Mineralogical and geochemical facets of the massive deposition of stibnite-metastibnite at a seafloor hydrothermal field (Wakamiko Crater, Kagoshima Bay, Ryukyu Volcanic Arc)

• Published in: American Mineralogist Vol. 109; no. 10; pp. 1819 - 1833
• Main Authors: Dekov, Vesselin, Furuma, Yukako, Guéguen, Bleuenn, Klose, Lukas, Yasukawa, Kazutaka, Morita, Motoaki, Asael, Dan, Yamanaka, Toshiro, Bindi, Luca, Koschinsky, Andrea, Pracejus, Bernhard, Kato, Yasuhiro
• Format: Journal Article
• Language: English
• Published: Washington Mineralogical Society of America 01.10.2024; Walter de Gruyter GmbH
• Subjects: Boulders; Cadmium; Chemical composition; Chimneys; Chlorinity; Chromium; Craters; Deposition; Detection limits; Disproportionation; Fluids; Heavy metals; Hydrothermal; Hydrothermal deposits; Hydrothermal fields; Isotope composition; Low concentrations; Low temperature; Manganese; metastibnite; Mounds; Ocean floor; Oxic conditions; Phase separation; Precipitates; Precipitation; Rapid quenching (metallurgy); Seawater; Stibnite; stibnite; metastibnite; hydrothermal alteration; seafloor; Japan; sulfate reduction; Wakamiko Crater; Sulfate reduction; Sulfates; Sulfur dioxide; Sulphate reduction; Trace elements; Wakamiko Crater
• ISSN: 0003-004X; 1945-3027
• DOI: 10.2138/am-2023-9096

Stibnite precipitates in the form of massive boulders at two active hydrothermal mounds in the submarine Wakamiko Crater (Ryukyu Volcanic Arc) as opposed to commonly observed accessory stibnite in the seafloor hydrothermal deposits. The stibnite dimorph, metastibnite, found here for the first time on the seafloor, appears to always form whenever stibnite is precipitated under submarine hydrothermal conditions. Our study shows that hydrothermal conditions of low temperatures (<50 °C) and low values of pH (<6) are favorable for the precipitation of stibnite on the seafloor. The stibnite probably does not precipitate at the measured vent fluid temperatures (i.e., 177.6–187.0 °C) along the chimney conduits, but rather at temperatures <50 °C and at slightly reduced to slightly oxic conditions ( = –0.5 to +0.5 V) within the chimney walls and hydrothermal mounds. Metastibnite deposition appears to be the result of rapid quenching of hot hydrothermal fluid when mixed with cold seawater and rapid precipitation at the interface between stibnite and vent fluid. The low concentrations (usually below detection limits) of the trace elements (Cd, Co, Cr, Cu, Li, Mn, Mo, Ni, P, Pb, Sr, V, Zn) in the stibnite deposits from Wakamiko Crater are likely a result of the decreased metal-transporting capacity of the precipitating vent fluid due to its low chlorinity. Low-chlorinity venting implies sub-seafloor boiling and phase separation of the hydrothermal fluid. Sluggish hydrothermal fluid/seawater mixing within the walls of the chimneys and mounds favors the reduction of sulfate dissolved in the hydrothermal fluids and results in a heavy S isotope composition of the sulfate in the vent fluids. Sulfate reduction and disproportionation of magmatic SO , both leading to heavy S isotope composition of sulfate in the vent fluids, seem to be common processes in volcanic arc/back-arc submarine hydrothermal settings.