Group by:  
Records: 2604
Арсанова Г.И. Сверхкритическое состояние воды как причина вулканических явлений // The Scientific Heritage. 2020. Т. 2. № 45. С. 7-17.
Features of the dynamics of volcanic eruptions for the first time are explained as a consequence of the properties of high-temperature phases of water and their transitions. Some properties of water in supercritical (fluid) condition are given. The latter determine the nature of the relationship between water and melt in the volcanic process, which in turn explains the explosions of different power, the rapidity of scorching clouds, the transfer of gases to the foot of volcanoes, breakouts and landslides on the slopes, the occurrence of ash, pumice, pseudoliquefied mass, as well as possibly ignimbrits and volcanic glass. It shows the impossibility of penetration of cold water into the active volcanic channel, as well as their high (before the change of phase) heating in the conditions of the crust.
Артамонов А.В. Подводные горы системы поднятий Маркус-Неккер (Тихий океан): особенности строения и магматизма // Вестник КРАУНЦ. Серия: Науки о Земле. 2016. Вып. 31. № 3.
The paper presents geological and geochemical characteristics of Cretaceous guyots of Marcus-Necker intraplate rise in the Pacific Ocean. Comparison of guyots located in different parts of the extended system revealed significant differences in their geochemical characteristics, which suggest lateral and (or) vertical mantle heterogeneity in the region. The studied volcanic rocks belong to the alkaline series. In some cases, they exhibit low values of Na2O/K2O. This volcanism is not typical for most of intraplate ocean rises. No consistency is observed between volcanic rock composition of guyots, their age and (or) geographic position. A complex pattern of magnetic anomaly lineations and irregular location of seamounts of different age cause difficulties in applying hot spot model to explain the formation of this intraplate magmatic province. The location of seamounts in the structure of the rise system and the entire system in the structure of the Pacific Ocean does not contradict the formation of fault zones, which initiate melting of upper mantle geochemically inhomogeneous substrate and lead to the formation of intraplate rises. Deep fluid flows may cause a large-scale melting of the upper mantle.
Бабаянц П.С., Блох Ю.И., Бондаренко В.И., Рашидов В.А., Трусов А.А. Применение пакета программ структурной интерпретации СИГМА-3D при изучении подводных вулканов Курильской островной дуги // Вестник КРАУНЦ. Серия: Науки о Земле. 2005. Вып. 6. № 2. С. 67-76.
SIGMA-3D software package of structural interpretation is an effective tool for the automated three-dimensional modeling while studying magnetic anomalies created by underwater volcanoes. With the help of this software package submarine volcanoes Grigorieva, Krylatka, and Yubileiny, located in the Kurile island arc, have been studied.
Бабаянц П.С., Блох Ю.И., Трусов А.А. Возможности структурно-вещественного картирования по данным магниторазведки и гравиразведки в пакете программ СИГМА-3D // Геофизический вестник. 2004. № 3. С. 11-15.
Базанова Л.И., Брайцева О.А., Дирксен О.В., Сулержицкий Л.Д., Данхара Т. Пеплопады крупнейших голоценовых извержений на траверсе Усть-Большерецк - Петропавловск-Камчатский: источники, хронология, частота // Вулканология и сейсмология. 2005. № 6. С. 30-46.
Базанова Л.И., Брайцева О.А., Иванов Б.В., Мелекесцев И.В. Декадный вулкан Авачинский на Камчатке // Вестник ДВО РАН. 1999. № 3. С. 126-135.
Базанова Л.И., Брайцева О.А., Мелекесцев И.В., Пузанков М.Ю. Оценка вулканической опасности от Авачинского вулкана, Камчатка, Россия // Взаимосвязь между тектоникой, сейсмичностью, магмообразованием и извержениями вулканов в вулканических дугах. Материалы IV Международного совещания по процессам в зонах субдукции Японской, Курило-Камчатской и Алеутской островных дуг. Петропавловск-Камчатский: ИВиС ДВО РАН. 2004. С. 51-52.
Базанова Л.И., Брайцева О.А., Мелекесцев И.В., Пузанков М.Ю. Потенциальная опасность от извержений Авачинского вулкана / Геодинамика и вулканизм Курило-Камчатской островодужной системы. Петропавловск-Камчатский: ИВГиГ ДВО РАН. 2001. С. 390-407.
History of eruptive activity of Avachinsky volcano over the last 10 mln years has been reconstructed; age, frequency and parameters of the past eruptions, character and scale of potentially hazardous volcanic phenomena have been determined. Assessment of volcanic hazard has been given associated with the activity of Molodoi cone which began its formation 38000 years ago. Specific features of its eruption are used as the basis for the map of volcanic hazard for adjacent territories.
Базанова Л.И., Брайцева О.А., Мелекесцев И.В., Сулержицкий Л.Д. Катастрофические извержения Авачинского вулкана (Камчатка) в голоцене: хронология, динамика, геолого-геоморфологический и экологический эффекты, долгосрочный прогноз // Вулканология и сейсмология. 2004. № 6. С. 15-20.
Five major explosive eruptions discharging pyroclastic volumes of more than 1 km^3 have been identified in the Holocene eruptive history of Avacha Volcano. All of these were Plinian-type eruptions, three (of andesitic composition) occurring 7150, 5500 and 4500 14C B.P. Two eruptions (3500 and 3280 14C B.P.) that supplied andesitic basalts preceded or started the formation of Young Cone on Avacha Volcano. We have reconstructed the dynamics and parameters of the eruptions, assessed their geologic, geomorphic and ecologic effects, and provided a long-term forecast.
Базанова Л.И., Брайцева О.А., Пузанков М.Ю., Сулержицкий Л.Д. Катастрофические плинианские извержения начальной фазы формирования молодого конуса вулкана Авачинский (Камчатка) // Вулканология и сейсмология. 2003. № 5. С. 20-40.
This paper discusses two catastrophic Plinian-type eruptions which occurred close enough in time (IIAV1 -3500 and IIAV3 - 3280 14C yrs B.P.) on Avacha Volcano and initiated the activity of its Young Cone. We studied the stratigraphy of the ejecta, reconstructed their chronology and parameters, assessed their environmental impact. The ejecta of both of these eruptions were dominated by tephra whose volume is >3 and >1.1 km3, respectively. The eruptive columns rose as high as 21-28 km. The IIAV1 ash layer can be followed for 300 km northeast of the volcano, the ashfall area enclosed within the 1 cm isopach being about 50000 km2. Both eruptions were accompanied by pyroclastic flows, surges, and catastro3phic lahars. The juvenile3pyroclastics is basaltic andesite. By the values of total discharge volume (>3.6 km3 for IIAV1 and >1.21 km3 for IIAV3), these eruptions must be among the largest to have occurred during the eruptive history of the Young Cone.