Ground deformation associated with the precursory unrest and early phases of the January 2006 eruption of Augustine Volcano, Alaska

Cervelli, P. F.; Fournier, T.; Freymueller, J. T.; Power, John A.

doi:10.1029/2006gl027219

Cited by 64 publications

(79 citation statements)

References 14 publications

(13 reference statements)

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“…An exception to this general behavior was a deformation episode that started immediately before and lasted through the initial phases of the 2006 eruption [36]. While this deformation was significant, it occurred at a time not covered by our SAR data and had almost entirely ceased at the time of our first SAR acquisition after the 2006 eruption.…”

Section: Geophysical Considerations and Model Assumptionsmentioning

confidence: 81%

“…Each of these eruptions were similar in nature and composition, beginning with an initial explosive phase (VEI~3), followed by a period of decreasing intensity, and finally, an effusive, dome building phase [34][35][36]. Although Augustine has had four eruptions in the past 50 years, this paper examines the two most recent eruptions in 1986 and 2006.…”

Section: Augustine Volcanomentioning

confidence: 99%

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Pyroclastic Flow Deposits and InSAR: Analysis of Long-Term Subsidence at Augustine Volcano, Alaska

et al. 2016

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Deformation of pyroclastic flow deposits begins almost immediately after emplacement, and continues thereafter for months or years. This study analyzes the extent, volume, thickness, and variability in pyroclastic flow deposits (PFDs) on Augustine Volcano from measuring their deformation rates with interferometric synthetic aperture radar (InSAR). To conduct this analysis, we obtained 48 SAR images of Augustine Volcano acquired between 1992 and 2010, spanning its most recent eruption in 2006. The data were processed using d-InSAR time-series analysis to measure the thickness of the Augustine PFDs, as well as their surface deformation behavior. Because much of the 2006 PFDs overlie those from the previous eruption in 1986, geophysical models were derived to decompose deformation contributions from the 1986 deposits underlying the measured 2006 deposits. To accomplish this, we introduce an inversion approach to estimate geophysical parameters for both 1986 and 2006 PFDs. Our analyses estimate the expanded volume of pyroclastic flow material deposited during the 2006 eruption to be 3.3 × 10 7 m 3 ± 0.11 × 10 7 m 3 , and that PFDs in the northeastern part of Augustine Island reached a maximum thickness of~31 m with a mean of~5 m. Similarly, we estimate the expanded volume of PFDs from the 1986 eruption at 4.6 × 10 7 m 3 ± 0.62 × 10 7 m 3 , with a maximum thickness of~31 m, and a mean of~7 m.

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Section: Geophysical Considerations and Model Assumptionsmentioning

confidence: 81%

Section: Augustine Volcanomentioning

confidence: 99%

Pyroclastic Flow Deposits and InSAR: Analysis of Long-Term Subsidence at Augustine Volcano, Alaska

et al. 2016

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“…From late April through October 2005, the seismicity rate gradually increased, from 16 relocated earthquakes in April to 99 in October, and the rate continued to increase until a ∼14 h long seismic swarm on 11 January, ending at the onset of explosive activity [ Power and Lalla , 2010], when 672 earthquakes were located by AVO. GPS data indicate a period of inflation beginning in roughly July 2005 [ Cervelli et al , 2006; Mattia et al , 2008; Cervelli et al , 2010]. Previous work has noted increased clustering in this time period and grouped some of the pre‐eruptive seismicity into a number of earthquake families based on waveform similarity [ DeShon et al , 2010].…”

Section: Resultsmentioning

confidence: 99%

“…It is a dacitic stratovolcano that erupted most recently in 2006, following previous major eruptions in 1986, 1976, 1963–1964, 1935, and 1885. The January 2006 eruption was preceded by increased seismicity beginning in late April 2005 and surface deformation indicating inflation beginning in November 2005 [ Cervelli et al , 2006]. In early to mid‐December 2005, activity escalated with a series of phreatic explosions.…”

Section: Introductionmentioning

confidence: 99%

The Augustine magmatic system as revealed by seismic tomography and relocated earthquake hypocenters from 1994 through 2009

Syracuse¹,

Thurber²,

Power³

2011

J. Geophys. Res.

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[1] We incorporate 14 years of earthquake data from the Alaska Volcano Observatory with data from a 1975 controlled-source seismic experiment to obtain the three-dimensional P and S wave velocity structure and the first high-precision earthquake locations at Augustine Volcano to be calculated in a fully three-dimensional velocity model. Velocity tomography shows two main features beneath Augustine: a narrow, high-velocity column beneath the summit, extending from ∼2 km depth to the surface, and elevated velocities on the south flank. Our relocation results allow a thorough analysis of the spatio-temoral patterns of seismicity and the relationship to the magmatic and eruptive activity. Background seismicity is centered beneath the summit at an average depth of 0.6 km above sea level. In the weeks leading to the January 2006 eruption of Augustine, seismicity focused on a NW-SE line along the trend of an inflating dike. A series of drumbeat earthquakes occurred in the early weeks of the eruption, indicating further magma transport through the same dike system. During the six months following the onset of the eruption, the otherwise quiescent region 1 to 5 km below sea level centered beneath the summit became seismically active with two groups of earthquakes, differentiated by frequency content. The deep longer-period earthquakes occurred during the eruption and are interpreted as resulting from the movement of magma toward the summit, and the post-eruptive shorter-period earthquakes may be due to the relaxation of an emptied magma tube. The seismicity subsequently returned to its normal background rates and patterns.Citation: Syracuse, E. M., C. H. Thurber, and J. A. Power (2011), The Augustine magmatic system as revealed by seismic tomography and relocated earthquake

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“…Geodetic data suggest that magma began to ascend from sea level as many as 50 days prior to the eruption of juvenile material, likely coincident with the onset of phreatic explosions. Modeling suggests that this intru sion may have progressively slowed as it ascended the final kilometer to the surface [Cervelli et al, 2006]. Continued analysis of this eruption should enable a better defini tion of the physical processes responsible for the accumulation, ascent, and eruption of high-silica andesites and dacites during the explosive as well as effusive periods.…”

Section: Analysis and Hazardsmentioning

confidence: 99%

The reawakening of Alaska's Augustine volcano

et al. 2006

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Augustine volcano, in south central Alaska, ended a 20‐year period of repose on 11 January 2006 with 13 explosive eruptions in 20 days. Explosive activity shifted to a quieter effusion of lava in early February, forming a new summit lava dome and two short, blocky lava flows by late March (Figure 1). The eruption was heralded by eight months of increasing seismicity, deformation, gas emission, and small phreatic eruptions, the latter consisting of explosions of steam and debris caused by heating and expansion of groundwater due to an underlying heat source.

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Ground deformation associated with the precursory unrest and early phases of the January 2006 eruption of Augustine Volcano, Alaska

Cited by 64 publications

References 14 publications

Pyroclastic Flow Deposits and InSAR: Analysis of Long-Term Subsidence at Augustine Volcano, Alaska

Pyroclastic Flow Deposits and InSAR: Analysis of Long-Term Subsidence at Augustine Volcano, Alaska

The Augustine magmatic system as revealed by seismic tomography and relocated earthquake hypocenters from 1994 through 2009

The reawakening of Alaska's Augustine volcano

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