Abstract
AbstractSerpentinization environments are key locations that support microbial communities by the abiogenic formation of reduced species associated with peridotite alteration. Here we studied partially serpentinized peridotites from the Chimaera seeps (Turkey), an active continental serpentinization system that vents highly methane‐rich fluids, to investigate the impact of water‐rock interaction on the sulfide and metal mineralogy and its implications on supporting microbial communities. Using high‐resolution scanning electron microscopy, electron microprobe analysis, and transmission electron microscopy we found diverse pentlandite decomposition features with precipitation of secondary sulfides including millerite, heazlewoodite, as well as Cu‐bearing sulfides, native Cu, and awaruite (Ni3Fe). Awaruite forms dense veinlets to single crystal platelets tens of nanometers in size, which is formed by desulphurization of pentlandite. In addition, the nanometer‐sized awaruite platelets are intimately intergrown with serpentine suggesting its growth during peridotite alteration by a dissolution‐precipitation process, likely associated with the interaction of methane‐ and H2‐rich but highly sulfur‐undersaturated fluids. Based on sulfur isotope signatures we infer a mantle and mid‐ocean ridge origin of the sulfide minerals associated with the first stage of partial serpentinization and awaruite formation. Subsequent and ongoing continental fluid‐rock interaction causes significant sulfide decomposition resulting in the formation of porosity and the release of, amongst others, H2S and Fe. These species may likely provide a source of nutrients for active microbial communities in these comparatively nutrient‐starved, low‐temperature continental serpentinization environments.
Highlights
Metal and sulfide minerals in ultramafic rocks are ideal tracers for fluid-rock interaction processes
Using high-resolution scanning electron microscopy, electron microprobe analysis, and transmission electron microscopy we found diverse pentlandite decomposition features with precipitation of secondary sulfides including millerite, heazlewoodite, as well as Cu-bearing sulfides, native Cu, and awaruite (Ni3Fe)
Peridotite alteration by Cretaceous seawater along an ocean ridge spreading center took place at around 230°C–350°C and resulted in pentlandite precipitation associated with thermochemical sulfate reduction, likely at low water-rock ratios causing positive δ34Ssulfide values as a result of isotope fractionation following closed system processes
Summary
Metal and sulfide minerals in ultramafic rocks are ideal tracers for fluid-rock interaction processes. Abiogenically produced H2 and/or CH4 as well as other reduced carbon species, produced as a result of the serpentinization process, together with oxidants such as sulfate or CO2, provide an ideal energy source for chemolithoautotrophic communities living at sites of active serpentinization (e.g., Brazelton et al, 2006; Kelley et al, 2005; Lang et al, 2018; McCollom, 2007) In this regard, these systems have gained increasing interest in the study of the evolution of life on Earth and in the search for life on other planets and planetary bodies (Martin & Russell, 2007; Russell et al, 2010; Vance & Melwani Daswani, 2020).
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