Deuterium exchangeability in modern and fossil plant resins

Abstract Deuterium exchange experiments on modern and fossil plant resins (amber) were conducted to assess to what extent diagenetic alteration can overprint the stable hydrogen ( δ 2 H) and carbon ( δ 13 C) isotopic composition of these materials. Pairs of resins and amber fragments were placed together with deuterated water in sealed quartz-glass tubes to assure that all samples were exposed equally to the chosen experimental conditions. Experiments lasting up to one year were carried out at temperatures of 50 °C and 90 °C using water artificially enriched in deuterium ( 2 H concentrations between 2861 and 8845 µg/g), which resulted in deuterium concentrations measured in samples well above natural concentrations (i.e., 2 H ∼ 143 µg/g). Modern resins recorded a mean deuterium exchange with deuterium-enriched water of 2.0 ± 0.1%, compared to 1.3 ± 0.2% observed in their fossil counterparts. No significant changes were observed in the δ 13 C of modern and fossil resins during the experiments. Overall, these results indicate that the extent of 2 H isotopic exchange in resins is minor and apparently occurs prior to polymerization. Consequently, the stable isotopic composition of fossil resins has the potential to serve as a useful proxy for paleoenvironmental reconstructions, given the widespread distribution of ambers in the Mesozoic and Cenozoic fossil record.