Timescales and thermal evolution of large silicic magma reservoirs during an ignimbrite flare-up: perspectives from zircon

Timescales and thermal evolution of large silicic magma reservoirs during an ignimbrite flare-up: perspectives from zircon

Four voluminous ignimbrites (150–500 km 3 ) erupted in rapid succession at 27 Ma in the central San Juan caldera cluster, Colorado. To reconstruct the timescales and thermal evolution of these magma reservoirs, we used zircon ID-TIMS U–Pb geochronology, zircon LA-ICP-MS geochemistry, thermal modelin...

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Bibliographic Details
Published in:Contributions to mineralogy and petrology Vol. 176; no. 12
Main Authors: Curry, Adam, Gaynor, Sean P., Davies, J. H. F. L., Ovtcharova, Maria, Simpson, Guy, Caricchi, Luca
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-12-2021
Springer
Springer Nature B.V
Subjects:
Accretion
Age
Analysis
Calderas
Crystallization
Deposition
Dispersion
Earth and Environmental Science
Earth Sciences
Evolution
Geochemistry
Geochronology
Geochronometry
Geology
Isotopes
Lava
Magma
Magma chambers
Magmatism
Mineral Resources
Mineralogy
Modelling
Original Paper
Petrology
Reservoirs
Snakes
Spectra
Subduction
Thermal analysis
Thermal evolution
Zircon
Ignimbrite
Southern Rocky Mountain volcanic field
Magma
Zircon geochronology
U–Pb
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Summary:Four voluminous ignimbrites (150–500 km 3 ) erupted in rapid succession at 27 Ma in the central San Juan caldera cluster, Colorado. To reconstruct the timescales and thermal evolution of these magma reservoirs, we used zircon ID-TIMS U–Pb geochronology, zircon LA-ICP-MS geochemistry, thermal modeling, and zircon age and crystallization modeling. Zircon geochronology reveals dispersed zircon age spectra in all ignimbrites, with decreasing age dispersion through time that we term a ‘chimney sweeping’ event. Zircon whole-grain age modeling suggests that 2σ zircon age spans represent approximately one-quarter of total zircon crystallization timescales due to the averaging effect of whole-grain, individual zircon ages, resulting in zircon crystallization timescales of 0.8–2.7 m.y. Thermal and zircon crystallization modeling combined with Ti-in-zircon temperatures indicates that magma reservoirs were built over millions of years at relatively low magmatic vertical accretion rates (VARs) of 2–5 × 10 –3  m y −1 (2–5 × 10 –6 km 3 y −1  km −2 ), and we suggest that such low VARs were characteristic of the assembly of the greater San Juan magmatic body. Though we cannot unequivocally discern between dispersed zircon age spectra caused by inheritance (xenocrystic or antecrystic) versus prolonged crystallization from the same magma reservoir (autocrystic), our findings suggest that long-term magma input at relatively low VARs produced thermally mature upper crustal magma reservoirs resulting in protracted zircon crystallization timescales. Compiling all U–Pb ID-TIMS zircon ages of large ignimbrites, we interpret the longer timescales of subduction-related ignimbrites as a result of longer term, lower flux magmatism, and the shorter timescales of Snake River Plain ignimbrites as a result of shorter term, higher flux magmatism.
ISSN:0010-7999
1432-0967
DOI:10.1007/s00410-021-01862-w