2019
DOI: 10.1186/s40623-019-1003-0
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Geophysical examination of the 27 April 2016 Whakaari/White Island, New Zealand, eruption and its implications for vent physiognomies and eruptive dynamics

Abstract: At approximately 09:36 UTC on 27 April 2016, a phreatic eruption occurred on Whakaari Island (White Island) producing an eruption sequence that contained multiple eruptive pulses determined to have occurred over the first 30 min, with a continuing tremor signal lasting ~ 2 h after the pulsing sequence. To investigate the eruption dynamics, we used a combination of cross-correlation and coherence methods with acoustic data. To estimate locations for the eruptive pulses, seismic data were collected and eruption … Show more

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Cited by 19 publications
(22 citation statements)
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References 72 publications
(94 reference statements)
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“…To unravel this event, we describe the eruption deposits and the relative timing between the ballistic pulses (derived from the seismoacoustic data) and surge generation. We refine our timeline and impacts with the geophysical monitoring data (Walsh et al 2019) to determine the number of pulses that ejected material beyond the crater area. Finally, we illustrate the emplacement dynamics and implied hazard of phreatic eruptions in the area proximal to the crater lake.…”
Section: White Islandmentioning
confidence: 99%
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“…To unravel this event, we describe the eruption deposits and the relative timing between the ballistic pulses (derived from the seismoacoustic data) and surge generation. We refine our timeline and impacts with the geophysical monitoring data (Walsh et al 2019) to determine the number of pulses that ejected material beyond the crater area. Finally, we illustrate the emplacement dynamics and implied hazard of phreatic eruptions in the area proximal to the crater lake.…”
Section: White Islandmentioning
confidence: 99%
“…As the eruption was unwitnessed, the number of eruptive pulses that contributed to the ballistic field could only be determined based on seismic and acoustic signals. White Island hosts two permanent Geonet seismometers with acoustic sensors (Walsh et al 2019) and due to the ongoing higher activity level since 2000, three additional temporary seismometers were on the island at the time of We focussed most of the photogrammetry survey towards the western subcrater, which is periodically infilled by a warm, acidic lake. At the time, there was no lake present and this survey attempted to quantify the topography of the inner crater basin ~ 8 months after the eruption described here.…”
Section: D Volcanic Ballistic Trajectory Modellingmentioning
confidence: 99%
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“…This special issue collected intriguing examples from White Island, Kawah Ijen, and Hakone (Yukutake et al 2017Caudron et al 2018;Harada et al 2018;Jolly et al 2018;Walsh et al 2019). Walsh et al (2019) located eruptive pulses emitted during a phreatic eruption that occurred at White Island on 27 April 2018 by a joint analysis combining acoustic and seismic data. The locations of the eruption vent were inferred using an amplitude source location method, and the depth of eruption pulses was inferred from volcanic acoustic-seismic ratios.…”
Section: Signals Emitted By Phreatic Eruption-location and Source Anamentioning
confidence: 99%