Fluid resonance in elastic-walled englacial transport networks

McQuillan, Maria; Karlstrom, L.

doi:10.1017/jog.2021.48

Cited by 3 publications

(3 citation statements)

References 58 publications

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“…In this case, the drastic change in VLP periods over the early part of the eruption likely represents an evolving conduit geometry due to some combination of a widening upper conduit and a change in conduit length due to a changing dip angle and reservoir attachment depth. A shallow dike/sill above the main Halema'uma'u reservoir could have also impacted the resonance (54); this would potentially be consistent with some seismic inversions (21,33), but such additional source complexity is not needed according to other seismic and geodetic inversions (7,9,11).…”

Section: An Evolving Magma Plumbing System Geometrymentioning

confidence: 79%

Evolving magma temperature and volatile contents over the 2008–2018 summit eruption of Kīlauea Volcano

Crozier

Karlstrom

2022

Sci. Adv.

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Magma rheology and volatile contents exert primary and highly nonlinear controls on volcanic activity. Subtle changes in these magma properties can modulate eruption style and hazards, making in situ inference of their temporal evolution vital for volcano monitoring. Here, we study thousands of impulsive magma oscillations within the shallow conduit and lava lake of Kīlauea Volcano, Hawai‘i, USA, over the 2008–2018 summit eruptive sequence, encoded by “very-long-period” seismic events and ground deformation. Inversion of these data with a petrologically informed model of magma dynamics reveals significant variation in temperature and highly disequilibrium volatile contents over days to years, within a transport network that evolved over the eruption. Our results suggest a framework for inferring subsurface magma dynamics associated with prolonged eruptions in near real time that synthesizes petrologic and geophysical volcano monitoring approaches.

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Section: An Evolving Magma Plumbing System Geometrymentioning

confidence: 79%

Evolving magma temperature and volatile contents over the 2008–2018 summit eruption of Kīlauea Volcano

Crozier

Karlstrom

2022

Sci. Adv.

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“…First, moulin cross-sectional area, and thus water storage capacity, can vary substantially over the course of a day or season (Figs. 6c and 9b), and features such as englacial crevasses and reservoirs may be present (e.g., McQuillan and Karlstrom, 2021). Second, in instances where moulins are reactivated over multiple melt seasons (Chu, 2014;Smith et al, 2017), there may be substantial deformation, as suggested by cable breakage in boreholes (Ryser et al, 2014;Wright et al, 2016).…”

Section: Comparison Of Modeled and Observed Moulin Geometriesmentioning

confidence: 99%

Controls on Greenland moulin geometry and evolution from the Moulin Shape model

2022

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Abstract. Nearly all meltwater from glaciers and ice sheets is routed englacially through moulins. Therefore, the geometry and evolution of moulins has the potential to influence subglacial water pressure variations, ice motion, and the runoff hydrograph delivered to the ocean. We develop the Moulin Shape (MouSh) model, a time-evolving model of moulin geometry. MouSh models ice deformation around a moulin using both viscous and elastic rheologies and melting within the moulin through heat dissipation from turbulent water flow, both above and below the water line. We force MouSh with idealized and realistic surface melt inputs. Our results show that, under realistic surface melt inputs, variations in surface melt change the geometry of a moulin by approximately 10 % daily and over 100 % seasonally. These size variations cause observable differences in moulin water storage capacity and moulin water levels compared to a static, cylindrical moulin. Our results suggest that moulins are important storage reservoirs for meltwater, with storage capacity and water levels varying over multiple timescales. Implementing realistic moulin geometry within subglacial hydrologic models may therefore improve the representation of subglacial pressures, especially over seasonal periods or in regions where overburden pressures are high.

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“…Crack waves (and their induced tube waves in wellbores) are used for diagnosing the fracture geometries in unconventional hydrocarbon reservoirs (Henry et al., 2002; Liang et al., 2017; Lipovsky & Dunham, 2015; Tary et al., 2014). The resonating or humming signals in glaciers have also been attributed to crack waves (Gräff et al., 2019; McQuillan & Karlstrom, 2021; Métaxian et al., 2003; Stuart et al., 2005). Natural cracks in the subsurface are complex in shape and usually form an inter‐connected network.…”

Section: Introductionmentioning

confidence: 99%

Resonances of Fluid‐Filled Cracks With Complex Geometry and Application to Very Long Period (VLP) Seismic Signals at Mayotte Submarine Volcano

Liang,

Peng,

Ampuero

et al. 2024

JGR Solid Earth

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Fluid‐filled cracks sustain a slow guided wave (Krauklis wave or crack wave) whose resonant frequencies are widely used for interpreting long period (LP) and very long period (VLP) seismic signals at active volcanoes. Significant efforts have been made to model this process using analytical developments along an infinite crack or numerical methods on simple crack geometries. In this work, we develop an efficient hybrid numerical method for computing resonant frequencies of complex‐shaped fluid‐filled cracks and networks of cracks and apply it to explain the ratio of spectral peaks in the VLP signals from the Fani Maoré submarine volcano that formed in Mayotte in 2018. By coupling triangular boundary elements and the finite volume method, we successfully handle complex geometries and achieve computational efficiency by discretizing solely the crack surfaces. The resonant frequencies are directly determined through eigenvalue analysis. After proper verification, we systematically analyze the resonant frequencies of rectangular and elliptical cracks, quantifying the effect of aspect ratio and crack stiffness. We then discuss theoretically the contribution of fluid viscosity and seismic radiation to energy dissipation. Finally, we obtain a crack geometry that successfully explains the characteristic ratio between the first two modes of the VLP seismic signals from the Fani Maoré submarine volcano in Mayotte. Our work not only reveals rich eigenmodes in complex‐shaped cracks but also contributes to illuminating the subsurface plumbing system of active volcanoes. The developed model is readily applicable to crack wave resonances in other geological settings, such as glacier hydrology and hydrocarbon reservoirs.

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Fluid resonance in elastic-walled englacial transport networks

Cited by 3 publications

References 58 publications

Evolving magma temperature and volatile contents over the 2008–2018 summit eruption of Kīlauea Volcano

Evolving magma temperature and volatile contents over the 2008–2018 summit eruption of Kīlauea Volcano

Controls on Greenland moulin geometry and evolution from the Moulin Shape model

Resonances of Fluid‐Filled Cracks With Complex Geometry and Application to Very Long Period (VLP) Seismic Signals at Mayotte Submarine Volcano

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