Old magma and a new, intrusive trigger: using diffusion chronometry to understand the rapid-onset Calbuco eruption, April 2015 (Southern Chile)

In April 2015, an unpredicted rapid-onset eruption occurred at Calbuco Volcano, Southern Andes of Chile. This event consisted of two, sub-Plinian eruptions separated by a few hours. By analysis of Fe–Ti exchange between ilmenite and titanomagnetite crystals in samples of erupted material, we determi...

Full description

Saved in:
Bibliographic Details
Published inContributions to mineralogy and petrology Vol. 174; no. 7; pp. 1 - 11
Main Authors Morgado, Eduardo, Morgan, Daniel J., Castruccio, Angelo, Ebmeier, Susanna K., Parada, Miguel-Ángel, Brahm, Raimundo, Harvey, Jason, Gutiérrez, Francisco, Walshaw, Richard
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.07.2019
Springer
Springer Nature B.V
Subjects
Analysis
Crystals
Density currents
Earth and Environmental Science
Earth Sciences
Geology
Heat exchange
Heating
Ilmenite
Iron
Lava
Mafic magma
Magma
Measuring instruments
Mineral Resources
Mineralogy
Original Paper
Oxides
Petrology
Recording
Reservoirs
Residence time
Residential density
Temperature
Titanium
Volcanic eruptions
Volcanoes
Chile
Magmatic timescales
Calbuco volcano
Rapid-onset eruption
Fe–Ti oxides
Diffusion chronometry
Online AccessGet full text

Cover

More Information
Summary:In April 2015, an unpredicted rapid-onset eruption occurred at Calbuco Volcano, Southern Andes of Chile. This event consisted of two, sub-Plinian eruptions separated by a few hours. By analysis of Fe–Ti exchange between ilmenite and titanomagnetite crystals in samples of erupted material, we determine timescales of pre-eruptive heating experienced at the partially solidified chamber base and constrain the magma residence time for the bulk of the carrier magma. Analysis of the Fe–Ti oxide pairs from a sample retrieved from a pyroclastic density current deposit (Cal-160) shows that it was affected by a significant heating event (recording 70–220 °C of heating), while other collected samples did not record this late heating. This sample is interpreted to represent a piece of crystal mush located at the bottom of a prolate, ellipsoidal mush reservoir, mobilised < 4 days before the eruption by a triggering pulse of mafic magma considerably hotter than the typical magmatic temperature of the reservoir. Another two fall deposit samples (lapillus, Cal-149Tb and Cal-155) of the eruption are interpreted to represent resident, eruptible magmas that did not interact with any magma recharge immediately prior to or during the eruption. We infer that these magmas had been at eruption temperature for some years based on their extensively equilibrated Fe–Ti oxides.
ISSN:0010-7999
1432-0967
DOI:10.1007/s00410-019-1596-0