Vol 10, No 2 (2016)

This paper considers volcanogenic exhalation mineralization using data from 35 years of observation of fumarole activity during an earlier phase of the posteruptive activity of the Second Cone, which is one of the New Tolbachik volcanoes that were formed during the eruption at the North Vent of the Great Tolbachik Fissure Eruption (Kamchatka, 1975–1976). We describe the main types of mineral associations, identify the key mineral species and the secondary and accessory minerals, as well as the sequence of mineral generation. We provide a summary of minerals and compounds that have been identified in ejecta of fumaroles on the Second Cone.

The Bannaya–Karymshina area is situated in southern Kamchatka west of the East Kamchatka Volcanic Belt in the backarc part of the Kuril–Kamchatka island arc. The area is unique in that it contains abundant ejecta of calc-alkaline, acid, mostly ignimbrite, volcanism for a period of 4 Ma. Three rock complexes can be identified with rhyolitic and rhyodacitic compositions: Middle Pliocene ignimbrites, crystalloclastic tuffs of Eopleistocene age that fill in the Karymshina caldera, and Early Pleistocene intrusions. All of these are composed of rocks with normal total alkalinity, while the concentration of potassium places them at the boundary between moderate and high-potassium rocks. We sought to determine the composition of primary acid melts by studying the composition of the silicate phase in homogeneous melt inclusions that were conserved in quartz phenocrysts hosted by volcanic rocks of varying ages. Practically all the melt inclusions we analyzed show increased total alkalies and are in the class of trachyrhyodacites and trachyrhyolites, with the varieties of the highest alkali content being alkaline rhyolites and comendites; the concentration of K₂O classifies them as subalkaline rocks; one also notes the increased alumina of the acid melts. The compositions and spatial locations of the melt inclusions in quartz phenocrysts provide evidence of a three-phase crystallization in magma chambers at different depths. According to the experimental data, the quartz phenocrysts crystallized in a water-saturated melt at pressures of 0.1 to 3.5 kbars.

An area where fresh volcanic ash has fallen was found to have concentrations of Th and U that exceed the background values by factors of 270 and 32, respectively, for natural waters and by factors of 35 and 6 for plants. The soils and bottom deposits were not enriched in Th and U after a single ashfall; however the Th/U ratio decreased in these natural media relative to the background values, indicating a genetic affinity with young ashes where the concentration of highly mobile (relative to thorium) uranium is higher compared with older ashes. For areas far from active ashfalls, where the soils were formed on acid ash, we found higher background concentrations of Th and U in soils, surface waters, and bottom deposits, as well as higher gamma-ray background values above the Earth’s surface relative to the areas where the soils were formed on basic and intermediate ashes. This research resulted in the identification of two radioecological provinces in Kamchatka, viz., a Northern and a Southern province.