Triggering of a volcanic dome collapse by rainwater infiltration

Peter D Hicks; Adrian J Matthews; Mark J Cooker

doi:10.1029/2009JB006831

Triggering of a volcanic dome collapse by rainwater infiltration

Peter D Hicks, Adrian J Matthews, Mark J Cooker

Engineering

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

The thermodynamic processes in a one-dimensional model of a porous lava dome are considered in the presence of a rising magmatic gas flux through the void spaces and rainfall interacting with the dome surface. The steady state surface temperature of the dome depends on both magmatic gas mass flux and rainfall rate. A critical rainfall rate is determined, that cools the dome surface to 100°C. Rainfall rates above this critical value allow liquid infiltration into the void spaces of the dome, thus restricting the escape of magmatic gas. A model which restricts the gas flow through the surface predicts internal gas pressures much higher than the overburden pressure in the top few meters, approximately one hour after the onset of rainfall. For a marginally stable dome, this could cause small Vulcanian explosions, which (depending on their location) could trigger a dome collapse, on a timescale consistent with observations.

Original language	English
Article number	B09212
Number of pages	8
Journal	Journal of Geophysical Research: Solid Earth
Volume	115
Issue number	B9
DOIs	https://doi.org/10.1029/2009JB006831
Publication status	Published - Sept 2010

Keywords

lava dome collapse
volcano-rainwater interactions
Soufriere Hills Volcano
Montserrat

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10.1029/2009JB006831

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abstract = "The thermodynamic processes in a one-dimensional model of a porous lava dome are considered in the presence of a rising magmatic gas flux through the void spaces and rainfall interacting with the dome surface. The steady state surface temperature of the dome depends on both magmatic gas mass flux and rainfall rate. A critical rainfall rate is determined, that cools the dome surface to 100°C. Rainfall rates above this critical value allow liquid infiltration into the void spaces of the dome, thus restricting the escape of magmatic gas. A model which restricts the gas flow through the surface predicts internal gas pressures much higher than the overburden pressure in the top few meters, approximately one hour after the onset of rainfall. For a marginally stable dome, this could cause small Vulcanian explosions, which (depending on their location) could trigger a dome collapse, on a timescale consistent with observations.",

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T1 - Triggering of a volcanic dome collapse by rainwater infiltration

AU - Hicks, Peter D

AU - Matthews, Adrian J

AU - Cooker, Mark J

PY - 2010/9

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N2 - The thermodynamic processes in a one-dimensional model of a porous lava dome are considered in the presence of a rising magmatic gas flux through the void spaces and rainfall interacting with the dome surface. The steady state surface temperature of the dome depends on both magmatic gas mass flux and rainfall rate. A critical rainfall rate is determined, that cools the dome surface to 100°C. Rainfall rates above this critical value allow liquid infiltration into the void spaces of the dome, thus restricting the escape of magmatic gas. A model which restricts the gas flow through the surface predicts internal gas pressures much higher than the overburden pressure in the top few meters, approximately one hour after the onset of rainfall. For a marginally stable dome, this could cause small Vulcanian explosions, which (depending on their location) could trigger a dome collapse, on a timescale consistent with observations.

AB - The thermodynamic processes in a one-dimensional model of a porous lava dome are considered in the presence of a rising magmatic gas flux through the void spaces and rainfall interacting with the dome surface. The steady state surface temperature of the dome depends on both magmatic gas mass flux and rainfall rate. A critical rainfall rate is determined, that cools the dome surface to 100°C. Rainfall rates above this critical value allow liquid infiltration into the void spaces of the dome, thus restricting the escape of magmatic gas. A model which restricts the gas flow through the surface predicts internal gas pressures much higher than the overburden pressure in the top few meters, approximately one hour after the onset of rainfall. For a marginally stable dome, this could cause small Vulcanian explosions, which (depending on their location) could trigger a dome collapse, on a timescale consistent with observations.

KW - lava dome collapse

KW - volcano-rainwater interactions

KW - Soufriere Hills Volcano

KW - Montserrat

U2 - 10.1029/2009JB006831

DO - 10.1029/2009JB006831

M3 - Article

SN - 2169-9313

VL - 115

JO - Journal of Geophysical Research: Solid Earth

JF - Journal of Geophysical Research: Solid Earth

IS - B9

M1 - B09212

ER -

Triggering of a volcanic dome collapse by rainwater infiltration

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Keywords

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