Tracking a Pyroclastic Density Current With Seismic Signals at Mt. Etna (Italy)
Language
English
Obiettivo Specifico
5V. Processi eruttivi e post-eruttivi
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Issue/vol(year)
/128 (2023)
ISSN
2169-9356
Publisher
Wiley-AGU
Pages (printed)
e2022JB026114
Date Issued
2023
Abstract
Pyroclastic density currents (PDCs) are dangerous flows of volcanic rock and gas that are the
most deadly proximal volcano hazard. There is significant interest in better understanding PDC dynamics,
however, they are challenging to study due to their extreme hazard, unpredictable occurrence, and because
complex internal dynamics are obscured by visually opaque clouds of ash. PDCs exert forces on Earth's surface
and generate seismic waves. Here, we use seismic data recorded by the permanent monitoring network at Mt.
Etna (Italy) to track the 11 February 2014 PDC at second-scale temporal resolution and calculate a maximum
velocity of 76 m/s (274 km/hr). We identify multiple pulses and show that the late-stage source locations
correspond with the mapped coarse-grained PDC deposits. High temporal and spatial resolution measurements
of PDC movement from seismic data can be used to inform numerical modeling of PDC dynamics and aid
in hazard assessment by improving our understanding of PDC flow paths. This work illustrates how seismic
signals can be used to track surficial mass movements in real-time.
most deadly proximal volcano hazard. There is significant interest in better understanding PDC dynamics,
however, they are challenging to study due to their extreme hazard, unpredictable occurrence, and because
complex internal dynamics are obscured by visually opaque clouds of ash. PDCs exert forces on Earth's surface
and generate seismic waves. Here, we use seismic data recorded by the permanent monitoring network at Mt.
Etna (Italy) to track the 11 February 2014 PDC at second-scale temporal resolution and calculate a maximum
velocity of 76 m/s (274 km/hr). We identify multiple pulses and show that the late-stage source locations
correspond with the mapped coarse-grained PDC deposits. High temporal and spatial resolution measurements
of PDC movement from seismic data can be used to inform numerical modeling of PDC dynamics and aid
in hazard assessment by improving our understanding of PDC flow paths. This work illustrates how seismic
signals can be used to track surficial mass movements in real-time.
Type
article
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