Eruptive Cycle and Bubble Trap of Strokkur Geyser, Iceland

Eibl, Eva P. S.; Müller, Daniel; Walter, Thomas R.; Allahbakhshi, Masoud; Jousset, Philippe; Hersir, Gylfi Páll; Dahm, Torsten

doi:10.1029/2020jb020769

Cited by 18 publications

(69 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is observed in the Western part of the Hhf where lack of high vegetation mimics the boundaries of the highly resistive region (dashed black lines in Figure 9). The interpretation of this volume as a vapor-saturated reservoir would agree with Eibl et al (2020); Eibl et al (2021) who suggest the occurrence of a shallow bubble trap about 13-23 m West of Strokkur and at about 25-30 m depth. Figure 4 shows that the most prominent hydrothermal features of the Hhf are emplaced at the margins of highly resistive regions.…”

Section: Discussionsupporting

confidence: 82%

“…It is suggested that Strokkur and Great Geysir geysers develop along vertical fracture-like pipes reaching at least 20 m depth (Pasvanoglu et al, 1998;Torfason & Davíðsson, 1985;Walter et al, 2018). Yet, besides indirect geophysical studies [e.g., Eibl et al (2020) and Eibl et al (2021)] little is known about the plumbing system at depth. Pasvanoglu et al (1998) propose that the ground water system of Hhf is recharged by meteoric waters flowing from the Langjöokull ice-sheet to the North.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Geysers, Boiling Groundwater and Tectonics: The 3D Subsurface Resistive Structure of the Haukadalur Hydrothermal Field, Iceland

Lupi

Collignon

Fischanger³

et al. 2022

JGR Solid Earth

View full text Add to dashboard Cite

show abstract

Section: Discussionsupporting

confidence: 82%

mentioning

confidence: 99%

Geysers, Boiling Groundwater and Tectonics: The 3D Subsurface Resistive Structure of the Haukadalur Hydrothermal Field, Iceland

Lupi

Collignon

Fischanger³

et al. 2022

JGR Solid Earth

View full text Add to dashboard Cite

show abstract

“…When the seismic source only releases a small amount of energy, and the distance of the source to the station is large, PE seems to reflect more the filtering of the seismic wave during its propagation to the station. This is also supported by the findings of Eibl et al (2021), who could not use these stations for the seismic source location due to low-quality particle motions. By contrast, the drop of PE prior to the 5.6 Mw earthquake at Bárðarbunga two days before the 1996 Gjálp eruption, could be detected by stations at a 100 km distance (Glynn & Konstantinou, 2016).…”

Section: The Influence Of Source Strength and Path Effects Toward The...supporting

confidence: 70%

“…The epicenters of the sources were estimated from the intersection of the azimuth angles derived from all 5 stations. Eibl et al (2021) project the epicenter location vertically down and extract the source depth from the intersection point with the derived incidence angles for all stations. Note that the shallow source depths during P1 and peaks in P4 are poorly constrained since the particle motion shows an elliptical particle motion characteristic for Rayleigh waves when the seismic sources reach or approach the surface.…”

Section: Stacked Pe Rms and Hypocentral Distances Of 53 Single Eruptionsmentioning

confidence: 99%

“…S1 is located about 10 m to the south of the conduit on the surface. Eibl et al (2021) estimated the source location by using the particle motion of the recorded seismic waves. The epicenters of the sources were estimated from the intersection of the azimuth angles derived from all 5 stations.…”

Section: Stacked Pe Rms and Hypocentral Distances Of 53 Single Eruptionsmentioning

confidence: 99%

See 1 more Smart Citation

Eruption Forecasting of Strokkur Geyser, Iceland, Using Permutation Entropy

et al. 2022

Self Cite

View full text Add to dashboard Cite

A volcanic eruption is usually preceded by seismic precursors, but their interpretation and use for forecasting the eruption onset time remain a challenge. A part of the eruptive processes in open conduits of volcanoes may be similar to those encountered in geysers. Since geysers erupt more often, they are useful sites for testing new forecasting methods. We tested the application of Permutation Entropy (PE) as a robust method to assess the complexity in seismic recordings of the Strokkur geyser, Iceland. Strokkur features several minute‐long eruptive cycles, enabling us to verify in 63 recorded cycles whether PE behaves consistently from one eruption to the next one. We performed synthetic tests to understand the effect of different parameter settings in the PE calculation. Our application to Strokkur shows a distinct, repeating PE pattern consistent with previously identified phases in the eruptive cycle. We find a systematic increase in PE within the last 15 s before the eruption, indicating that an eruption will occur. We quantified the predictive power of PE, showing that PE performs better than seismic signal strength or quiescence when it comes to forecasting eruptions.

show abstract