Reactions between komatiite and CO2-rich seawater at 250 and 350 °C, 500 bars: implications for hydrogen generation in the Hadean seafloor hydrothermal system

Ueda, Hisahiro; Shibuya, Takazo; Sawaki, Yusuke; Saitoh, Masafumi; Takai, Ken; Maruyama, Shigenori

doi:10.1186/s40645-016-0111-8

Cited by 27 publications

(88 citation statements)

References 74 publications

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“…Such CO 2 -rich seawater provided seafloor hydrothermal vent environments that would sustain the emergence and early evolution of life (Takai et al 2006;Russell et al 2010Russell et al , 2014Shibuya et al 2015Shibuya et al , 2016. Furthermore, chemical exchange reactions would have had particular characteristics as the then CO 2 -rich seawater interfaced oceanic lithosphere (e.g., intense CO 2 fixation into the crust) (Nakamura and Kato 2004;Rouchon and Orberger 2008) resulting in the generation of novel high-temperature hydrothermal fluids (e.g.., alkaline, silica-rich, metal-poor fluid, and Mg-rich fluid) (Shibuya et al 2010;Ueda et al 2016). These processes would have played a significant role in controlling the chemistry of early oceans.…”

Section: Introductionmentioning

confidence: 99%

Weak hydrothermal carbonation of the Ongeluk volcanics: evidence for low CO2 concentrations in seawater and atmosphere during the Paleoproterozoic global glaciation

Shibuya

Komiya

Takai

et al. 2017

Prog Earth Planet Sci

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It was previously revealed that the total CO 2 concentration in seawater decreased during the Late Archean. In this paper, to assess the secular change of total CO 2 concentration in seawater, we focused on the Paleoproterozoic era when the Earth experienced its first recorded global glaciation. The 2.4 Ga Ongeluk Formation outcrops in the Kaapvaal Craton, South Africa. The formation consists mainly of submarine volcanic rocks that have erupted during the global glaciation. The undeformed lavas are mostly carbonate-free but contain rare disseminated calcites. The carbon isotope ratio of the disseminated calcite (δ 13 C cc vs. VPDB) ranges from − 31.9 to − 13.2 ‰. The relatively low δ 13 C cc values clearly indicate that the carbonation was partially contributed by 13 C-depleted CO 2 derived from decomposition of organic matter beneath the seafloor. The absence of δ 13 C cc higher than − 13.2‰ is consistent with the exceptionally 13 C-depleted CO 2 in the Ongeluk seawater during glaciation. The results suggest that carbonation occurred during subseafloor hydrothermal circulation just after the eruption of the lavas. Previously, it was reported that the carbonate content in the uppermost subseafloor crust decreased from 3.2 to 2.6 Ga, indicating a decrease in total CO 2 concentration in seawater during that time. However, the average CO 2 (as carbonate) content in the Ongeluk lavas (< 0.001 wt%) is much lower than those of 2.6 Ga representatives and even of modern equivalents. This finding suggests that the total CO 2 concentration in seawater further decreased during the period between 2.6 and 2.4 Ga. Thus, the very low content of carbonate in the Ongeluk lavas is probable evidence for the extremely low CO 2 concentration in seawater during the global glaciation. Considering that the carbonate content of the subseafloor crusts also shows a good correlation with independently estimated atmospheric pCO 2 levels through the Earth history, it seem highly likely that the low carbonate content in the Ongeluk lavas reflects the low atmospheric pCO 2 at that time. We conclude that the continuous decrease in CO 2 concentration of seawater/atm. from 3.2 Ga was one of the contributing factors to the Paleoproterozoic global glaciation.

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Section: Introductionmentioning

confidence: 99%

Weak hydrothermal carbonation of the Ongeluk volcanics: evidence for low CO2 concentrations in seawater and atmosphere during the Paleoproterozoic global glaciation

Shibuya

Komiya

Takai

et al. 2017

Prog Earth Planet Sci

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“…Experimental studies have revealed that high concentrations of CO 2 and thus lower pH of early Earth's oceans (Halevy and Bachan 2017) had the potential to elevate in situ pH and reduce metal concentrations in hydrothermal fluids even at high temperatures, in contrast to their modern equivalents (Shibuya et al 2013). Additionally, the experimental studies show that H 2 concentrations of hydrothermal fluids in komatiite-hosted systems would be comparable to those in modern ultramafic-hosted hydrothermal systems Ueda et al 2016). These experimental studies suggest the existence of H 2 -rich alkaline hydrothermal vents on early Earth (Macleod et al 1994).…”

Section: Earth's Hydrothermal Systems and Closed-system Hydrothermal mentioning

confidence: 99%

“…The vents would add to the general habitability of the oceans by providing nutrients and an energy source. In addition to in situ studies of terrestrial hydrothermal vent fluids and ocean floor drilling (Beaulieu et al 2015;Tivey 2011;Alt 2013), laboratory based experiments using large-scale reactors are conducted to reproduce closed-system water-rock interactions (Yoshizaki et al 2009;Shibuya et al 2013;Ueda et al 2016), which are essential for our understanding of the ocean floor on these icy moons. Efforts are also being taken to develop microfluidics devices for a more controlled setting.…”

Section: Introductionmentioning

confidence: 99%

Experimental and Simulation Efforts in the Astrobiological Exploration of Exooceans

Taubner

Olsson-Francis

Vance³

et al. 2020

Space Sci Rev

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The icy satellites of Jupiter and Saturn are perhaps the most promising places in the Solar System regarding habitability. However, the potential habitable environments are hidden underneath km-thick ice shells. The discovery of Enceladus' plume by the Cassini mission has provided vital clues in our understanding of the processes occurring within the interior of exooceans. To interpret these data and to help configure instruments for future missions, controlled laboratory experiments and simulations are needed. This review aims

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“…Solid curves indicate solutions with 1 mol/L of Ca⊖Mg chloride. Ranges of hydrothermal fluids in this study and previous studies are plotted as individual symbols (Jones et al, 2010;Neubeck et al, 2014;McCollom et al, 2016;Ueda et al, 2016Ueda et al, , 2017 Neubeck et al, 2014;McCollom et al, 2016;Ueda et al, 2016Ueda et al, , 2017…”

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confidence: 99%

“…。カンラン石を用いた高二酸化炭素濃度下の熱水実験は 30 ～ 320°C の幅広い温度範囲で行われている (Jones et al, 2010;Neubeck et al, 2014;McCollom et al, 2016;Ueda et al, 2017 (Lazar et al, 2012;Hao and Li, 2015;Ueda et al, 2016 (Alt., 1995;Edmond et al, 1979;Elderfield and Schultz, 1996;Kelley et al, 2001 (Rividi et al, 2010;Rintamäki, A., 2016) and those formed in hydrothermal experiments Ueda et al, 2016Ueda et al, , 2017 (Jones et al, 2010;Neubeck et al, 2014;McCollom et al, 2016;Ueda et al, 2016Ueda et al, , 2017) ． Fig. 7 Calcite⊖dolomite⊖magnesite stability fields as functions of temperature and mMg/ (mMg + mCa) value estimated from experiments at 275⊖420°C and their extrapolation to 0°C (modified after Tribble et al, 1995) .…”

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confidence: 99%

Serpentinite-hosted Hydrothermal System on the Early Earth

Ueda

Sawaki

2019

Journal of Geography(Chigaku Zasshi)

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To understand the influence of high CO 2 contents in a hydrothermal fluid on ultramafic rockhosted seafloor hydrothermal systems on the early Earth, the reaction between tremolite-bearing serpentinite exposed in the Hakuba-Happo area and a CO 2 -rich NaCl fluid at 200°C and 100 bars was monitored. The H 2 concentration in the fluid reached a constant value of approximately 0.4 mmol/kg within 6312 hours. This concentration is lower than the H 2 concentration in a natural hot spring in the Hakuba-Happo area. During the experiments, the total carbonic acid concentration (∑CO 2 ) in the fluid decreased, and magnesite was formed through the water⊖rock interaction. This is the first experimental report of magnesite formed from Ca-bearing ultramafic rocks, which is possibly attributed to the lower temperature condition compared to previous studies. Incorporation of ferrous iron into the magnesite probably suppressed iron oxidation in fluids and resultant H 2 generation during serpentinization and carbonation at 200°C. Compilation of existing experimental data indicates that precipitated carbonate species depend on reaction temperature, initial fluid composition, and composition of reacted rock. The compilation further suggests that the amount of precipitated carbonate decreases and iron-poor calcite becomes predominant at higher temperatures. Therefore, the influence of the fluid CO 2 on H 2 generation at high temperatures becomes small even on the early Earth. The description of carbonate species formed in komatiites of Archean greenstone belts tells us that H 2 generation in low-temperature hydrothermal fluids circulating peridotitic komatiites was possibly limited by the precipitation of Mg-rich carbonate and iron incorporated therein. On the other hand, experimental hydrothermal fluids co-existing with Mg-bearing carbonate during serpentinization of ultramafic rocks clearly have high Mg contents or become more magnesian, compared to modern basalt-hosted hydrothermal fluids. This implies that carbonation of ultramafic rocks would be one of the main sources of oceanic Mg on the early Earth.Key words： serpentinite, komatiite, CO 2 , carbonate minerals, hydrothermal experiment ：蛇紋岩，コマチアイト，二酸化炭素，炭酸塩鉱物，熱水実験＊東京工業大学大学院理学院地球惑星科学系＊＊東京大学大学院総合文化研究科宇宙地球科学教室＋現所属：国立研究開発法人海洋研究開発機構 (JAMSTEC) 超先鋭研究開発部門 (X-star) 超先鋭研究プログラム (SUGAR)

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Reactions between komatiite and CO2-rich seawater at 250 and 350 °C, 500 bars: implications for hydrogen generation in the Hadean seafloor hydrothermal system

Cited by 27 publications

References 74 publications

Weak hydrothermal carbonation of the Ongeluk volcanics: evidence for low CO2 concentrations in seawater and atmosphere during the Paleoproterozoic global glaciation

Weak hydrothermal carbonation of the Ongeluk volcanics: evidence for low CO2 concentrations in seawater and atmosphere during the Paleoproterozoic global glaciation

Experimental and Simulation Efforts in the Astrobiological Exploration of Exooceans

Serpentinite-hosted Hydrothermal System on the Early Earth

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