Spokoiny Volcano. Bibliography
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Braitseva O.A., Ponomareva V.V., Melekestsev I.V., Sulerzhitskiy L.D., Pevzner M.M. Holocene Kamchatka volcanoes. 2002.
Ponomareva V.V., Churikova T., Melekestsev I.V., Braitseva O.A., Pevzner M., Sulerzhitskii L. Late Pleistocene-Holocene Volcanism on the Kamchatka Peninsula, Northwest Pacific Region / Volcanism and Subduction: The Kamchatka Region. Washington, D. C.: American Geophysical Union. 2007. Vol. 172. P. 165-198. doi: 10.1029/172GM15.
Late Pleistocene-Holocene volcanism in Kamchatka results from the subduction of the
Pacific Plate under the peninsula and forms three volcanic belts arranged in en echelon manner
from southeast to northwest. The cross-arc extent of recent volcanism exceeds 250 km and
is one of the widest worldwide. All the belts are dominated by mafic rocks. Eruptives with
SiO2>57% constitute ~25% of the most productive Central Kamchatka Depression belt and
~30% of the Eastern volcanic front, but <10% of the least productive Sredinny Range belt.
All the Kamchatka volcanic rocks exhibit typical arc-type signatures and are represented
by basalt-rhyolite series differing in alkalis. Typical Kamchatka arc basalts display a strong
increase in LILE, LREE and HFSE from the front to the back-arc. La/Yb and Nb/Zr increase
from the arc front to the back arc while B/Li and As, Sb, B, Cl and S concentrations decrease.
The initial mantle source below Kamchatka ranges from N-MORB-like in the volcanic front
and Central Kamchatka Depression to more enriched in the back arc. Rocks from the Central
Kamchatka Depression range in 87Sr/86Sr ratios from 0.70334 to 0.70366, but have almost
constant Nd isotopic ratios (143Nd/144Nd 0.51307–0.51312). This correlates with the highest
U/Th ratios in these rocks and suggest the highest fluid-flux in the source region.
Holocene large eruptions and eruptive histories of individual Holocene volcanoes have been
studied with the help of tephrochronology and 14C dating that permits analysis of time-space
patterns of volcanic activity, evolution of the erupted products, and volcanic hazards.
Ponomareva Vera V., Melekestsev Ivan V., Dirksen Oleg V. Sector collapses and large landslides on Late Pleistocene–Holocene volcanoes in Kamchatka, Russia // Journal of Volcanology and Geothermal Research. 2006. Vol. 158. № 1-2. P. 117-138. doi:10.1016/j.jvolgeores.2006.04.016.
On Kamchatka, detailed geologic and geomorphologic mapping of young volcanic terrains and observations on historical eruptions reveal that landslides of various scales, from small (0.001 km3) to catastrophic (up to 20–30 km3), are widespread. Moreover, these processes are among the most effective and most rapid geomorphic agents. Of 30 recently active Kamchatka volcanoes, at least 18 have experienced sector collapses, some of them repetitively. The largest sector collapses identified so far on Kamchatka volcanoes, with volumes of 20–30 km3 of resulting debris-avalanche deposits, occurred at Shiveluch and Avachinsky volcanoes in the Late Pleistocene. During the last 10,000 yr the most voluminous sector collapses have occurred on extinct Kamen' (4–6 km3) and active Kambalny (5–10 km3) volcanoes. The largest number of repetitive debris avalanches (> 10 during just the Holocene) has occurred at Shiveluch volcano. Landslides from the volcanoes cut by ring-faults of the large collapse calderas were ubiquitous. Large failures have happened on both mafic and silicic volcanoes, mostly related to volcanic activity. Orientation of collapse craters is controlled by local tectonic stress fields rather than regional fault systems.

Specific features of some debris avalanche deposits are toreva blocks — huge almost intact fragments of volcanic edifices involved in the failure; some have been erroneously mapped as individual volcanoes. One of the largest toreva blocks is Mt. Monastyr' — a ∼ 2 km3 piece of Avachinsky Somma involved in a major sector collapse 30–40 ka BP.

Long-term forecast of sector collapses on Kliuchevskoi, Koriaksky, Young Cone of Avachinsky and some other volcanoes highlights the importance of closer studies of their structure and stability.
Огородов Н.В., Кожемяка Н.Н., Важеевская А.А., Огородова А.С. Вулканы и четвертичный вулканизм Срединного хребта Камчатки / Отв. ред. Эрлих Э.Н. М.: Наука. 1972. 191 с.
Первая часть работы посвящена основным вопросам четвертичного вулканизма Срединного хребта Камчатки. Рассматривается соотношение пород фундамента и четвертичных эффузивов, расчленение четвертичных эффузивов на отдельные возрастные комплексы и выделяются два этапа в четвертичном вулканическом цикле излияний. Приводится характеристика особенностей вулканической деятельности обоих этапов, петрографо-петрохимический анализ продуктов извержений, а также рассматривается структурное положение четвертичных эффузивов и доказывается, что выделенные этапы четвертичного вулканизма соответствуют определенным стадиям геосинклинального цикла в развитии земной коры. В заключение приводятся история четвертичного вулканизма, геологический эффект четвертичных излияний, а также сравнительная характеристика его с другими вулканическими зонами Камчатки и сопредельными территориями.
Певзнер М.М. Голоценовый вулканизм Срединного хребта Камчатки Труды Геологического института. / Отв. ред. Федонкин М.А. М.: ГЕОС. 2015. Вып. 608. 252 с.
The monograph is devoted to the spatio-temporal activation of Holocene volcanism within the Miocene-Quaternary volcanic zone of the Sredinny Range of Kamchatka. The pattern of volcanic activation, grouping elements and periodic pulses of endogenous activity, as well as their chronological relationship with episodes of endogenous activity increasing of the North Pacific. The characteristics of individual volcanic centers and the largest eruptions are provided. Age determinations of eruptions are based on detailed tephrochronological research and extensive radiocarbon dating.
For a wide range of professionals in the field of geology, geochronology, volcanology, petrology, geography,
geomorphology, paleoclimatology, ecology and geobotany.
Певзнер М.М. Северная граница вулканической активности Камчатки в голоцене // Вестник КРАУНЦ. Серия: Науки о Земле. 2010. Вып. 15. № 1. С. 117-144.
The paper presents data on specified northern boundary of the Holocene volcanic activity in Kamchatka. This boundary is located 80 km to the north for the frontal volcanic zone and 180 km to the northwest from Sheveluch Volcano for the zone of the Sredinny Range. For the first time numerous evidence for the Holocene volcanic activity within the Kamchatkan zones with no deep seismicity and located to the north from the Aleutian transform fault were detected, studied and dated using geologic methods and isotope geochemistry. Radiocarbon age for the eruptions was estimated.
Певзнер М.М., Волынец А.О. Голоценовый вулканизм Срединного хребта Камчатки // Проблемы эксплозивного вулканизма (к 50-летию катастрофического извержения вулкана Безымянный). Материалы первого международного симпозиума. Петропавловск-Камчатский, 25-30 марта 2006 г. Петропавловск-Камчатский: ИВиС ДВО РАН. 2006. С. 124-132.
Numerous Holocene volcanic centres (5 stratovolcanoes, including 4 active and potentially dangerous, and 12 monogenetic centres) are discovered within Sredinny Range of Kamchatka. Their exact ages are determined. Spatial and temporal characteristics, as well as composition of Holocene volcanic rocks witness against direct connection of magma genesis with contemporary Pacific plate subduction. Sub-meridional chronological trends and elements of grouping, identified for Holocene volcanic activity of Sredinny Range of Kamchatka, may indicate seismo-geodynamical nature of young volcanic activity and associated with it advection in the extinct island arc system.
Пономарева В.В., Чурикова Т.Г., Мелекесцев И.В., Брайцева О.А., Певзнер М.М., Сулержицкий Л.Д. Позднеплейстоцен-голоценовый вулканизм Камчатки / Изменение окружающей среды и климата: природные и связанные с ними техногенные катастрофы. Том II. Новейший вулканизм северной Евразии: закономерности развития, вулканическая опасность, связь с глубинными процессами и изменениями природной среды и климата. М.: ИГЕМ РАН. 2008. С. 19-40.
Изменение окружающей среды и климата: природные и связанные с ними техногенные катастрофы. Том II. Новейший вулканизм северной Евразии: закономерности развития, вулканическая опасность, связь с глубинными процессами и изменениями природной среды и климата. М., Изд-во ИГЕМ; 2008, с. 19-40