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Volcanic activity at Sedankinsky Dol lava field, Sredinny Ridge, during the Holocene (Kamchatka, Russia) (2004)
Dirksen O.V., Bazanova L.I., Pletchov P.Yu., Portnyagin M.V., Bychkov K.A. Volcanic activity at Sedankinsky Dol lava field, Sredinny Ridge, during the Holocene (Kamchatka, Russia) // Abstracts. 4rd Biennial Workshop on Subduction Processes emphasizing the Kurile-Kamchatka-Aleutian Arcs (JKASP-4). Linkages among tectonics, seismicity, magma genesis, and eruption in volcanic arcs. August 21-27, 2004. Petropavlovsk-Kamchatsky: Institute of Volcanology and Seismology FEB RAS. 2004. P. 55
Volcanic ash on Bering Island (Commander Islands) and Kamchatkan Holocene Eruptions (1990)
Kirianov V.Yu., Egorova I.A., Litasova S.N. Volcanic ash on Bering Island (Commander Islands) and Kamchatkan Holocene Eruptions // Volcanology and Seismology. 1990. Vol. 8. № 6. P. 850-868.
Volcanic edifice stability during cryptodome intrusion (2001)
Donnadieu Franck, Merle Olivier, Besson Jean-Claude Volcanic edifice stability during cryptodome intrusion // Bulletin of Volcanology. 2001. Т. 63. № 1. С. 61-72. doi:10.1007/s004450000122.
   Аннотация
Limit equilibrium analyses were applied to the 1980 Mount St. Helens and 1956 Bezymianny failures in order to examine the influence on stability of structural deformation produced by cryptodome emplacement. Weakening structures associated with the cryptodome include outward-dipping normal faults bounding a summit graben and a flat shear zone at the base of the bulged flank generated by lateral push of the magma. Together with the head of the magmatic body itself, these structures serve directly to localize failure along a critical surface with low stability deep within the interior of the edifice. This critical surface, with the safety coefficient reduced by 25–30%, is then very sensitive to stability condition variation, in particular to the pore-pressure ratio (ru) and seismicity coefficient (n). For ru=0.3, or n=0.2, the deep surface suffers catastrophic failure, removing a large volume of the edifice flank. In the case of Mount St. Helens, failure occurred within a material with angle of friction ~40°, cohesion in the range 105–106 Pa, and probably significant water pore pressure. On 18 May 1980, detachment of slide block I occurred along a newly formed rupture surface passing through the crest of the bulge. Although sliding of block I may have been helped by the basal shear zone, significant pore pressure and a triggering earthquake were required (ru=0.3 and n=0.2). Detachment of the second block was guided by the summit normal fault, the front of the cryptodome, and the basal shear zone. This occurred along a deep critical surface, which was on the verge of failure even before the 18 May 1980 earthquake. The stability of equivalent surfaces at Bezymianny Volcano appears significantly higher. Thus, although magma had already reached the surface, weaker materials, or higher pore pressure and/or seismic conditions were probably required to reach the rupture threshold. From our analysis, we find that deep-seated sector collapses formed by removing the edifice summit cannot generally result from a single slide. Cryptodome-induced deformation does, however, provide a deep potential slip surface. As previously thought, it may assist deep-seated sector collapse because it favors multiple retrogressive slides. This leads to explosive depressurization of the magmatic and hydrothermal systems, which undermines the edifice summit and produces secondary collapses and explosive blasts.
Volcanic eruptions and seismic activity at Klyuchevskoi, Bezymiannyi and Shiveluch in 1986-1987 (1991)
Zharinov N.A., Gorelchik V.I., Belousov A.B., Belousova M.G., Garbuzova V.T., Demyanchuk Yu.V., Zhdanova E.Yu. Volcanic eruptions and seismic activity at Klyuchevskoi, Bezymiannyi and Shiveluch in 1986-1987 // Volcanology and Seismology. 1991. Vol. 12. Vol. 3. P. 327-345.
Volcanic hazards from Bezymianny- and Bandai-type eruptions (1987)
Siebert Lee, Glicken Harry, Ui Tadahide Volcanic hazards from Bezymianny- and Bandai-type eruptions // Bulletin of Volcanology. 1987. Vol. 49. Vol. 1. P. 435-459. doi: 10.1007/BF01046635.
Volcanic structure and composition of Old Shiveluch volcano, Kamchatka (2013)
Gorbach Natalia, Portnyagin Maxim, Tembrel Igor Volcanic structure and composition of Old Shiveluch volcano, Kamchatka // Journal of Volcanology and Geothermal Research. 2013. Vol. 263. P. 193-208. doi:10.1016/j.jvolgeores.2012.12.012.
Volcanic tsunami: a review of source mechanisms, past events and hazards in Southeast Asia (Indonesia, Philippines, Papua New Guinea) (2014)
Paris Raphaël, Switzer Adam D., Belousova Marina, Belousov Alexander, Ontowirjo Budianto, Whelley Patrick L., Ulvrova Martina Volcanic tsunami: a review of source mechanisms, past events and hazards in Southeast Asia (Indonesia, Philippines, Papua New Guinea) // Natural Hazards. 2014. Vol. 70. № 1. P. 447-470. doi:10.1007/s11069-013-0822-8.
Volcanic zone of the Kurile Islands (1961)
Gorshkov G.S. Volcanic zone of the Kurile Islands / Proceedings of the 9th Pacific Schience Congress. Bangkok, Thailand, November 18th to December 9th, 1957. Geology and Geophysics. Bangkok: Rama i Road.. Bangkok: Rama i Road.. 1961. Vol. 12. P. 185-190.
Volcanic-hydrothermal system of Baransky volcano, Iturup, Kurile islands (1995)
Taran Yuri, Yurova L.M. Volcanic-hydrothermal system of Baransky volcano, Iturup, Kurile islands // IUGG XXI General Assembley. 1995. P. VA41C - 6.
Volcaniclastic stratigraphy of Gede Volcano, West Java, Indonesia: How it erupted and when (2015)
Belousov Alexander, Belousova Marina, Krimer D., Costa F., Prambada O., Zaennudin A. Volcaniclastic stratigraphy of Gede Volcano, West Java, Indonesia: How it erupted and when // Journal of Volcanology and Geothermal Research. 2015. Vol. 301. P. 238-252.