Abstract
The Nyos maar-diatreme volcano on the Oku Volcanic Group (OVG) in NW Cameroon carries yet the most infamous maar lake in the world because the lake exploded in 1986 releasing CO2 that killed ~1,750 people and over 3,000 livestock. A process of safely getting rid of accumulated gas from the lake started in 2001. Even though ~33 % of it has been removed, gas continues to seep into the lake from the mantle, so the lake still poses a thread. Available data on basaltic lava from the maar-diatreme volcano and other volcanoes of the OVG are used here to determine the depth and location where the magmas are produced, and to make inferences on the generation of CO2 in the Nyos mantle. Fractionation-corrected major element data agree well with experimental data on mantle peridotite and suggest that Lake Nyos magmas formed at pressures of 2–3 GPa in the garnet stability field. This inference is corroborated by trace element models that indicate small degree (1–2 %) partial melting in the presence of residual garnet (2–3 %). The basalts have elevated High Field Strength Element (HFSE) ratios (Zr/Hf = 48.5 ± 1.2 and Ti/Eu = 5,606 ± 224) which cannot be explained by any reasonable fractional crystallization model. A viable mechanism would be melting of a mantle that was previously spiked by percolating carbonatitic melts. It is suggested that small degree partial melting of this metasomatised mantle produces the lavas with super chondritic HFSE ratios, and is generating the CO2 that seeps into and accumulates in the lake, and which asphyxiated people and animals during the 1986 gas disaster. This finding requires that current efforts to degas Lake Nyos should take into account the fact that CO2 will continue to seep into the lake for a yet undetermined but long time in the future. A viable solution would be to avoid renewed stratification of the lake, by (somehow) safely and permanently bringing bottom gas-charged waters to the surface to release gas, even after the gas currently stocked in the lake has been completely removed.
Keywords
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Acknowledgments
Compilation of the Cameroon Volcanic Line and other data used in this paper was made when I was on a ‘mis à la disposition’ of Okayama University Institute for Study of the Earth’s Interior (ISEI) in Misasa, Japan, from the Institute for Geological and Mining Research (IRGM, Cameroon). My stay in ISEI was supported by a JSPS grant to Minoru Kusakabe for ‘Asia-Africa Science Platform Program (Geochemistry of Lake Nyos gas disaster, Cameroon Volcanic Line-Rift Valley volcanoes and the underlying mantle), and also by a COE-21 (Center of Excellence in the 21st Century in Japan) grant to Eizo Nakamura. Assistance from colleagues and collaborators of IRGM and ISEI is acknowledged. Some of the pictures shown in Figs. 2 and 9 were taken during many trips to Lake Nyos within the framework of (1) the Lakes Nyos and Monoun Degassing Project funded by the Government of Cameroon, USAID and the French Cooperation; (2) SATREPS-IRGM project headed by Prof. Takeshi Ohba of Tokai University (Japan) and funded by the Government of Cameroon, the Japan International Cooperation Agency (JICA) and the Japan Science and Technology Agency (JST); (3) the Lake Nyos dam reinforcement project funded by the Government of Cameroon and the European Union. We acknowledge the leadership of MINRESI, through IRGM that coordinates all these projects. Discussions with T. Yokoyama and review comments from Dmitri Rouwet, Karoly Németh and Tanya Furman helped in improving the paper. I stayed at the Misasa Onsen Hospital for part of the time that I was in Misasa, but was able to continue to work. I commend Y. Nakano (COE-21 administrative officer), all the nurses and doctors through Yukari Tanabe and Morio Yasuo respectively, for the assistance that they gave me.
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Aka, F.T. (2015). Depth of Melt Segregation Below the Nyos Maar-Diatreme Volcano (Cameroon, West Africa): Major-Trace Element Evidence and Their Bearing on the Origin of CO2 in Lake Nyos. In: Rouwet, D., Christenson, B., Tassi, F., Vandemeulebrouck, J. (eds) Volcanic Lakes. Advances in Volcanology. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-36833-2_21
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