Please use this identifier to cite or link to this item: http://hdl.handle.net/10995/102858
Title: A Method for Magma Viscosity Assessment by Lava Dome Morphology
Authors: Starodubtseva, Y. V.
Starodubtsev, I. S.
Ismail-Zadeh, A. T.
Tsepelev, I. A.
Melnik, O. E.
Korotkii, A. I.
Issue Date: 2021
Publisher: Pleiades journals
Citation: A Method for Magma Viscosity Assessment by Lava Dome Morphology / Y. V. Starodubtseva, I. S. Starodubtsev, A. T. Ismail-Zadeh, et al. — DOI 10.1134/S0742046321030064 // Journal of Volcanology and Seismology. — 2021. — Vol. 15. — Iss. 3. — P. 159-168.
Abstract: Abstract: Lava domes form when a highly viscous magma erupts on the surface. Several types of lava dome morphology can be distinguished depending on the flow rate and the rheology of magma: obelisks, lava lobes, and endogenic structures. The viscosity of magma nonlinearly depends on the volume fraction of crystals and temperature. Here we present an approach to magma viscosity estimation based on a comparison of observed and simulated morphological forms of lava domes. We consider a two-dimensional axisymmetric model of magma extrusion on the surface and lava dome evolution, and assume that the lava viscosity depends only on the volume fraction of crystals. The crystallization is associated with a growth of the liquidus temperature due to the volatile loss from the magma, and it is determined by the characteristic time of crystal content growth (CCGT) and the discharge rate. Lava domes are modeled using a finite-volume method implemented in Ansys Fluent software for various CCGTs and volcanic vent sizes. For a selected eruption duration a set of morphological shapes of domes (shapes of the interface between lava dome and air) is obtained. Lava dome shapes modeled this way are compared with the observed shape of the lava dome (synthesized in the study by a random modification of one of the calculated shapes). To estimate magma viscosity, the deviation between the observed dome shape and the simulated dome shapes is assessed by three functionals: the symmetric difference, the peak signal-to-noise ratio, and the structural similarity index measure. These functionals are often used in the computer vision and in image processing. Although each functional allows to determine the best fit between the modeled and observed shapes of lava dome, the functional based on the structural similarity index measure performs it better. The viscosity of the observed dome can be then approximated by the viscosity of the modeled dome, which shape fits best the shape of the observed dome. This approach can be extended to three-dimensional case studies to restore the conditions of natural lava dome growth. © 2021, The Author(s).
Keywords: IMAGE PROCESSING
LAVA DOME
MORPHOLOGY
NUMERICAL ANALYSIS
VISCOSITY
ASSESSMENT METHOD
CRYSTAL
CRYSTALLIZATION
GEOMORPHOLOGY
IMAGE PROCESSING
LAVA DOME
MAGMA CHEMISTRY
NUMERICAL METHOD
TEMPERATURE
THREE-DIMENSIONAL MODELING
VISCOSITY
URI: http://hdl.handle.net/10995/102858
Access: info:eu-repo/semantics/openAccess
SCOPUS ID: 85107440217
PURE ID: 22107516
f2eb7ef6-56c0-4766-9240-e805272b5189
ISSN: 7420463
DOI: 10.1134/S0742046321030064
metadata.dc.description.sponsorship: We are grateful to two anonymous reviewers for their constructive comments. Numerical experiments were carried out on the Uran computing cluster (Institute of Mathematics and Mechanics, Ural Branch of the Russian Academy of Sciences, Yekaterinburg). The work was supported by the Russian Science Foundation (project no. 19-17-00027).
RSCF project card: 19-17-00027
Appears in Collections:Научные публикации, проиндексированные в SCOPUS и WoS CC

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