High-temperature water–rock interactions and hydrothermal environments in the chondrite-like core of Enceladus

• Published in: Nature communications Vol. 6; no. 1; p. 8604
• Main Authors: Sekine, Yasuhito, Shibuya, Takazo, Postberg, Frank, Hsu, Hsiang-Wen, Suzuki, Katsuhiko, Masaki, Yuka, Kuwatani, Tatsu, Mori, Megumi, Hong, Peng K., Yoshizaki, Motoko, Tachibana, Shogo, Sirono, Sin-iti
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 27.10.2015; Nature Publishing Group; Nature Pub. Group
• Subjects: 704/2151/213; 704/2151/2809; 704/445/431; 704/445/847; Earth science; Experiments; Humanities and Social Sciences; Jupiter; Laboratories; multidisciplinary; Nanoparticles; R&D; Research & development; Saturn; Science; Science (multidisciplinary); Silica; Temperature; Japan; Germany
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/ncomms9604

It has been suggested that Saturn’s moon Enceladus possesses a subsurface ocean. The recent discovery of silica nanoparticles derived from Enceladus shows the presence of ongoing hydrothermal reactions in the interior. Here, we report results from detailed laboratory experiments to constrain the reaction conditions. To sustain the formation of silica nanoparticles, the composition of Enceladus’ core needs to be similar to that of carbonaceous chondrites. We show that the presence of hydrothermal reactions would be consistent with NH 3 - and CO 2 -rich plume compositions. We suggest that high reaction temperatures (>50 °C) are required to form silica nanoparticles whether Enceladus’ ocean is chemically open or closed to the icy crust. Such high temperatures imply either that Enceladus formed shortly after the formation of the solar system or that the current activity was triggered by a recent heating event. Under the required conditions, hydrogen production would proceed efficiently, which could provide chemical energy for chemoautotrophic life. Observations indicate that the southern hemisphere of Enceladus is geologically active, with spray containing Si nanoparticles being ejected from an underground ocean. Here, the authors report that experiments to constrain reaction conditions suggest the core is similar to that of carbonaceous chondrites.