Extreme seismic anisotropy indicates shallow accumulation of magmatic sills beneath Yellowstone caldera

Understanding the distribution and mobility of crystal mushes within modern magmatic systems is crucial to volcanic hazard assessments as distinct pockets of mobile magma may become interconnected and lead to melt accumulation on shorter time scales than magma that is broadly distributed in a homoge...

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Bibliographic Details
Published in:Earth and planetary science letters 2023-08, Vol.616, p.118244, Article 118244
Main Authors: Wu, Sin-Mei, Huang, Hsin-Hua, Lin, Fan-Chi, Farrell, Jamie, Schmandt, Brandon
Format: Article
Language:English
Subjects:
ambient noise tomography
large-N array
magmatic sills
radial anisotropy
Yellowstone
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Summary:Understanding the distribution and mobility of crystal mushes within modern magmatic systems is crucial to volcanic hazard assessments as distinct pockets of mobile magma may become interconnected and lead to melt accumulation on shorter time scales than magma that is broadly distributed in a homogeneous mush. Here, we reveal that Yellowstone's upper-crustal magma reservoir in the top 20 km is heterogeneous in both melt concentration and texture. We exploit ambient noise in an unprecedented dense temporary seismic network to jointly constrain vertically- and horizontally-polarized shear wave speeds to create enhanced 3D isotropic and anisotropic shear velocity models. Our models show an exceptionally low-velocity (>20% reduction) layer 4–7 km beneath the surface, situated near the top of the reservoir previously-imaged by earthquake P-wave tomography. The presence of strong radial anisotropy (20%) within this layer indicates the uppermost portion of the modern Yellowstone reservoir is organized as a sill complex, with up to 28% of melt fraction in horizontally-elongated volumes at depths where rhyolite was commonly stored before past eruptions. The findings demonstrate that high-resolution anisotropic imaging through a dense seismic network can constrain both magma distribution and reservoir texture, which are important to understand the evolution and hazard assessment of volcanic systems like Yellowstone. •Dense nodal array depicts detailed images of Yellowstone's crustal magmatic system.•Melt is found accumulated shallow at 4–7 km depth, near the top of magma reservoir.•Significant anisotropy implies a sill complex with up to 28% of melt.
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2023.118244