Japan Geoscience Union Meeting 2022

Presentation information

[J] Poster

M (Multidisciplinary and Interdisciplinary) » M-IS Intersection

[M-IS17] Aqua planetology

Thu. Jun 2, 2022 11:00 AM - 1:00 PM Online Poster Zoom Room (34) (Ch.34)

convener:Yasuhito Sekine(Earth-Life Science Insitute, Tokyo Institute of Technology), convener:Keisuke Fukushi(Institute of Nature & Environmental Technology, Kanazawa University), Tomohiro Usui(Japan Aerospace Exploration Agency), convener:Takazo Shibuya(Japan Agency for Marine-Earth Science and Technology), Chairperson:Hidenori Genda(Earth-Life Science Institute, Tokyo Institute of Technology), Takazo Shibuya(Japan Agency for Marine-Earth Science and Technology), Keisuke Fukushi(Institute of Nature & Environmental Technology, Kanazawa University), Yasuhito Sekine(Earth-Life Science Insitute, Tokyo Institute of Technology), Tomohiro Usui(Japan Aerospace Exploration Agency)

11:00 AM - 1:00 PM

[MIS17-P05] Formation of bright materials on Ceres with explosive cryovolcanic eruption of deep subsurface liquid brines.

Masahiro Yoda1, *Yasuhito Sekine1, Takazo Shibuya2, Sakiko Kikuchi2, Shuya Tan1 (1.Earth-Life Science Insitute, Tokyo Institute of Technology, 2.JAMSTEC)

Keywords:Ceres, carbonate, cryovolcano

Ceres is a dwarf planet in the asteroid belt, which have been attracting attention due to the possibility of liquid eruption from the interior. The surface of Ceres is typically composed of dark components, such as organic matter, and several secondary minerals (e.g., De Sanctis et al., 2015). In addition to the secondary minerals, the bright materials mainly composed of Na2CO3 with small amounts of NH4-bearing salts have been observed on geologically young units of Ceres (e.g., De Sanctis et al., 2016). Gravity and geomorphic data strongly suggest that the liquid brine source that erupted on the surface was originated from deep oceanic water of Ceres (Raymond et al., 2020). On the other hand, the presence of Na2CO3 in the bright materials requires highly alkaline brines (e.g., pH > 11), although water chemistry of the deep oceanic water of Ceres was estimated to be moderately alkaline (e.g., 9 < pH <10.5) (e.g., Castillo-Rogez et al., 2018). Thereby, there was a contradiction between geophysical (gravity and geomorphology) evidence and geochemical predictions for formation of the bright materials on Ceres. One potential issue with the contradiction is that effects of decompression of liquid brines upon eruption on salt formation are unclear due to the lack of investigations by laboratory experiments.
Here, we examined the salt formation upon decompression of volatile-containing liquid brines based on laboratory experiments. Our experimental results suggested that alkalinization of liquid brines due to consequent degassing of dissolved CO2 upon rapid decompression can explain the formation of Na2CO3 from moderately alkaline brines (pH down to 10.0). Small amounts of NH4-bearing salts could be formed with Na2CO3 if the brine samples contain the highly levels of NH3 (e.g., ΣNH3/ΣCO2 > 1). Based on our results, we constrained the possible chemical compositions of liquid brine source of the bright materials on Ceres. We also evaluated the chemical evolution of deep oceanic water of Ceres using thermodynamic equilibrium models. The comparison of experimental results and model evaluations suggest that if the subsurface liquid brines originate from deep oceanic water generated by water-rock interactions with water-to-rock ratios less than ~1, Na2CO3 with small amounts of NH4-bearing salts in the bright materials can be explained with its explosive cryovolcanic eruption. Given the young surface age of the bright materials, our results support that Ceres may have maintained the deep subsurface liquid ocean until today.