Shallow magma convection evidenced by excess degassing and thermal radiation during the dome-forming Sabancaya eruption (2012–2020)

We used a large set of satellite- (visible, infrared, and radar images from Planetscope, MODIS, VIIRS, Sentinel2, Landsat 8, and Sentinel 1) and ground-based data (optical images, SO2 flux, shallow seismicity) to describe and characterize the activity of the Sabancaya volcano during the unrest and eruption phases that occurred between 2012 and 2020. The unrest phase (2012–2016) was characterized by increasing gas and thermal flux, sourced by a convective magma column rising along with the remnants of a buried plug still permeable to fluid flow. Conversely, a new conduit, adjacent to the previo... Mehr ...

Verfasser: Coppola, Diego
Valade, Sébastien A.
Masías Alvarez, Pablo Jorge
Laiolo, Marco
Massimetti, Francesco
Campus, Adele
Aguilar Contreras, Rigoberto
Anccasi Figueroa, Rosa María
Apaza Choquehuayta, Fredy Erlingtton
Ccallata Pacsi, Beto
Cigolini, Corrado
Cruz Mamani, Luis Fernando
Finizola, Anthony
Gonzales Zúñiga, Katherine
Macedo Sánchez, Orlando
Miranda Cruz, Rafael
Ortega Gonzáles, Mayra Alexandra
Paxi Zamalloa, Rosario
Taipe Maquerhua, Edu Luis
Valdivia Humerez, David
Dokumenttyp: Artikel
Erscheinungsdatum: 2022
Verlag/Hrsg.: Springer Berlin Heidelberg
Schlagwörter: Volcanes / Magmatismo / Erupciones volcánicas / Energía geotérmica / Actividad eruptiva
Sprache: Englisch
Permalink: https://search.fid-benelux.de/Record/base-29238377
Datenquelle: BASE; Originalkatalog
Powered By: BASE
Link(s) : https://hdl.handle.net/20.500.12544/3842

We used a large set of satellite- (visible, infrared, and radar images from Planetscope, MODIS, VIIRS, Sentinel2, Landsat 8, and Sentinel 1) and ground-based data (optical images, SO2 flux, shallow seismicity) to describe and characterize the activity of the Sabancaya volcano during the unrest and eruption phases that occurred between 2012 and 2020. The unrest phase (2012–2016) was characterized by increasing gas and thermal flux, sourced by a convective magma column rising along with the remnants of a buried plug still permeable to fluid flow. Conversely, a new conduit, adjacent to the previous one, fed the eruptive phase (2016–2020) which was instead characterized by a discontinuous extrusive activity, with phases of dome growth (at rates from 0.04 to 0.75 m3 s−1) and collapse. The extrusive activity was accompanied by fluctuating thermal anomalies (0.5–25 MW), by irregular SO2 degassing (700–7000 tons day−1), and by variable explosive activity (4–100 events d−1) producing repeated vulcanian ash plumes (500–5000 m above the crater). Magma budget calculation during the eruptive phase indicates a large excess of degassing, with the volume of degassed magma (0.25–1.28 km3) much higher than the volume of erupted magma (< 0.01 km3). Similarly, the thermal energy radiated by the eruption was much higher than that sourced by the dome itself, an unbalance that, by analogy with the degassing, we define as “excess thermal radiation”. Both of these unbalances are consistent with the presence of shallow magma convection that fed the extrusive and explosive activity of the Sabancaya dome.