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Bulletin of Volcanology

Resumen/Descripción – provisto por la editorial en inglés
Bulletin of Volcanology was founded in 1922, as Bulletin Volcanologique, and is the official journal of the International Association of Volcanology and Chemistry of the Earth’s Interior (IAVCEI). The Bulletin of Volcanology publishes papers on volcanoes, their products, their eruptive behavior, and their hazards. Papers aimed at understanding the deeper structure of volcanoes, and the evolution of magmatic systems using geochemical, petrological, and geophysical techniques are also published. Material is published in four sections: Review Articles; Research Articles; Short Scientific Communications; and a Forum that provides for discussion of controversial issues and for comment and reply on previously published Articles and Communications.
Palabras clave – provistas por la editorial

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Disponibilidad
Institución detectada Período Navegá Descargá Solicitá
No detectada desde abr. 1997 / hasta dic. 2023 SpringerLink

Información

Tipo de recurso:

revistas

ISSN impreso

0258-8900

ISSN electrónico

1432-0819

País de edición

Alemania

Fecha de publicación

Tabla de contenidos

A window on mantle-derived magmas within the Central Andes: eruption style transitions at Cerro Overo maar and La Albóndiga lava dome, northern Chile

Gabriel UretaORCID; Károly Németh; Felipe Aguilera; Martin Zimmer; Andrew Menzies

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Change of eruptive style during Pliocene deglaciation: from scoria cones to lava shields in southern extra-Andean Patagonia, Argentina

Mauricio González GuillotORCID; Juan Federico Ponce

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Analysis of the 2020 Taal Volcano tephra fall deposits from crowdsourced information and field data

M. I. R. Balangue-Tarriela; A. M. F. LagmayORCID; D. M. Sarmiento; J. Vasquez; M. C. Baldago; R. Ybañez; A. A. Ybañez; J. R. Trinidad; S. Thivet; L. Gurioli; B. Van Wyk de Vries; M. Aurelio; D. J. Rafael; A. Bermas; J. A. Escudero

<jats:title>Abstract</jats:title><jats:p>After 43 years of dormancy, Taal Volcano violently erupted in January 2020 forming a towering eruption plume. The fall deposits covered an area of 8605 km<jats:sup>2</jats:sup>, which includes Metro Manila of the National Capital Region of the Philippines. The tephra fall caused damage to crops, traffic congestion, roof collapse, and changes in air quality in the affected areas. In a tropical region where heavy rains are frequent, immediate collection of data is crucial in order to preserve the tephra fall deposit record, which is readily washed away by surface water runoff and prevailing winds. Crowdsourcing, field surveys, and laboratory analysis of the tephra fall deposits were conducted to document and characterize the tephra fall deposits of the 2020 Taal Volcano eruption and their impacts. Results show that the tephra fall deposit thins downwind exponentially with a thickness half distance of about 1.40 km and 9.49 km for the proximal and distal exponential segments, respectively. The total calculated volume of erupted fallout deposit is 0.057 km<jats:sup>3</jats:sup>, 0.042 km<jats:sup>3</jats:sup>, or 0.090 km<jats:sup>3</jats:sup> using the exponential, power-law, and Weibull models, respectively, and all translate to a VEI of 3. However, using a probabilistic approach (Weibull method) with 90% confidence interval, the volume estimate is as high as 0.097 km<jats:sup>3</jats:sup>. With the addition of the base surge deposits amounting to 0.019 km<jats:sup>3</jats:sup>, the volume translates to a VEI of 4, consistent with the classification for the observed height and umbrella radius of the 2020 main eruption plume. VEI 4 is also consistent with the calculated median eruption plume height of 17.8 km and sub-plinian classification based on combined analysis of isopleth and isopach data. Phreatomagmatic activity originated from a vent located in Taal Volcano’s Main Crater Lake (MCL), which contained 42 million m<jats:sup>3</jats:sup> of water. This eruptive style is further supported by the characteristics of the ash grain components of the distal 12 January 2020 tephra fall deposits, consisting dominantly of andesitic vitric fragments (83–90%). Other components of the fall deposits are lithic (7–11%) and crystal (less than 6%) grains. Further textural and geochemical analysis of these tephra fall deposits contributes to better understand the volcanic processes that occurred at Taal Volcano, one of the 16 Decade Volcanoes identified by the International Association of Volcanology and Chemistry of the Earth’s Interior (IAVCEI) because of its destructive nature and proximity to densely populated areas. The crowdsourcing initiative provided a significant portion of the data used for this study while at the same time educating and empowering the community to build resilience.</jats:p>

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Scattering and intrinsic absorption parameters of Rayleigh waves at 18 active volcanoes in Japan inferred using seismic interferometry

Takashi HiroseORCID; Hideki Ueda; Eisuke Fujita

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Synthetic aperture radar volcanic flow maps (SAR VFMs): a simple method for rapid identification and mapping of volcanic mass flows

Michael P. PolandORCID

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

The effect of wind and plume height reconstruction methods on the accuracy of simple plume models — a second look at the 2010 Eyjafjallajökull eruption

Tobias DürigORCID; Magnús T. Gudmundsson; Thorbjörg Ágústsdóttir; Thórdís Högnadóttir; Louise S. Schmidt

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Correction to: Comment on “Effects in North Africa of the 934–940 CE Eldgjá and 1783–1784 CE Laki eruptions (Iceland) revealed by previously unrecognized written sources” by Brugnatelli, V., and Tibaldi, A. [Bull. Volcanol. (2020) 82:73]

Timothy P. NewfieldORCID; Clive OppenheimerORCID

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

P-, S-wave velocity and VP/VS of the Colima Volcanic Complex from local earthquake tomography

Christian R. Escudero

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Calibration strategies of PDC kinetic energy models and their application to the construction of hazard maps

A. AravenaORCID; A. Bevilacqua; M. de’ Michieli Vitturi; T. Esposti Ongaro; A. Neri; R. Cioni

Palabras clave: Geochemistry and Petrology.

Pp. No disponible

Open-vent volcanoes fuelled by depth-integrated magma degassing

M. EdmondsORCID; E.J. Liu; K.V. Cashman

<jats:title>Abstract</jats:title><jats:p>Open-vent, persistently degassing volcanoes—such as Stromboli and Etna (Italy), Villarrica (Chile), Bagana and Manam (Papua New Guinea), Fuego and Pacaya (Guatemala) volcanoes—produce high gas fluxes and infrequent violent strombolian or ‘paroxysmal’ eruptions that erupt very little magma. Here we draw on examples of open-vent volcanic systems to highlight the principal characteristics of their degassing regimes and develop a generic model to explain open-vent degassing in both high and low viscosity magmas and across a range of tectonic settings. Importantly, gas fluxes from open-vent volcanoes are far higher than can be supplied by erupting magma and independent migration of exsolved volatiles is integral to the dynamics of such systems. The composition of volcanic gases emitted from open-vent volcanoes is consistent with its derivation from magma stored over a range of crustal depths that in general requires contributions from both magma decompression (magma ascent and/or convection) and iso- and polybaric second boiling processes. Prolonged crystallisation of water-rich basalts in crustal reservoirs produces a segregated exsolved hydrous volatile phase that may flux through overlying shallow magma reservoirs, modulating heat flux and generating overpressure in the shallow conduit. Small fraction water-rich melts generated in the lower and mid-crust may play an important role in advecting volatiles to subvolcanic reservoirs. Excessive gas fluxes at the surface are linked to extensive intrusive magmatic activity and endogenous crustal growth, aided in many cases by extensional tectonics in the crust, which may control the longevity and activity of open-vent volcanoes. There is emerging abundant geophysical evidence for the existence of a segregated exsolved magmatic volatile phase in magma storage regions in the crust. Here we provide a conceptual picture of gas-dominated volcanoes driven by magmatic intrusion and degassing throughout the crust.</jats:p>

Palabras clave: Geochemistry and Petrology.

Pp. No disponible