Fracturing and tectonic stress drive ultrarapid magma flow into dikes

Freysteinn Sigmundsson; Michelle Parks; Halldór Geirsson; Andrew Hooper; Vincent Drouin; Kristín S. Vogfjörd; Benedikt G. Ófeigsson; Sonja H.M. Greiner; Yilin Yang; Chiara Lanzi; Gregory P. De Pascale; Kristín Jónsdóttir; Sigrún Hreinsdóttir; Valentyn Tolpekin; Hildur María Friðriksdóttir; Páll Einarsson; Sara Barsotti

doi:10.1126/science.adn2838

Fracturing and tectonic stress drive ultrarapid magma flow into dikes

Freysteinn Sigmundsson
, Michelle Parks
, Halldór Geirsson
, Andrew Hooper
, Vincent Drouin
, Kristín S. Vogfjörd
, Benedikt G. Ófeigsson
, Sonja H.M. Greiner
, Yilin Yang
, Chiara Lanzi
, Gregory P. De Pascale
, Kristín Jónsdóttir
, Sigrún Hreinsdóttir
, Valentyn Tolpekin
, Hildur María Friðriksdóttir
, Páll Einarsson
, Sara Barsotti

Háskóli Íslands

Rannsóknarafurð: Framlag til fræðitímarits › Grein › ritrýni

Útdráttur

Many examples of exposed giant dike swarms can be found where lateral magma flow has exceeded hundreds of kilometers. We show that massive magma flow into dikes can be established with only modest overpressure in a magma body if a large enough pathway opens at its boundary and gradual buildup of high tensile stress has occurred along the dike pathway prior to the onset of diking. This explains rapid initial magma flow rates, modeled up to about 7400 cubic meters per second into a dike ~15-kilometers long, which propagated under the town of Grindavík, Southwest Iceland, in November 2023. Such high flow rates provide insight into the formation of major dikes and imply a serious hazard potential for high–flow rate intrusions that propagate to the surface and transition into eruptions.

Upprunalegt tungumál	Enska
Síður (frá-til)	1228-1235
Síðufjöldi	8
Fræðitímarit	Science
Bindi	383
Númer tölublaðs	6688
DOI	https://doi.org/10.1126/science.adn2838
Útgáfustaða	Útgefið - 15 mar. 2024

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10.1126/science.adn2838

Vitna í þetta

Sigmundsson, F., Parks, M., Geirsson, H., Hooper, A., Drouin, V., Vogfjörd, K. S., Ófeigsson, B. G., Greiner, S. H. M., Yang, Y., Lanzi, C., De Pascale, G. P., Jónsdóttir, K., Hreinsdóttir, S., Tolpekin, V., Friðriksdóttir, H. M., Einarsson, P., & Barsotti, S. (2024). Fracturing and tectonic stress drive ultrarapid magma flow into dikes. Science, 383(6688), 1228-1235. https://doi.org/10.1126/science.adn2838

@article{b5fa462156814a15a1ee4fa4c8a7cfbc,

title = "Fracturing and tectonic stress drive ultrarapid magma flow into dikes",

abstract = "Many examples of exposed giant dike swarms can be found where lateral magma flow has exceeded hundreds of kilometers. We show that massive magma flow into dikes can be established with only modest overpressure in a magma body if a large enough pathway opens at its boundary and gradual buildup of high tensile stress has occurred along the dike pathway prior to the onset of diking. This explains rapid initial magma flow rates, modeled up to about 7400 cubic meters per second into a dike \textasciitilde{}15-kilometers long, which propagated under the town of Grindav{\'i}k, Southwest Iceland, in November 2023. Such high flow rates provide insight into the formation of major dikes and imply a serious hazard potential for high–flow rate intrusions that propagate to the surface and transition into eruptions.",

author = "Freysteinn Sigmundsson and Michelle Parks and Halld{\'o}r Geirsson and Andrew Hooper and Vincent Drouin and Vogfj{\"o}rd, \{Krist{\'i}n S.\} and {\'O}feigsson, \{Benedikt G.\} and Greiner, \{Sonja H.M.\} and Yilin Yang and Chiara Lanzi and \{De Pascale\}, \{Gregory P.\} and Krist{\'i}n J{\'o}nsd{\'o}ttir and Sigr{\'u}n Hreinsd{\'o}ttir and Valentyn Tolpekin and Fri{\dh}riksd{\'o}ttir, \{Hildur Mar{\'i}a\} and P{\'a}ll Einarsson and Sara Barsotti",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 the authors, some rights reserved.",

year = "2024",

month = mar,

day = "15",

doi = "10.1126/science.adn2838",

language = "English",

volume = "383",

pages = "1228--1235",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

number = "6688",

}

Sigmundsson, F, Parks, M, Geirsson, H, Hooper, A, Drouin, V, Vogfjörd, KS, Ófeigsson, BG, Greiner, SHM, Yang, Y, Lanzi, C, De Pascale, GP, Jónsdóttir, K, Hreinsdóttir, S, Tolpekin, V, Friðriksdóttir, HM, Einarsson, P & Barsotti, S 2024, 'Fracturing and tectonic stress drive ultrarapid magma flow into dikes', Science, bind. 383, nr. 6688, bls. 1228-1235. https://doi.org/10.1126/science.adn2838

TY - JOUR

T1 - Fracturing and tectonic stress drive ultrarapid magma flow into dikes

AU - Sigmundsson, Freysteinn

AU - Parks, Michelle

AU - Geirsson, Halldór

AU - Hooper, Andrew

AU - Drouin, Vincent

AU - Vogfjörd, Kristín S.

AU - Ófeigsson, Benedikt G.

AU - Greiner, Sonja H.M.

AU - Yang, Yilin

AU - Lanzi, Chiara

AU - De Pascale, Gregory P.

AU - Jónsdóttir, Kristín

AU - Hreinsdóttir, Sigrún

AU - Tolpekin, Valentyn

AU - Friðriksdóttir, Hildur María

AU - Einarsson, Páll

AU - Barsotti, Sara

PY - 2024/3/15

Y1 - 2024/3/15

N2 - Many examples of exposed giant dike swarms can be found where lateral magma flow has exceeded hundreds of kilometers. We show that massive magma flow into dikes can be established with only modest overpressure in a magma body if a large enough pathway opens at its boundary and gradual buildup of high tensile stress has occurred along the dike pathway prior to the onset of diking. This explains rapid initial magma flow rates, modeled up to about 7400 cubic meters per second into a dike ~15-kilometers long, which propagated under the town of Grindavík, Southwest Iceland, in November 2023. Such high flow rates provide insight into the formation of major dikes and imply a serious hazard potential for high–flow rate intrusions that propagate to the surface and transition into eruptions.

AB - Many examples of exposed giant dike swarms can be found where lateral magma flow has exceeded hundreds of kilometers. We show that massive magma flow into dikes can be established with only modest overpressure in a magma body if a large enough pathway opens at its boundary and gradual buildup of high tensile stress has occurred along the dike pathway prior to the onset of diking. This explains rapid initial magma flow rates, modeled up to about 7400 cubic meters per second into a dike ~15-kilometers long, which propagated under the town of Grindavík, Southwest Iceland, in November 2023. Such high flow rates provide insight into the formation of major dikes and imply a serious hazard potential for high–flow rate intrusions that propagate to the surface and transition into eruptions.

UR - https://www.scopus.com/pages/publications/85187963360

U2 - 10.1126/science.adn2838

DO - 10.1126/science.adn2838

M3 - Article

C2 - 38330140

SN - 0036-8075

VL - 383

SP - 1228

EP - 1235

JO - Science

JF - Science

IS - 6688

ER -

Fracturing and tectonic stress drive ultrarapid magma flow into dikes

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