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Focused magmatism beneath Uturuncu volcano, Bolivia : Insights from seismic tomography and deformation modeling. / Kukarina, Ekaterina; West, Michael; Keyson, Laura Hutchinson et al.

In: Geosphere, Vol. 13, No. 6, 01.11.2017, p. 1855-1866.

Research output: Contribution to journalArticlepeer-review

Harvard

Kukarina, E, West, M, Keyson, LH, Koulakov, I, Tsibizov, L & Smirnov, S 2017, 'Focused magmatism beneath Uturuncu volcano, Bolivia: Insights from seismic tomography and deformation modeling', Geosphere, vol. 13, no. 6, pp. 1855-1866. https://doi.org/10.1130/GES01403.1

APA

Kukarina, E., West, M., Keyson, L. H., Koulakov, I., Tsibizov, L., & Smirnov, S. (2017). Focused magmatism beneath Uturuncu volcano, Bolivia: Insights from seismic tomography and deformation modeling. Geosphere, 13(6), 1855-1866. https://doi.org/10.1130/GES01403.1

Vancouver

Kukarina E, West M, Keyson LH, Koulakov I, Tsibizov L, Smirnov S. Focused magmatism beneath Uturuncu volcano, Bolivia: Insights from seismic tomography and deformation modeling. Geosphere. 2017 Nov 1;13(6):1855-1866. doi: 10.1130/GES01403.1

Author

Kukarina, Ekaterina ; West, Michael ; Keyson, Laura Hutchinson et al. / Focused magmatism beneath Uturuncu volcano, Bolivia : Insights from seismic tomography and deformation modeling. In: Geosphere. 2017 ; Vol. 13, No. 6. pp. 1855-1866.

BibTeX

@article{2ea3348051234f4183a8ddfc80617777,
title = "Focused magmatism beneath Uturuncu volcano, Bolivia: Insights from seismic tomography and deformation modeling",
abstract = "We have carried out a tomographic inversion for seismic velocity in the vicinity of Uturuncu volcano (Bolivia) based on a 33-station temporary seismic network deployment. We combine travel times from earthquakes in the shallow crust with those from earthquakes on the subducting Nazca plate to broadly constrain velocities throughout the crust using the LOTOS tomography algorithm. The reliability and resolution of the tomography is verified using a series of tests on real and synthetic data. The resulting three-dimensional distributions of Vp, Vs, and Vp/Vs reveal a large tooth-shaped anomaly rooted in the deep crust and stopping abruptly 6 km below the surface. This feature exhibits very high values of Vp/Vs (up to 2.0) extending to ~80 km depth. To explain the relationship of this anomaly with the surface uplift observed in interferometric synthetic aperture radar (InSAR) data, we propose two scenarios. In the first, the feature is a pathway for liquid volatiles that convert to gas, due to decompression, at ~6 km depth, causing a volume increase. This expansion drives seismicity in the overlying crust. In the second model, this anomaly is a buoyant pulse of magma within the batholith, ascending due to gravitational instability. We propose a simplified numerical simulation to demonstrate how this second model generally supports many of the observations. We conclude that both of these scenarios might be valid and complement each other for the Uturuncu case. Based on joint analysis of the tomography results and available geochemical and petrological information, we have constructed a model of the Uturuncu magma system that illustrates the main stages of phase transitions and melting.",
keywords = "REDOUBT VOLCANO, UPPER-MANTLE, TEMPERATURE, INVERSION, VELOCITY, ERUPTION, BODY, ALGORITHM, PRESSURE, CHAMBERS",
author = "Ekaterina Kukarina and Michael West and Keyson, {Laura Hutchinson} and Ivan Koulakov and Leonid Tsibizov and Sergey Smirnov",
year = "2017",
month = nov,
day = "1",
doi = "10.1130/GES01403.1",
language = "English",
volume = "13",
pages = "1855--1866",
journal = "Geosphere",
issn = "1553-040X",
publisher = "Geological Society of America",
number = "6",

}

RIS

TY - JOUR

T1 - Focused magmatism beneath Uturuncu volcano, Bolivia

T2 - Insights from seismic tomography and deformation modeling

AU - Kukarina, Ekaterina

AU - West, Michael

AU - Keyson, Laura Hutchinson

AU - Koulakov, Ivan

AU - Tsibizov, Leonid

AU - Smirnov, Sergey

PY - 2017/11/1

Y1 - 2017/11/1

N2 - We have carried out a tomographic inversion for seismic velocity in the vicinity of Uturuncu volcano (Bolivia) based on a 33-station temporary seismic network deployment. We combine travel times from earthquakes in the shallow crust with those from earthquakes on the subducting Nazca plate to broadly constrain velocities throughout the crust using the LOTOS tomography algorithm. The reliability and resolution of the tomography is verified using a series of tests on real and synthetic data. The resulting three-dimensional distributions of Vp, Vs, and Vp/Vs reveal a large tooth-shaped anomaly rooted in the deep crust and stopping abruptly 6 km below the surface. This feature exhibits very high values of Vp/Vs (up to 2.0) extending to ~80 km depth. To explain the relationship of this anomaly with the surface uplift observed in interferometric synthetic aperture radar (InSAR) data, we propose two scenarios. In the first, the feature is a pathway for liquid volatiles that convert to gas, due to decompression, at ~6 km depth, causing a volume increase. This expansion drives seismicity in the overlying crust. In the second model, this anomaly is a buoyant pulse of magma within the batholith, ascending due to gravitational instability. We propose a simplified numerical simulation to demonstrate how this second model generally supports many of the observations. We conclude that both of these scenarios might be valid and complement each other for the Uturuncu case. Based on joint analysis of the tomography results and available geochemical and petrological information, we have constructed a model of the Uturuncu magma system that illustrates the main stages of phase transitions and melting.

AB - We have carried out a tomographic inversion for seismic velocity in the vicinity of Uturuncu volcano (Bolivia) based on a 33-station temporary seismic network deployment. We combine travel times from earthquakes in the shallow crust with those from earthquakes on the subducting Nazca plate to broadly constrain velocities throughout the crust using the LOTOS tomography algorithm. The reliability and resolution of the tomography is verified using a series of tests on real and synthetic data. The resulting three-dimensional distributions of Vp, Vs, and Vp/Vs reveal a large tooth-shaped anomaly rooted in the deep crust and stopping abruptly 6 km below the surface. This feature exhibits very high values of Vp/Vs (up to 2.0) extending to ~80 km depth. To explain the relationship of this anomaly with the surface uplift observed in interferometric synthetic aperture radar (InSAR) data, we propose two scenarios. In the first, the feature is a pathway for liquid volatiles that convert to gas, due to decompression, at ~6 km depth, causing a volume increase. This expansion drives seismicity in the overlying crust. In the second model, this anomaly is a buoyant pulse of magma within the batholith, ascending due to gravitational instability. We propose a simplified numerical simulation to demonstrate how this second model generally supports many of the observations. We conclude that both of these scenarios might be valid and complement each other for the Uturuncu case. Based on joint analysis of the tomography results and available geochemical and petrological information, we have constructed a model of the Uturuncu magma system that illustrates the main stages of phase transitions and melting.

KW - REDOUBT VOLCANO

KW - UPPER-MANTLE

KW - TEMPERATURE

KW - INVERSION

KW - VELOCITY

KW - ERUPTION

KW - BODY

KW - ALGORITHM

KW - PRESSURE

KW - CHAMBERS

UR - http://www.scopus.com/inward/record.url?scp=85035750299&partnerID=8YFLogxK

U2 - 10.1130/GES01403.1

DO - 10.1130/GES01403.1

M3 - Article

AN - SCOPUS:85035750299

VL - 13

SP - 1855

EP - 1866

JO - Geosphere

JF - Geosphere

SN - 1553-040X

IS - 6

ER -

ID: 9672256