日本地球惑星科学連合2021年大会

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セッション記号 M (領域外・複数領域) » M-IS ジョイント

[M-IS14] 水惑星学

2021年6月5日(土) 15:30 〜 17:00 Ch.02 (Zoom会場02)

コンビーナ:関根 康人(東京工業大学地球生命研究所)、渋谷 岳造(海洋研究開発機構)、玄田 英典(東京工業大学 地球生命研究所)、福士 圭介(金沢大学環日本海域環境研究センター)、座長:玄田 英典(東京工業大学 地球生命研究所)、関根 康人(東京工業大学地球生命研究所)、臼井 寛裕(東京工業大学地球生命研究所)、福士 圭介(金沢大学環日本海域環境研究センター)、渋谷 岳造(海洋研究開発機構)

15:45 〜 16:00

[MIS14-14] Effect of photo-oxidation reactions of ferrous iron on geochemical conditions required for redox stratification on early Gale lake

*田畑 陽久1,2、関根 康人2、尾崎 和海3 (1.東京大学大学院 理学系研究科 地球惑星科学専攻、2.東京工業大学 地球生命研究所、3.東邦大学 理学部 生命圏環境科学科)


キーワード:火星、地球化学、光化学、鉄酸化、酸化還元成層

Recent observations on iron mineralogy and geochemical data by NASA’s Curiosity rover suggested that Gale Crater had sustained closed-basin, redox-stratified lakes at around Hesperian (~3.5–3.3 Ga) (Hurowitz et al., 2017). On Earth, redox stratification in closed-basin lakes is largely maintained by biological processes, e.g., photosynthesis. For Martian lakes without photosynthetic life to be redox stratified, photo-oxidation of ferrous iron could have been a source of oxidants at shallow lakes; whereas, upwelling of reducing ferrous iron is hypothesized to have occurred from the bottom (Hurowitz et al., 2017). However, no quantitative evaluations have been conducted to investigate conditions that can achieve redox stratification on early Mars.

In the present study, we investigate geohydrological and atmospheric conditions (e.g., Fe2+ fluxes from rivers and groundwater, advection rate and pH of lake water, and UV flux) to achieve redox stratification on early Gale lakes using a one-dimensional reaction-transport model. We took into account pH-dependent, photo-oxidation of Fe2+ into the model using our experimental data (Tabata et al., 2021). Attenuation of UV light due to atmospheric gas species and dissolved species was considered in the model; accordingly, the effeciency of oxidant production is highly sensitive to atmospheric and water compositions.

Our results suggest that when Fe2+ is supplied from the top of a lake, acidic pH of 4–5, high Fe2+ influx (0.1–100 mol m–2 yr–1), and thick atmosphere (~1 bar CO2) are required for redox stratification. In the case of Fe2+ input from the top, Fe2+ needs to be transported to the deep before being fully photo-oxidized for redox stratification. The required conditions can achieve low efficiency of Fe2+ photo-oxidation near the surface sufficient to transport to the deep. When Fe2+ is supplied only from the bottom of a lake, required conditions for redox stratification are circum-neutral pH (6–7) and moderate Fe2+ influx (0.01–1 mol m–2 yr–1). At acidic pH, water became ferruginous throughout a lake due to inefficient photo-oxidation and low levels of Fe2+ near the surface. High input flux of Fe2+ results in abundance of carbonate formation, which is inconsistent with the finding of little carbonates in Gale’s lacustrine sediments. Considering the recent estimate of circum-neutral pH of early Gale lake (Fukushi et al., 2019), our results prefer groundwater upwelling as the major source of Fe2+ on the lakes. In addition, low CO2 in the atmosphere would be prefered to avoid Fe-carbonate formation and to promote efficient Fe2+ photo-oxidation for redox stratification, which implies the need of abundance of other efficient greenhouse effect gases to warm the surface on early Mars.