JpGU-AGU Joint Meeting 2017

Presentation information

[EJ] Poster

P (Space and Planetary Sciences) » P-PS Planetary Sciences

[P-PS05] [EJ] Mars and Mars system: results from a broad spectrum of Mars studies and aspects for future missions

Sat. May 20, 2017 1:45 PM - 3:15 PM Poster Hall (International Exhibition Hall HALL7)

convener:Hideaki Miyamoto(University of Tokyo), Tomohiro Usui(Earth-Life Science Institute, Tokyo Institute of Technology ), Ayako Matsuoka(Research Division for Space Plasma, Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency), Sushil K Atreya(University of Michigan Ann Arbor)

[PPS05-P09] Experimental study of Fe2+ photo-oxidation in circumneutral-pH solution: Implications for the trigger for acidification of surface water on early Mars

*Haruhisa Tabata1, Yasuhito Sekine1, Yoshiki Kanzaki2, Seiji Sugita1, Takashi Murakami1 (1.Department of Earth and Planetary Science, The University of Tokyo, 2.Department of Geosciences, The Pennsylvania State University)

Keywords:Mars, surface environment, acidification, photo-oxidation, atmospheric evolution

Mars is suggested to have experienced a global environmental change around the boundary between the Noachian and Hesperian, characterized by a dramatic shift in pH of surface water from circumneutral to highly acidic (Bibring et al., 2006). The previous study has proposed that photo-oxidation of ferrous iron (Fe2+) dissolved in surface water may have caused the acidification (Hurowitz et al., 2010), because this reaction produces proton (H+) via formation of Fe(III) oxide and H2, as follows.
Fe2+ + 2H2O → Fe3+O(OH)↓ + 0.5H2↑ + 2H+
Although this process can explain the mineral assemblages and chemical compositions of Hesperian sedimentary rocks revealed by the Opportunity rover (Rieder et al., 2004, Morris et al., 2006), the trigger for the onset of the photo-oxidation on early Mars remains unclear.
Our previous study has proposed a qualitative hypothesis that a change in the solar irradiance on early Mars could have triggered the shift in pH of surface water (Tabata et al., 2016). More particularly, UV shielding by abundance SO2 could have inhibited the photo-oxidation reaction; whereas, reaching of solar UV light due to a decline in atmospheric SO2 level may have caused an acidification. To assess this hypothesis more quantitatively, the reaction rate of the photo-oxidation is necessary. However, the kinetics data obtained by the previous studies are limited only under highly acidic conditions, namely pH < 3.0 (Jortner et al., 1962).
In the present study, we conducted laboratory experiments to measure the Fe2+ photo-oxidation rate at pH > 3.0. In the experiments, we irradiated UV and visible light using a Xe lamp onto a Fe2+-containing solution in a quartz reaction vessel. An optical filter was used to control the spectrum of the light source onto the solution. To avoid oxidation of Fe2+ by atmospheric O2, the preparation processes were performed in a Ar-purged glovebox. The reaction rate was obtained from a gradient of Fe2+ concentrations in the solution over the irradiation time.
Our experimental results show that the reaction rate of the photo-oxidation at circumneutral pH is consistent with a predicted value that is calculated from the following empirical equation obtained at pH < 3.0 (Jortner et al., 1962).

This suggests that the reaction mechanism would be independent from pH, at least from acidic to circumneutral values. In addition, our results indicate that UV shielding at wavelength < 300 nm strongly inhibits the photo-oxidation within the solution, implying that surface water with circumneutral pH can be maintained in the presence of UV absorbers in the atmosphere on early Mars. Based on these experiments, we strongly support the hypothesis that a change in the atmospheric composition, namely SO2 levels, would have triggered the global environmental change occurred on early Mars.

References:
[1] Bibring et al. (2006) Science, 312, 400-404.
[2] Hurowitz et al. (2010) Nature Geosci. 3, 323-326.
[3] Rieder et al. (2004) Science, 306, 1746-1749.
[4] Morris et al. (2006) J. Geophys. Res., 111, E12S15.
[5] Tabata et al. (2016) Goldschmidt2016 abstract, #3013.
[6] Jortner et al. (1962) The Jour. of Physical Chem., 66, 1258-1271.