Volcano Monitoring With Magnetic Measurements: A Simulation of Eruptions at Axial Seamount, Kīlauea, Bárðarbunga, and Mount Saint Helens

Biasi, Joseph; Tivey, Maurice A.; Fluegel, Bailey

doi:10.1029/2022gl100006

Cited by 3 publications

(6 citation statements)

References 77 publications

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“…This is consistent with independent geophysical data (Chadwick et al, 2022) which shows that Axial, while it has inflated to ∼90% of its pre-eruption level, has a magma supply rate that has been waning since the last eruption in 2015, so that any future eruption is still years away. Furthermore, magnetic modeling of Axial Seamount (Biasi et al, 2022) shows that while a thermal zone extends beyond the magma body itself, the northern part of the caldera needed extensive cooling to replicate the results reported here.…”

Section: Resultssupporting

confidence: 73%

“…This thermally demagnetized zone may grow prior to an impending eruption due to the inflation of the magma chamber that is known to occur prior to eruptions (Chadwick et al., 2022; Nooner & Chadwick, 2016). If true, we may be able to measure magnetic changes in this zone as it enlarges (Biasi et al., 2022). However, it is also possible that seawater circulation within the shallow fractured crust overlying the magma chamber would keep the crust cool creating a cold lid that would restrict the extent of the thermal zone to some depth and may only change once lava has erupted to the surface.…”

Section: Introductionmentioning

confidence: 99%

“…Our data analysis may help determine which of these thermal zone hypotheses is supported by evidence. Furthermore, if successful, magnetic surveys may provide a low‐cost and efficient method for gathering frequent temporal data in comparison to other forms of geophysical surveys (Biasi et al., 2022), and could provide valuable insights into the internal workings of Axial Seamount.…”

Section: Introductionmentioning

confidence: 99%

“…More recent seismic imaging of Axial confirms the presence of an elongate magma chamber (MMR in Figure 1) beneath the summit caldera of Axial (Arnulf et al, 2014(Arnulf et al, , 2018Carbotte et al, 2020) and a smaller secondary reservoir to the east (SMR in Figure 1). The thermal signature of the main magma chamber, the internal lava feeder system, and the slow re-inflation of the summit since 2015 may be detectable using magnetic fields (Biasi et al, 2022). Here, we present the first study of temporal magnetic imaging using repeat surveys of high-resolution, near-bottom magnetic data gathered over the summit of Axial Seamount since 2015 with the autonomous underwater vehicle (AUV) Sentry.…”

mentioning

confidence: 99%

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The Magnetization of an Underwater Caldera: A Time‐Lapse Magnetic Anomaly Study of Axial Seamount

Fluegel

Tivey

Biasi

et al. 2022

Geophysical Research Letters

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Axial Seamount is the most active underwater volcano in the northeast Pacific located ∼480 km off the coast of Oregon (45°56′N, 130°00′W). It is situated on the diverging midocean ridge boundary of the Juan de Fuca and Pacific plates, which has an intermediate spreading rate of 5-6 cm/yr (Wilson, 1988, Figure 1). It is also the location of the world's first underwater volcano observatory New Millennium Observatory and since 2014 has been the location of the National Science Foundation's Ocean Observatory Initiative Regional Cabled Array, which records real-time data from a network of monitoring instruments (Embley & Baker, 1999;Kelley et al., 2014). The volcano rises to a depth of about 1,400 m and has a distinct 3 × 8 km horseshoe-shaped caldera present at its summit (Figure 1). The caldera walls rise about 100 m above the caldera floor. The caldera floor is comprised of unsedimented basaltic lava flows and active hydrothermal vent systems are found along the caldera margin faults.

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Section: Resultssupporting

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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The Magnetization of an Underwater Caldera: A Time‐Lapse Magnetic Anomaly Study of Axial Seamount

Fluegel

Tivey

Biasi

et al. 2022

Geophysical Research Letters

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“…Future magnetic studies at Kīlauea should now focus on monitoring geomagnetic field variations associated to the evolution of the volcanic system since the 2018 crisis. Studying the evolution of magnetic anomalies within volcanic edifices will help to highlight spatio‐temporal changes in magmatic and hydrothermal dynamics, mechanical processes and weakness zones (Biasi et al., 2022; Gailler & Kauahikaua, 2017). Promising ongoing studies are in progress, for example, at the scale of Piton de la Fournaise (Réunion Island) where the evolution of the volcanic activity is associated with volcano‐magnetic variations (Zlotnicki et al., 1993).…”

Section: Discussionmentioning

confidence: 99%

The Subsurface Structure of the Kīlauea Caldera Before Its 2018 Collapse Inferred From Ground Magnetic, SP, and Temperatures Anomalies

Gailler,

Bouligand,

Kauahikaua

et al. 2024

JGR Solid Earth

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The 2018 crisis of Kīlauea volcano stands as a major event in its evolution with a large down‐rift effusive eruption that drained a shallow magma reservoir at the summit. The characterization of such active magmatic systems and associated hazardous events remains a necessity and a challenge. The summit area is hydrothermally active and strongly altered as indicated by geological mapping. A unique data set of geophysical measurements was collected around Halemaʻumaʻu crater before its collapse. Magnetic data are interpreted here in combination with geological information, temperature anomalies at the surface, self‐potential measurements, and a model of electrical conductivity. 3D forward modeling shows that the main magnetic dipole‐like anomaly observed around the crater is not only caused by the crater topography but suggests the presence of an important volume of weakly magnetic material beneath the crater, which may be caused by higher temperature and/or hydrothermal alteration. 3D inversion of the data allows us to explore the first order geometry of the magnetic structures. We complement this inversion with 2D forward modeling in order to refine the geometry of major structures. This study shows the presence of major geological structures in the 2018 collapsed area that may have been associated with mechanical weaknesses and could have played a role in the geometry of the collapse. Therefore, mapping magnetic anomalies and monitoring their temporal evolution are of great interest for constraining the nature and mechanical properties of the underlying formations and their temporal evolution in order to help predict future behavior.

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Hydroacoustic Monitoring of Mayotte Submarine Volcano during Its Eruptive Phase

Lavayssière,

Bazin,

Royer

2024

Geosciences

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Submarine volcanoes are more challenging to monitor than subaerial volcanoes. Yet, the large eruption of the Hunga Tonga-Hunga Ha’apai volcano in the Tonga archipelago in 2022 was a reminder of their hazardous nature and hence demonstrated the need to study them. In October 2020, four autonomous hydrophones were moored in the sound fixing and ranging channel 50 km offshore Mayotte Island, in the North Mozambique Channel, to monitor the Fani Maoré 2018–2020 submarine eruption. Between their deployment and July 2022, this network of hydrophones, named MAHY, recorded sounds generated by the recent volcanic activity, along with earthquakes, submarine landslides, marine mammals calls, and marine traffic. Among the sounds generated by the volcanic activity, impulsive signals have been evidenced and interpreted as proxy for lava flow emplacements. The characteristics and the spatio-temporal evolution of these hydroacoustic signals allowed the estimation of effusion and flow rates, key parameters for volcano monitoring. These sounds are related to the non-explosive quenching of pillow lavas due to the rapid heat transfer between hot lava and cold seawater, with this process releasing an energy equivalent to an airgun source as used for active seismic exploration. Volcano observatories could hence use autonomous hydrophones in the water column to detect and monitor active submarine eruptions in the absence of regular on-site seafloor survey.

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Volcano Monitoring With Magnetic Measurements: A Simulation of Eruptions at Axial Seamount, Kīlauea, Bárðarbunga, and Mount Saint Helens

Cited by 3 publications

References 77 publications

The Magnetization of an Underwater Caldera: A Time‐Lapse Magnetic Anomaly Study of Axial Seamount

The Magnetization of an Underwater Caldera: A Time‐Lapse Magnetic Anomaly Study of Axial Seamount

The Subsurface Structure of the Kīlauea Caldera Before Its 2018 Collapse Inferred From Ground Magnetic, SP, and Temperatures Anomalies

Hydroacoustic Monitoring of Mayotte Submarine Volcano during Its Eruptive Phase

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