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relationship between atmospheric pO2 and MIF‐S was proposed (Farquhar et al., 2000). Subsequent experimental and modeling approaches revealed that the formation of MIF‐S and their preservation in sediments deposited at the Earth’s surface required that the atmospheric oxygen abundance was below 10–5 present atmospheric level (PAL; Pavlov and Kasting, 2002; but see also Zahnle et al., 2006).

Schematic illustration of range in delta 33S for sedimentary sulfide and sulfate exhibiting mass-independently fractionated sulfur isotopes in the Archean and early Paleoproterozoic and its disappearance around 2300 million years ago.

      Recent work on other redox‐sensitive elements and their isotopic composition (e.g., Mo, Cr, U) has added substantially to this discussion, resulting in a refinement in our understanding and challenging in particular the timing of the first significant rise in atmospheric oxygen abundance.

      It is without doubt that the sedimentary records of sulfide and sulfate have archived a vast range of information in respect to the evolution of our Earth System. Geological processes at the surface of our planet (e.g., deposition and weathering) as well as at depth leave their traces as much as microbially mediated processes of sulfur cycling. The sulfur isotopic composition has been and continues to be the most important source of information in respect to these processes, despite the fact that diagenesis tends to obscure to some extent any primary signal. Moreover, through the intimate relationship between the geochemical cycles of sulfur, carbon and oxygen, sulfur isotopes have become a prime proxy signal for the overall evolution of Earth’s redox state. Future efforts should continue to explore these possibilities in our quest to quantitatively understanding Earth System Evolution.

      I thank the editors for inviting me to contribute this review. Financial support for my research on sulfur isotope geochemistry by the Deutsche Forschungsgemeinschaft (DFG) throughout the years is gratefully acknowledged. Ted Present and two anonymous reviewers are thanked for their constructive comments that improved the clarity of this manuscript.

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