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Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature

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Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature. / Smith, Rosanna; Sammonds, Peter; Tuffen, Hugh et al.
In: Earth and Planetary Science Letters, Vol. 307, No. 1-2, 01.07.2011, p. 191-200.

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Harvard

Smith, R, Sammonds, P, Tuffen, H & Meredith, P 2011, 'Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature', Earth and Planetary Science Letters, vol. 307, no. 1-2, pp. 191-200. https://doi.org/10.1016/j.epsl.2011.04.044

APA

Smith, R., Sammonds, P., Tuffen, H., & Meredith, P. (2011). Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature. Earth and Planetary Science Letters, 307(1-2), 191-200. https://doi.org/10.1016/j.epsl.2011.04.044

Vancouver

Smith R, Sammonds P, Tuffen H, Meredith P. Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature. Earth and Planetary Science Letters. 2011 Jul 1;307(1-2):191-200. doi: 10.1016/j.epsl.2011.04.044

Author

Smith, Rosanna ; Sammonds, Peter ; Tuffen, Hugh et al. / Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature. In: Earth and Planetary Science Letters. 2011 ; Vol. 307, No. 1-2. pp. 191-200.

Bibtex

@article{1c6abb7593f6471295f298826b6e0f8e,
title = "Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature",
abstract = "The 2004–2008 eruption of Mount St. Helens, Washington, USA, formed a typical example of a Pelean spiny lava dome, with solid spines of crystalline silicic lava extruded along shear zones bounded by fault gouge (Cashman et al., 2008; Iverson et al., 2006). Creation of and movement along shear zones in this erupting lava, recorded as shallow micro-earthquakes, were thus key controls on eruption style and rate, in addition to dome stability. As eruption style and lava dome stability often change within individual eruptions, it is important to identify how the strength of dome rocks changes with temperature, time, texture and extrusion rate. However, critical values of the shear strength of dome lava at eruptive temperatures have never been measured. We have found in controlled laboratory experiments simulating eruption conditions that dome lava strength increased during the course of the 2004–2008 eruption of Mount St. Helens, as the textures became more crystalline and less porous. Increasing lava strength during the eruption would lead to deformation becoming increasingly localised to shear zones, explaining why the extrusion style and centre were so consistent. Acoustic emissions and microstructure analysis indicate that fracturing was more localised at higher temperatures, resulting in higher strengths at eruptive temperature compared to ambient temperatures for later erupted samples. The strength of these later erupted samples at eruptive temperatures increased markedly with strain rate. This would damp any increases in effusion rate that may result from changes in magma pressure, explaining the steady effusion rate at Mount St. Helens from 2004 to 2008.",
keywords = "volcanology, Mount St. Helens , lava dome , rock physics , acoustic emission , volcano seismology",
author = "Rosanna Smith and Peter Sammonds and Hugh Tuffen and Philip Meredith",
year = "2011",
month = jul,
day = "1",
doi = "10.1016/j.epsl.2011.04.044",
language = "English",
volume = "307",
pages = "191--200",
journal = "Earth and Planetary Science Letters",
issn = "0012-821X",
publisher = "Elsevier Science B.V.",
number = "1-2",

}

RIS

TY - JOUR

T1 - Evolution of the mechanics of the 2004–2008 Mt. St. Helens lava dome with time and temperature

AU - Smith, Rosanna

AU - Sammonds, Peter

AU - Tuffen, Hugh

AU - Meredith, Philip

PY - 2011/7/1

Y1 - 2011/7/1

N2 - The 2004–2008 eruption of Mount St. Helens, Washington, USA, formed a typical example of a Pelean spiny lava dome, with solid spines of crystalline silicic lava extruded along shear zones bounded by fault gouge (Cashman et al., 2008; Iverson et al., 2006). Creation of and movement along shear zones in this erupting lava, recorded as shallow micro-earthquakes, were thus key controls on eruption style and rate, in addition to dome stability. As eruption style and lava dome stability often change within individual eruptions, it is important to identify how the strength of dome rocks changes with temperature, time, texture and extrusion rate. However, critical values of the shear strength of dome lava at eruptive temperatures have never been measured. We have found in controlled laboratory experiments simulating eruption conditions that dome lava strength increased during the course of the 2004–2008 eruption of Mount St. Helens, as the textures became more crystalline and less porous. Increasing lava strength during the eruption would lead to deformation becoming increasingly localised to shear zones, explaining why the extrusion style and centre were so consistent. Acoustic emissions and microstructure analysis indicate that fracturing was more localised at higher temperatures, resulting in higher strengths at eruptive temperature compared to ambient temperatures for later erupted samples. The strength of these later erupted samples at eruptive temperatures increased markedly with strain rate. This would damp any increases in effusion rate that may result from changes in magma pressure, explaining the steady effusion rate at Mount St. Helens from 2004 to 2008.

AB - The 2004–2008 eruption of Mount St. Helens, Washington, USA, formed a typical example of a Pelean spiny lava dome, with solid spines of crystalline silicic lava extruded along shear zones bounded by fault gouge (Cashman et al., 2008; Iverson et al., 2006). Creation of and movement along shear zones in this erupting lava, recorded as shallow micro-earthquakes, were thus key controls on eruption style and rate, in addition to dome stability. As eruption style and lava dome stability often change within individual eruptions, it is important to identify how the strength of dome rocks changes with temperature, time, texture and extrusion rate. However, critical values of the shear strength of dome lava at eruptive temperatures have never been measured. We have found in controlled laboratory experiments simulating eruption conditions that dome lava strength increased during the course of the 2004–2008 eruption of Mount St. Helens, as the textures became more crystalline and less porous. Increasing lava strength during the eruption would lead to deformation becoming increasingly localised to shear zones, explaining why the extrusion style and centre were so consistent. Acoustic emissions and microstructure analysis indicate that fracturing was more localised at higher temperatures, resulting in higher strengths at eruptive temperature compared to ambient temperatures for later erupted samples. The strength of these later erupted samples at eruptive temperatures increased markedly with strain rate. This would damp any increases in effusion rate that may result from changes in magma pressure, explaining the steady effusion rate at Mount St. Helens from 2004 to 2008.

KW - volcanology

KW - Mount St. Helens

KW - lava dome

KW - rock physics

KW - acoustic emission

KW - volcano seismology

U2 - 10.1016/j.epsl.2011.04.044

DO - 10.1016/j.epsl.2011.04.044

M3 - Journal article

VL - 307

SP - 191

EP - 200

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

SN - 0012-821X

IS - 1-2

ER -