Diagenetic alteration of biogenic silica oxygen isotope values: implications for use as a paleoenvironmental proxy
Abstract
Oxygen isotope (δ18O) values of biogenic silica have enormous potential as paleoenvironmental proxies in marine and non-marine environments. Isotopic exchange and phase changes (opal-A to opal-CT) can overprint the initial δ18O values, but these diagenetic processes can also provide additional paleoenvironmental information. The timing and magnitude of isotopic exchange reactions are difficult to constrain in natural environments; however, experimental results of diatom aging indicate that changes in the δ18O values of the biogenic silca occur coincident with dehydroxylation of the silica prior to opal-CT formation. Diagenetic alteration of biogenic silica dramatically changes our interpretation of silica isotope data from sedimentary records. For example, diatom δ18O values from a Pliocene ( 4.68 to 3.44 Ma) age marine sediment core (AND-1B) from the Ross Sea, Antarctica range from +28 to +36‰. The silica-water fractionation relationship for marine diatoms of Juillet-Leclerc and Labeyrie (1987) and a standard marine δ18O water value of 0‰ results in unrealistic sea surface temperatures of >20°C. Conversely, if water temperatures of 0 to 10°C are used, the resulting water δ18O values range from -8 to -16‰. A plausible alternate scenario is that the diatom δ18O values are recording sediment pore-water conditions. Pore waters in the AND-2A core had δ18O values of -11‰, possibly as a result cryogenic brine formation (Frank et al., 2010). These low δ18O values are in close agreement with our calculated δ18O water values. Despite diagenetic overprinting of the diatom δ18O values, there is still good agreement between the measured diatom δ18O values and the stacked benthic δ18O record (Lisiecki and Raymo, 2005); biogenic silica δ18O values in the AND-1B core likely record the composition of shallow sediment pore water and cryogenic brine formation. The agreement between our δ18O record and the benthic stack δ18O values suggests that brine formation in the early Pliocene Ross Sea may be driven by regional and global scale climate processes. Sedimentary diatoms most likely represent a combination of growth and diagenetic environments, and the δ18O value of diagenetic water needs to be addressed when reconstructing paleoceanographic and paleoenvironmental conditions.
- Publication:
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AGU Fall Meeting Abstracts
- Pub Date:
- December 2016
- Bibcode:
- 2016AGUFMPP14B..08D
- Keywords:
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- 1041 Stable isotope geochemistry;
- GEOCHEMISTRYDE: 1051 Sedimentary geochemistry;
- GEOCHEMISTRYDE: 4914 Continental climate records;
- PALEOCEANOGRAPHYDE: 4924 Geochemical tracers;
- PALEOCEANOGRAPHY