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Journal Article

Young cumulate complex beneath Veniaminof caldera, Aleutian arc, dated by zircon in erupted plutonic blocks Available to Purchase

Charles R. Bacon, Thomas W. Sisson, Frank K. Mazdab
Journal: Geology
Published: 01 June 2007
Geology (2007) 35 (6): 491–494.
DOI: https://doi.org/10.1130/G23446A.1
...Charles R. Bacon; Thomas W. Sisson; Frank K. Mazdab Abstract Mount Veniaminof volcano, Alaska Peninsula, provides an opportunity to relate Quaternary volcanic rocks to a coeval intrusive complex. Veniaminof erupted tholeiitic basalt through dacite in the past ∼260 k.y. Gabbro, diorite...
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Journal Article

Intermediate-Term Declines in Seismicity at Mt. Wrangell and Mt. Veniaminof Volcanoes, Alaska, following the 3 November 2002 M w 7.9 Denali Fault Earthquake Available to Purchase

John J. Sánchez, Stephen R. McNutt
Published: 01 December 2004
Bulletin of the Seismological Society of America (2004) 94 (6B): S370–S383.
DOI: https://doi.org/10.1785/0120040602
... to the epicenter (247 km), had a background rate of 16 events/day. For the following 30 days, however, its seismicity rate dropped by 50%. Mt. Veniaminof (1400 km from the epicenter) had a rate of 8 seismic events/day, but suffered a drop in seismicity by 80% after the maishock; this may have lasted for 15 days...
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View PDF for article title, Intermediate-Term Declines in Seismicity at Mt. Wrangell and Mt. <span class="search-highlight">Veniaminof</span> Volcanoes, Alaska, following the 3 November 2002 M w 7.9 Denali Fault Earthquake
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Amplitudes and arrival times of an NVT event recorded on the Veniaminof (VN) and Peulik (PL) seismic networks. Panel (a) shows the maximum amplitude of the two largest pulses within the tremor event. The Veniaminof stations record larger amplitudes than the Peulik stations. Panel (b)  shows arrival times. The NVT signal arrives at the Veniaminof stations approximately one minute before arriving at the Peulik stations. The center of the two volcano networks are approximately 250 km apart. The color version of this figure is available only in the electronic edition.

Amplitudes and arrival times of an NVT event recorded on the Veniaminof (VN... Available to Purchase

Published: 01 December 2011
Figure 3. Amplitudes and arrival times of an NVT event recorded on the Veniaminof (VN) and Peulik (PL) seismic networks. Panel (a) shows the maximum amplitude of the two largest pulses within the tremor event. The Veniaminof stations record larger amplitudes than the Peulik stations. Panel (b
Image
Mt. Veniaminof data and map. (a) Multitaper spectrogram and (b) filtered waveforms for the three stations that detected the ground‐coupled airwaves. (c) The topographic map of Veniaminof with the station‐pair double difference (SPDD) locations (orange dots). The active vent is denoted by a red triangle and the seismic stations as white squares.

Mt. Veniaminof data and map. (a) Multitaper spectrogram and (b) filtered wa... Available to Purchase

Published: 05 April 2016
Figure 5. Mt. Veniaminof data and map. (a) Multitaper spectrogram and (b) filtered waveforms for the three stations that detected the ground‐coupled airwaves. (c) The topographic map of Veniaminof with the station‐pair double difference ( SPDD ) locations (orange dots). The active vent is denoted
Image
Figure 1. Shaded relief map of Mount Veniaminof volcano and vicinity with sample locations (last three digits of sample numbers). Upper left corner is Bering Sea coast, lower right is Pacific Ocean. Note NW-trending array of satellitic cones fed by lateral dikes from Veniaminof. Caldera diameter is ∼8 km; width of map is ∼50 km.

Figure 1. Shaded relief map of Mount Veniaminof volcano and vicinity with s... Available to Purchase

Published: 01 June 2007
Figure 1. Shaded relief map of Mount Veniaminof volcano and vicinity with sample locations (last three digits of sample numbers). Upper left corner is Bering Sea coast, lower right is Pacific Ocean. Note NW-trending array of satellitic cones fed by lateral dikes from Veniaminof. Caldera diameter
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Figure 3. Representative variation diagrams for samples from Veniaminof. A: MgO vs. SiO2. B: TiO2 vs. SiO2. X-ray fluorescence analyses (recalculated to total 100 wt% volatile free, all Fe as FeO) for Alaska Volcano Observatory by GeoAnalytical Laboratory, Washington State University.

Figure 3. Representative variation diagrams for samples from Veniaminof. A:... Available to Purchase

Published: 01 June 2007
Figure 3. Representative variation diagrams for samples from Veniaminof. A: MgO vs. SiO 2 . B: TiO 2 vs. SiO 2 . X-ray fluorescence analyses (recalculated to total 100 wt% volatile free, all Fe as FeO) for Alaska Volcano Observatory by GeoAnalytical Laboratory, Washington State University.
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Figure 4. Activity ratio diagrams for zircon from Veniaminof plutonic blocks analyzed by SHRIMP RG. Heavy solid lines are isochrons and model ages calculated with Isoplot (Ludwig, 2003); straight dashed lines in B–F are isochrons from other samples; Th/U weight ratio scale at top of each diagram. Ellipses represent ±1σ uncertainties on individual analyses; uncertainties on calculated ages are 95% confidence level. A, B: Miarolitic granodiorite 03TSV148. C: Miarolitic granodiorite 02TSV060. D: Diorite 01CBV047. E: Porphyritic gabbro 03TSV150. F: Coarse gabbroic cumulate 04CBV334. MSWD—mean square of weighted deviates.

Figure 4. Activity ratio diagrams for zircon from Veniaminof plutonic block... Available to Purchase

Published: 01 June 2007
Figure 4. Activity ratio diagrams for zircon from Veniaminof plutonic blocks analyzed by SHRIMP RG. Heavy solid lines are isochrons and model ages calculated with Isoplot ( Ludwig, 2003 ); straight dashed lines in B–F are isochrons from other samples; Th/U weight ratio scale at top of each diagram
Image
Figure 6. Cross section through Mount Veniaminof and intrusive complex–mush column. No scale.

Figure 6. Cross section through Mount Veniaminof and intrusive complex–mush... Available to Purchase

Published: 01 June 2007
Figure 6. Cross section through Mount Veniaminof and intrusive complex–mush column. No scale.
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Seismicity plots for mw and Mt. Veniaminof, before and after the dfe. (a) 6-hour-long pseudohelicorder plot for station wanc, on mw volcano, 1 October 2002. Data are band-passed between 0.8 and 5 Hz. Earthquakes that meet the counting criteria are enclosed in boxes (see text). (b) Same as (a) for 16 November 2002. Large events are aftershocks of the dfe. (c) and (d) Pseudohelicorder plots for station vnnf on mv volcano, recorded on 19 October 2002 and 16 November 2002, respectively.

Seismicity plots for mw and Mt. Veniaminof, before and after the dfe . (... Available to Purchase

Published: 01 December 2004
Figure 3. Seismicity plots for mw and Mt. Veniaminof, before and after the dfe . (a) 6-hour-long pseudohelicorder plot for station wanc , on mw volcano, 1 October 2002. Data are band-passed between 0.8 and 5 Hz. Earthquakes that meet the counting criteria are enclosed in boxes (see text
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Twenty-four-hour helicorder plots from station VNSS on Veniaminof volcano for the 24-hr periods before and after the dfe. Wind noise increased throughout 3 November and largely masked smaller events on 4 November, making event counts difficult. “CP” denotes calibration pulse (two per plot). Plots were generated using “Heli_ew,” a module of the EARTHWORM data-acquisition system (e.g., Bittenbinder et al., 1994).

Twenty-four-hour helicorder plots from station VNSS on Veniaminof volcano f... Available to Purchase

Published: 01 December 2004
Figure 4. Twenty-four-hour helicorder plots from station VNSS on Veniaminof volcano for the 24-hr periods before and after the dfe . Wind noise increased throughout 3 November and largely masked smaller events on 4 November, making event counts difficult. “CP” denotes calibration pulse (two per
Journal Article

Seismic Envelope‐Based Detection and Location of Ground‐Coupled Airwaves from Volcanoes in Alaska Available to Purchase

David Fee, Matt Haney, Robin Matoza, Curt Szuberla, John Lyons, Chris Waythomas
Published: 05 April 2016
Bulletin of the Seismological Society of America (2016) 106 (3): 1024–1035.
DOI: https://doi.org/10.1785/0120150244
...Figure 5. Mt. Veniaminof data and map. (a) Multitaper spectrogram and (b) filtered waveforms for the three stations that detected the ground‐coupled airwaves. (c) The topographic map of Veniaminof with the station‐pair double difference ( SPDD ) locations (orange dots). The active vent is denoted...
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Journal Article

Earthquake Triggering at Alaskan Volcanoes Following the 3 November 2002 Denali Fault Earthquake Available to Purchase

Seth C. Moran, John A. Power, Scott D. Stihler, John J. Sánchez, Jacqueline Caplan-Auerbach
Published: 01 December 2004
Bulletin of the Seismological Society of America (2004) 94 (6B): S300–S309.
DOI: https://doi.org/10.1785/0120040608
...Figure 4. Twenty-four-hour helicorder plots from station VNSS on Veniaminof volcano for the 24-hr periods before and after the dfe . Wind noise increased throughout 3 November and largely masked smaller events on 4 November, making event counts difficult. “CP” denotes calibration pulse (two per...
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Book Chapter

Volcano monitoring Available to Purchase

Author(s)
James G. Smith, Jonathan Dehn, Richard P. Hoblitt, Richard G. LaHusen, Jacob B. Lowenstern, Seth C. Moran, Lindsay McClelland, Kenneth A. McGee, Manuel Nathenson, Paul G. Okubo, John S. Pallister, Michael P. Poland, John A. Power, David J. Schneider, Thomas W. Sisson
Book: Geological Monitoring
Publisher: Geological Society of America
Published: 01 January 2009
DOI: 10.1130/2009.monitoring(12)
EISBN: 9780813759432
..., Korovin, Veniaminof, and Anatahan, exhibit one or more signs of restlessness, such as anomalous earthquakes, deformation of the volcano's surface, or changes in volume and composition Introduction to Volcano Resources Vital Sign 2. Ground Deformation Study Design Case Study Mount Rainier...
Abstract
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Abstract Volcanoes are not randomly distributed over the Earth's surface. Most are concentrated on the edges of continents, along island chains, or beneath the sea where they form long mountain ranges. More than half of the world's active volcanoes above sea level encircle the Pacific Ocean (see Fig. 1 ). The concept of plate tectonics explains the locations of volcanoes and their relationship to other large-scale geologic features. The Earth's surface is made up of a patchwork of about a dozen large plates and a number of smaller ones that move relative to one another at &lt;1 cm to ~10 cm/yr (about the speed at which fingernails grow). These rigid plates, with average thickness of ~80 km, are separating, sliding past each other, or colliding on top of the Earth's hot, viscous interior. Volcanoes tend to form where plates collide or spread apart ( Fig. 2 ) but can also grow in the middle of a plate, like the Hawaiian volcanoes ( Fig. 3 ). Of the more than 1,500 volcanoes worldwide believed to have been active in the past 10,000 years, 169 are in the United States and its territories ( Ewert et al., 2005 ) (see Fig. 4 ). As of spring 2007, two of these volcanoes, Kilauea and Mount St. Helens, are erupting, while several others, including Mauna Loa, Fourpeaked, Korovin, Veniaminof, and Anatahan, exhibit one or more signs of restlessness, such as anomalous earthquakes, deformation of the volcano's surface, or changes in volume and composition

Journal Article

Nonvolcanic Tremor in the Aleutian Arc Available to Purchase

C. L. Peterson, S. R. McNutt, D. H. Christensen
Published: 01 December 2011
Bulletin of the Seismological Society of America (2011) 101 (6): 3081–3087.
DOI: https://doi.org/10.1785/0120100241
...Figure 3. Amplitudes and arrival times of an NVT event recorded on the Veniaminof (VN) and Peulik (PL) seismic networks. Panel (a) shows the maximum amplitude of the two largest pulses within the tremor event. The Veniaminof stations record larger amplitudes than the Peulik stations. Panel (b...
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Figure 2. Textures of plutonic blocks from ca. 3700 yr B.P. eruption of Veniaminof. A: Broken surface of porous miarolitic granodiorite 02TSV060. Plagioclase, quartz, hornblende, and Ti-poor magnetite protrude into cavities formerly occupied by magmatic aqueous fluid and/or vapor. B: Broken surface of miarolitic gabbroic cumulate 04CBV337. Segregated residual melt, now felsite, has large cavities. Cumulate has intercrystalline voids.

Figure 2. Textures of plutonic blocks from ca. 3700 yr B.P. eruption of Ven... Available to Purchase

Published: 01 June 2007
Figure 2. Textures of plutonic blocks from ca. 3700 yr B.P. eruption of Veniaminof. A: Broken surface of porous miarolitic granodiorite 02TSV060. Plagioclase, quartz, hornblende, and Ti-poor magnetite protrude into cavities formerly occupied by magmatic aqueous fluid and/or vapor. B: Broken surface
Journal Article

Compositional variation in the chevkinite group: new data from igneous and metamorphic rocks Available to Purchase

R. Macdonald, H. E. Belkin, F. Wall, B. bagiński
Published: 01 October 2009
Mineralogical Magazine (2009) 73 (5): 777–796.
DOI: https://doi.org/10.1180/minmag.2009.073.5.777
... between rutile and phlogopite grains. T.W. Sisson (U.S. Geological Survey) identified a chevkinite-group mineral associated spatially with miarolitic cavities in plutonic blocks erupted at ∼3700 y BP during the most recent caldera-forming eruption of the Veniaminof volcano, Alaska ( Bacon et al...
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Natural and experimental lava flows advancing on ice and snow. A: Lava flow emplaced into ice-filled caldera during 1983 eruption at Mount Veniaminof, Alaska (photo by E. Yount, Alaska Volcano Observatory, U.S. Geological Survey). Pit in ice is ∼1300 m wide. B: Lava flowing over bed of ice 12 cm thick. Lava flow is 15 cm wide. C: Lava flowing over snow 12 cm thick. Lava flow is ∼20 cm wide.

Natural and experimental lava flows advancing on ice and snow. A: Lava flow... Available to Purchase

Published: 01 August 2013
Figure 1. Natural and experimental lava flows advancing on ice and snow. A: Lava flow emplaced into ice-filled caldera during 1983 eruption at Mount Veniaminof, Alaska (photo by E. Yount, Alaska Volcano Observatory, U.S. Geological Survey). Pit in ice is ∼1300 m wide. B: Lava flowing over bed
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Map and network layouts. (a) Alaska and the three studied volcanoes. (b) Cleveland Volcano (red triangle) in relation to the Okmok seismic network ∼130–150  km distant. (c) Mt. Veniaminof and associated seismic network, consisting of 10 stations spread over an ∼30×30  km2 region. (d) Pavlof Volcano and seismic network of five stations over ∼16×15  km2. Contours in (b–d) are determined from ASTER and ETOPO datasets and are shown at 200, 400, and 400 m, respectively.

Map and network layouts. (a) Alaska and the three studied volcanoes. (b) Cl... Available to Purchase

Published: 05 April 2016
Figure 1. Map and network layouts. (a) Alaska and the three studied volcanoes. (b) Cleveland Volcano (red triangle) in relation to the Okmok seismic network ∼130–150  km distant. (c) Mt. Veniaminof and associated seismic network, consisting of 10 stations spread over an ∼30×30  km 2 region. (d
Journal Article

A Comparison of Seismic Event Detection with IASPEI and Earthworm Acquisition Systems at Alaskan Volcanoes Available to Purchase

James P. Dixon, John A. Power, Scott D. Stihler
Published: 01 March 2005
Seismological Research Letters (2005) 76 (2): 168–176.
DOI: https://doi.org/10.1785/gssrl.76.2.168
... had significant volcanic activity within the last 15 years that might have affected the seismicity rates; and the Veniaminof, Okmok, Tanaga, and Gareloi subnetworks were installed after the change to the Earthworm data acquisition system. The data from the three seismograph subnetworks were...
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Seismological notes Available to Purchase

Published: 01 July 1939
Bulletin of the Seismological Society of America (1939) 29 (3): 513–516.
DOI: https://doi.org/10.1785/BSSA0290030513
... in Healdsburg and vicinity. Perryville, Alaska, June 7, 1939Earthquakes accompanying the eruption of Mount Veniaminof continued but were of less intensity than they had been since the volcano began erupting two weeks previously. Ponce, Puerto Rico, June 11, 1939A slight earthquake shook Puerto Rico about...
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