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Laboratory assessment of the impact of chemical oxidation, mineral dissolution, and heating on the nitrogen isotopic composition of fossil-bound organic matter
Martínez-Garcia, A.; Jung, J.; Ai, X.E.; Sigman, D.M.; Auderset, A.; Duprey, N.N.; Foreman, A.; Fripiat, F.; Leichliter, J.; Lüdecke, T.; Moretti, S.; Wald, T. (2022). Laboratory assessment of the impact of chemical oxidation, mineral dissolution, and heating on the nitrogen isotopic composition of fossil-bound organic matter. Geochem. Geophys. Geosyst. 23(8): e2022GC010396. https://dx.doi.org/10.1029/2022GC010396
In: Geochemistry, Geophysics, Geosystems. American Geophysical Union: Washington, DC. ISSN 1525-2027; e-ISSN 1525-2027, more
Peer reviewed article  

Available in  Authors 

Keywords
    Bacillariophyceae [WoRMS]; Foraminifera [WoRMS]
    Marine/Coastal
Author keywords
    nitrogen isotopes; diagenesis; foraminifera; corals; diatoms; teeth

Authors  Top 
  • Martínez-Garcia, A.
  • Jung, J.
  • Ai, X.E.
  • Sigman, D.M.
  • Auderset, A.
  • Duprey, N.N.
  • Foreman, A.
  • Fripiat, F., more
  • Leichliter, J.
  • Lüdecke, T.
  • Moretti, S.
  • Wald, T.

Abstract
    Fossil-bound organic material holds great potential for the reconstruction of past changes in nitrogen (N) cycling. Here, with a series of laboratory experiments, we assess the potential effect of oxidative degradation, fossil dissolution, and thermal alteration on the fossil-bound N isotopic composition of different fossil types, including deep and shallow water scleractinian corals, foraminifera, diatoms and tooth enamel. Our experiments show that exposure to different oxidizing reagents does not significantly affect the N isotopic composition or N content of any of the fossil types analyzed, demonstrating that organic matter is well protected from changes in the surrounding environment by the mineral matrix. In addition, we show that partial dissolution (of up to 70%–90%) of fossil aragonite, calcite, opal, or enamel matrixes has a negligible effect on the N isotopic composition and N content of the fossils. These results suggest that the isotopic composition of fossil-bound organic material is relatively uniform, and also that N exposed during dissolution is lost without significant isotopic discrimination. Finally, our heating experiments show negligible changes in the N isotopic composition and N content of all fossil types at 100°C. At 200°C and hotter, any N loss and associated nitrogen isotope changes appear to be directly linked to the sensitivity of the mineral matrix to thermal stress, which depends on the biomineral type. These results suggest that, so long as high temperature does not compromise the mineral structure, the biomineral matrix acts as a closed system with respect to N, and the N isotopic composition of the fossil remains unchanged.

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