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The 1906 eruption of Vesuvius: from magmatic to phreatomagmatic activity through the flashing of a shallow depth hydrothermal system

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Abstract

The April 1906 eruption of Vesuvius is the type-example of the “final eruptions” that close the short cycles of semi-persistent activity that characterized the volcano in the 1631–1944 period. The eruption had a marked explosive character that accompanied the emission of lava from several vents on the southern slopes of the volcano. The observed sequence of events was characterized by repeated fluctuations of the magma level within the conduit, by large lava fountains, by conduit partial collapses, and by the final explosive decapitation of the summit cone. Contemporary chronicles, although frequently contradictory, allow reconstruction of the eruption, which can be divided into four main phases: (1) lateral lava effusions; (2) lava fountains; (3) gas-pyroclasts column; (4) low dense clouds. Pyroclastic deposits of the Monte Somma ridge and northeastern slope can be related to observed and described events and mainly refer to the 2nd and 3rd phases. The increase in the degree of fragmentation of the juvenile component together with the marked increase of the lithic component and morphologic evidence emphasize the repeated occurrence of magmawater interaction. This was most spectacular in the 3rd phase of the eruption in which, after the decapitation of the cone, a high gas-pyroclasts eruption column was formed. Because of the nature of the lithic fragments (mainly hydrothermally altered and metasomatic rocks), the huge amount of steam, and the high lithic/juvenile ratio, it is unlikely that the largest part of the energy in play was related to the contact between magma and cold phreatic water. We suggest that most of the steam involved in this phase of the eruption came from flashing of the hydrothermal system connected to the very shallow feeding system of the volcano and formed as a consequence of repeated subsurface intrusions between 1872 and 1906. Juvenile products were ejected through the eruption, and represent (at least) two different magma bodies: the first (“older”) was erupted during the initial phase of the eruption and was exhausted at the beginning of the lava fountains phase, when fresh magma was involved in the eruption.

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Authors and Affiliations

  1. Gruppo Nazionale per la Vulcanologia, C.N.R., Via Nizza, 128, I-00198, Roma, Italy

    Antonella Bertagnini & Patrizia Landi

  2. Dipartimento di Scienze Della Terra, Universita' di Pisa, Via S. Maria, 53, I-56100, Pisa, Italy

    Antonella Bertagnini, Patrizia Landi, Roberto Santacroce & Alessandro Sbrana

  3. Istituto Internazionale di Vulcanologia, Piazza Roma, 2, I-95123, Catania, Italy

    Roberto Santacroce

Authors
  1. Antonella Bertagnini
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  2. Patrizia Landi
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  3. Roberto Santacroce
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  4. Alessandro Sbrana
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Bertagnini, A., Landi, P., Santacroce, R. et al. The 1906 eruption of Vesuvius: from magmatic to phreatomagmatic activity through the flashing of a shallow depth hydrothermal system. Bull Volcanol 53, 517–532 (1991). https://doi.org/10.1007/BF00298153

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  • DOI: https://doi.org/10.1007/BF00298153

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