Sulfur accumulation in pinewood ( Pinus sylvestris) induced by bacteria in a simulated seabed environment: Implications for marine archaeological wood and fossil fuels

• Published in: International biodeterioration & biodegradation Vol. 62; no. 4; pp. 336 - 347
• Main Authors: Fors, Yvonne, Nilsson, Thomas, Risberg, Emiliana Damian, Sandström, Magnus, Torssander, Peter
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.12.2008
• Subjects: Consortia; Erosion bacteria; Fossil fuels; Marine archaeological wood; Pinus sylvestris; Sulfur accumulation; Sulfur isotope fractionation; Sulfur reducing bacteria; Sulfur spectroscopy; Waterlogged wood degradation; Marine archaeological wood; Consortia; Sulfur accumulation; Sulfur isotope fractionation; Sulfur reducing bacteria; Fossil fuels; Waterlogged wood degradation; Erosion bacteria; Sulfur spectroscopy
• ISSN: 0964-8305; 1879-0208
• DOI: 10.1016/j.ibiod.2007.11.008

Fresh pinewood blocks were submerged in sulfate and iron(II) containing media, inoculated with bacterial consortia isolated from seawater, aiming to simulate the seabed conditions of the Vasa shipwreck (1628). The consortia contained erosion (EB) and sulfate-reducing bacteria (SRB). Sulfur K-edge X-ray absorption near edge structure (XANES) spectroscopy and scanning X-ray spectromicroscopy images showed that organic sulfur, mainly thiols (R-SH), had accumulated in the lignin-rich middle lamella in EB-degraded parts of the wood. The sulfur content in the wood increased more than 10 times in 2 years. In another series with active inoculums from marine archaeological wood, the sulfur XANES spectra showed, after 4 years of anaerobic treatment, considerable amounts also of inorganic iron sulfides, Fe 1−xS, which oxidized at atmospheric exposure. A sediment sample from the Vasa's seabed was also rich in iron sulfides, including pyrite, FeS 2. X-ray fluorescence mappings of sulfur and phosphorous distributions indicate that scavenging SRB penetration, producing hydrogen sulfide in situ, is restricted to EB-degraded parts of the wood structure. The sulfur isotope depletion of 34S from δ 34S = 21‰ in marine sulfate to δ 34S = 6‰ and 1.8‰ for fractions of reduced sulfur and sulfate separated from a Vasa wood sample, respectively, suggests bacterial transformation. A fuller understanding of the routes of sulfur accumulation, as reactive iron sulfides and as organic sulfur, has important implications for improving conservation methods of marine archaeological wood. Moreover, the biogenic accumulation of organically bound sulfur, specifically in lignin-rich parts of waterlogged wood, has wider geochemical significance for fossil fuels of marine origin, as lignin-rich humic matter is important for the diagenetic formation of kerogens from anoxic marine sediments.