ausblenden:
Schlagwörter:
Climate change; Dissolution; Glacial geology; Oceanography; Seawater effects; Silica; Sediments, Biological fractionation; Diatom production; Differential dissolution; Fractionation effects; Glacial sediments; Interglacial climate; Productivity zones; Silica concentrations, Sediments; Climate change, germanium/silicon ratio; global isotope record; marine diatom; opal burial ratio; palaeoclimate change
Zusammenfassung:
Late Pleistocene variations of germanium to silicon ratios in marine diatom shells from sediment cores, (Ge/Si) opal , are coherent with the global isotope record of glacial to interglacial climate change. These variations are thought to reflect changes in (Ge/Si) seawater driven by climatemodulated alterations in oceanic Ge/Si sources and sinks. However, an important criterion for interpreting (Ge/Si) opal as a monitor of whole ocean (Ge/Si) seawater is that the opal burial ratio be insensitive both to local diatom production and surface ocean silica concentrations (so-called biological fractionation effects) and to differential dissolution artifacts (so-called diagenesis offsets). Here we test these assumptions by comparing model ocean sediment (Ge/Si) opal distributions with data from Holocene and glacial sediments across the high-latitude Indian-Antarctic Ocean siliceous ooze belt. In contrast to the model, the data show no gradients in either Holocene or glacial (Ge/Si) opal values across productivity zones displaying dramatic changes in biosiliceous production, opal burial, and dissolution. This evidence supports the contention that fractionation effects are small and that observed down-core variations in (Ge/Si) opal faithfully record secular changes in (Ge/Si) seawater .
