Explosive volcanism (VEI 6) without caldera formation: insight from Huaynaputina volcano, southern Peru |
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Authors: | Yan Lavallée Shanaka L de Silva Guido Salas Jeffrey M Byrnes |
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Institution: | 4. Department für Geo- und Umweltwissenschaften, Ludwig-Maximilians Universit?t, Theresienstrasse 41/III, 80333, München, Germany 1. Department of Space Studies, University of North Dakota, 4149 Campus Road, Grand Forks, ND, 58202, USA 2. Escuela de Ingeniería Geofisica, Universidad Nacional de San Agustin, Av. Independencia s/n, Edificio Antiguo 3er Piso, Arequipa, Peru 3. Department of Geology and Planetary Science, University of Pittsburgh, 4107 O’Hara Street, 200 SRCC, Pittsburgh, PA, 15260, USA
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Abstract: | Through examination of the vent region of Volcán Huaynaputina, Peru, we address why some major explosive eruptions do not
produce an equivalent caldera at the eruption site. Here, in 1600, more than 11 km3 DRE (VEI 6) were erupted in three stages without developing a volumetrically equivalent caldera. Fieldwork and analysis of
aerial photographs reveal evidence for cryptic collapse in the form of two small subsidence structures. The first is a small
non-coherent collapse that is superimposed on a cored-out vent. This structure is delimited by a partial ring of steep faults
estimated at 0.85 by 0.95 km. Collapse was non-coherent with an inwardly tilted terrace in the north and a southern sector
broken up along a pre-existing local fault. Displacement was variable along this fault, but subsidence of approximately 70 m
was found and caused the formation of restricted extensional gashes in the periphery. The second subsidence structure developed
at the margin of a dome; the structure has a diameter of 0.56 km and crosscuts the non-coherent collapse structure. Subsidence
of the dome occurred along a series of up to seven concentric listric faults that together accommodate approximately 14 m
of subsidence. Both subsidence structures total 0.043 km3 in volume, and are much smaller than the 11 km3 of erupted magma. Crosscutting relationships show that subsidence occurred during stages II and III when ∼2 km3 was erupted and not during the main plinian eruption of stage I (8.8 km3).
The mismatch in erupted volume vs. subsidence volume is the result of a complex plumbing system. The stage I magma that constitutes
the bulk of the erupted volume is thought to originate from a ∼20-km-deep regional reservoir based on petrological constraints
supported by seismic data. The underpressure resulting from the extraction of a relatively small fraction of magma from the
deep reservoir was not sufficient enough to trigger collapse at the surface, but the eruption left a 0.56-km diameter cored-out
vent in which a dome was emplaced at the end of stage II. Petrologic evidence suggests that the stage I magma interacted with
and remobilized a shallow crystal mush (∼4–6 km) that erupted during stage II and III. As the crystal mush erupted from the
shallow reservoir, depressurization led to incremental subsidence of the non-coherent collapse structure. As the stage III
eruption waned, local pressure release caused subsidence of the dome. Our findings highlight the importance of a connected
magma reservoir, the complexity of the plumbing system, and the pattern of underpressure in controlling the nature of collapse
during explosive eruptions. Huaynaputina shows that some major explosive eruptions are not always associated with caldera
collapse.
Editorial responsibility: J Stix |
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Keywords: | Caldera Non-coherent collapse structure Summit pit crater Lava dome subsidence Magma pressure change Pre-existing fault Huaynaputina volcano Southern Peru |
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