Stratigraphically controlled sampling captures the onset of highly fluid-fluxed melting at San Jorge volcano, Southern Volcanic Zone, Chile

Volcanological studies coupled with detailed geochemistry can reveal important aspects regarding the melting and ascent processes of a magmatic body. The explosive part of the eruption giving rise to scoria and tephra deposits can hold a wealth of information which can complement chemical analyses o...

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Bibliographic Details
Published inContributions to mineralogy and petrology Vol. 174; no. 12; pp. 1 - 24
Main Authors McGee, Lucy, Morgado, Eduardo, Brahm, Raimundo, Parada, Miguel-Ángel, Vinet, Nicolas, Lara, Luis E., Flores, Andres, Turner, Michael, Handley, Heather, Nowell, Geoff
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.12.2019
Springer
Springer Nature B.V
Subjects
Ascent
Basalt
Chemical analysis
Composition
Crystallization
Earth and Environmental Science
Earth Sciences
Geochemistry
Geology
Isotopes
Lava
Lava flows
Magma
Melting
Mineral Resources
Mineralogy
Organic chemistry
Original Paper
Petrology
Radium
Rocks
Sampling
Sediments (Geology)
Sequencing
Silica
Silicon dioxide
Stratigraphy
Tephra
Trace elements
Uranium
Volcanic activity
Volcanic eruptions
Volcanoes
Chile
U-series
Magma genesis
Ra excess
Fluid-flux melting
Chile
Southern Volcanic Zone
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Summary:Volcanological studies coupled with detailed geochemistry can reveal important aspects regarding the melting and ascent processes of a magmatic body. The explosive part of the eruption giving rise to scoria and tephra deposits can hold a wealth of information which can complement chemical analyses of lava flows, however, it is often poorly exposed. A well-exposed scoria deposit and lava flow at the small eruptive center (SEC) San Jorge near Pucón in the Southern Volcanic Zone (SVZ), Chile, provides an opportunity to examine melting and storage processes in a primitive magma body almost in ‘real time’ through sampling up the stratigraphy of the deposit. This dataset comprises whole rock major and trace element chemistry, Sr–Nd and U-Th–Ra isotopes, in addition to mineral data through the eruption sequence. San Jorge whole rock compositions are unique in the area (MgO 10–12 wt%, SiO 2 50–52 wt%, Cr 600–900 ppm) and the studied tephras extend to the highest uranium- and radium-excesses yet measured in the SVZ. The unusual composition of the volcanic material displays similarities to rocks from the arc-front stratovolcano Villarrica but is distinct from other stratovolcanoes in the area, which exhibit greater influence from sediment input to the source, crustal assimilation and prolonged storage. We model the San Jorge magmas as a mixture of melts originating from highly fluid-fluxed, depleted mantle and fractionated basalt from the same source, with increasing amounts of the latter component with progression of eruption. This suggests that San Jorge-like magmas were the main feeder of the longer lived system building Villarrica. Abrupt major element variations up-sequence additionally show a rapid switch to more fractionated compositions, indicating that storage and evolution through crystallization may have taken place once the initially wet melts ‘dried out’.
ISSN:0010-7999
1432-0967
DOI:10.1007/s00410-019-1643-x