Japan Geoscience Union Meeting 2019

Presentation information

[J] Oral

B (Biogeosciences ) » B-BC Biogeochemistry

[B-BC03] Interrelation between Life, Water, Mineral, and Atmosphere

Tue. May 28, 2019 3:30 PM - 5:00 PM 201A (2F)

convener:Takeshi Kakegawa(Graduate School of Science, Tohoku University), Tadashi Yokoyama(Graduate School of Integrated Arts and Sciences, Hiroshima University), Keisuke Fukushi(Institute of Nature & Environmental Technology, Kanazawa University), Fumito Shiraishi(Department of Earth and Planetary Systems Science, Graduate School of Science, Hiroshima University), Chairperson:Takeshi Kakegawa, Fumito Shiraishi(Hiroshima Univ.)

4:00 PM - 4:15 PM

[BBC03-09] Volcanism, sedimentation, and development of life in a Mesoarchaean intracratonic setting: the Dominion Group, South Africa

*Andrea Agangi1,2, Axel Hofmann2, Dora Paprika2, Andrey Bekker2,3, Frantz Ossa-Ossa2,4 (1.Akita University, 2.University of Johannesburg, 3.University of California, 4.University of Tuebingen)

Keywords:Archaean, Terrestrial life, Alteration

The ca. 3 billion-years-old Dominion Group of the Kaapvaal craton, South Africa is a >2 km-thick volcano-sedimentary succession emplaced in an intracontinental setting shortly after craton consolidation. As such, it represents one of the oldest examples of volcanism and sedimentation on stable continental crust. Deposition of the Dominion Group is interpreted to have occurred largely subaerially in a failed rift. In contrast to other Palaeo- to Mesoarchaean successions of the Kaapvaal craton, the Dominion Group is little deformed and was metamorphosed at greenschist facies grade, allowing excellent preservation of rock textures and chemical composition. The succession includes a thin basal conglomerate that marks a major, craton-scale nonconformity, and is overlain by sandstone. Volcanic rocks include intercalated massive to amygdaloidal mafic lavas of tholeiitic affinity, felsic lavas, and ignimbrites with high Fe/Mg.

In the area around the town of Ottosdal, the Dominion Group is represented by felsic volcanic rocks with intercalated, thin sedimentary layers that crop out discontinuously for several km along the strike. The presence of shallow, porphyritic intrusions that developed peperitic contacts with the sediments and the intense alteration developed in sediments underlying (but not in overlying) volcanic rocks indicate deposition of these sediments in a volcanically and hydrothermally active environment, such as volcanic lakes. These sediments are composed of carbonaceous and variably sulfidic shale and minor arenite and have a distinctive aluminium-rich composition (Al2O3 up to 36 wt.%) and very low contents of alkaline elements, Ca, and Fe (Na2O content from below detection limit to 0.3 wt%; Fe2O3 = 0.1 to 1.6 wt%). The main mineral components of these sediments are pyrophyllite, diaspore, K-mica, rutile, and pyrite. No carbonate was found.

The total organic carbon content) is up to 1.5 wt%, and bulk-sample isotope analyses indicate strongly 13C-depleted composition (δ13CVPDB = -45 to -29‰). These isotopic values are diagnostic of biogenic carbon fixation and the lowest, best-preserved values are indicative of methanogenesis and methanotrophy in a redox and chemically stratified shallow basin. Modern examples of volcanic environments hosting methane-producing Archaea, even under low pH and high temperature conditions, are known from Kamchatka, Russia and Argentina.

Our results indicate that restricted and ephemeral lakes that developed in Mesoarchaean volcanic environments shortly after the large-scale emergence of the Kaapvaal craton fostered life and were likely niches for life diversification. This ancient environment might be a better Mars analogue than modern caldera environments on Earth where the impact of advanced biosphere is more pronounced.