sediment core. In Cariaco Basin, lipid sulfurization processes appear to begin near the chemocline and continue in sediments on timescales of thousands of years. Slow diagenetic sulfurization in sediments produces lipid monomers with sulfur atoms in ring structures that are 34S-depleted relative to coexisting dissolved sulfide. Lipid monomers become progressively enriched in 34S over time, indicating ongoing formation coinciding with an increase in the amount of total sulfur in bulk kerogen. One of the most abundant monomers observed in Cariaco sediments, a phytol-related thiophene, is also produced intermittently near the chemocline. Phytol thiophene δ34S values in sediment traps are similar to those observed in shallow Cariaco sediments except during occasional ';enrichment events,' when phytol thiophene δ34S values increase to as high as -2‰. In contrast, disulfide bonding appears to affect both lipids and carbohydrates and occur exclusively at the chemocline on very short timescales of days to weeks. In both the water column and the sediments, the sulfur isotope ratios of disulfide-bound monosaccharides are dramatically 34S-enriched relative to dissolved sulfide at the chemocline (~-30‰), ranging from -11‰ to +9‰. Disulfide-bound phytenes, which likely derive from the same precursor compounds as phytol thiophenes, were observed in only a few of the sediment trap extracts and have sulfur-isotopic compositions near +4.5‰. These 34S-enriched compositions indicate that the source of sulfur for rapid disulfide bonding may be an intermediate sulfur species that is not in isotopic equilibrium with dissolved sulfide. Significantly, δ34S values for disulfide-bound compounds in Cariaco Basin appear to be set at the chemocline and stable during subsequent diagenesis, opening the possibility that organic sulfur isotopes may archive information about environmental conditions at the chemocline in low-maturity sediments. Disulfide bonding does not, however, appear to be the major process driving slower diagenetic sulfur incorporation into kerogen. Compound-specific organic sulfur isotope analysis makes it possible to distinguish the products of different lipid and carbohydrate sulfurization processes for the first time.