Sheared sheet intrusions as mechanism for lateral flank displacement on basaltic volcanoes: Applications to Réunion Island volcanoes

Cayol, Valérie; Catry, Thibault; Michon, Laurent; Chaput, Marie; Famin, Vincent; Bodart, Olivier; Froger, Jean‐Luc; Romagnoli, Claudia

doi:10.1002/2014jb011139

Cited by 16 publications

(12 citation statements)

References 93 publications

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“…Thus, the rake is fixed at 90°based on the eastward GPS displacement recorded between 2 and 10 April at the only station (FERg) located to the east of the summit [Peltier et al, 2009a]. We also use a modified computation where fracture interpenetration is not permitted, a condition enforced through the use of Lagrange multipliers as explained in Cayol et al [2014]…”

Section: Inverse Modeling Methodsmentioning

confidence: 99%

“…Because we questioned whether the obtained closure was really required to explain the surface displacement, inversions preventing fracture interpenetration were also conducted [Cayol et al, 2014]. A demonstrably less good fit was obtained (RMSE = 3.52 and AIC = 2889, inversion termed "No interp" in Table 4), which indicates that closure of the fracture is the most likely model.…”

Section: Nonlinear Inversion Of Geometry Location and Homogeneous Smentioning

confidence: 99%

“…resulting fracture is submitted not only to overpressure but also to tangential stress. When the volcano stress field resulting from gravity is extensive, simultaneous cointrusive flank displacement and fracture opening are induced [Cayol et al, 2014;Chaput et al, 2014a]. Following this approach, Chaput et al [2014b] proposed a new model for flank failure of basaltic volcanoes in which cycles of stress permutations explain the variety of stress fields, as inferred from detailed microstructural studies at Piton des Neiges.…”

Section: Introductionmentioning

confidence: 99%

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Inversion of coeval shear and normal stress of Piton de la Fournaise flank displacement

et al. 2016

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The April 2007 eruption of Piton de la Fournaise was the biggest volcano eruptive crisis of the 20th and 21st centuries. Interferometric synthetic aperture radar (InSAR) captured a large coeruptive seaward displacement on the volcano's eastern flank, which continued for more than a year at a decreasing rate. Coeruptive uplift and posteruptive subsidence were also observed. While it is generally agreed that flank displacement is induced by fault slip, we suggest that this flank displacement might have been induced by a sheared sill, based on observations of sheared sills at Piton des Neiges. To test this hypothesis, we develop a new method to invert a quadrangular curved source submitted to simultaneous pressure and shear stress changes. This method, based on boundary elements, is applied to data acquired along six Envisat orbits covering a 14 month period subsequent to the April 2007 eruption. Posteruptive displacement is well explained by closure and slip of a large (5 km by 8 km) and shallow (500 m) trapezoidal fracture parallel to the flank and probably coincident with a lithological discontinuity. We investigate whether thermal contraction or degassing of a coeruptive sill can explain the displacement. Such a sill would have to be 10 times thicker than inferred from the coeruptive uplift and solidification time 10 times shorter (~20 days) than the duration of the posteruptive subsidence (24 to 33 months). Instead, we propose that the posteruptive eastern flank displacement is due to the compaction and ongoing slow slip on a shallow detachment fault.

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Section: Inverse Modeling Methodsmentioning

confidence: 99%

Section: Nonlinear Inversion Of Geometry Location and Homogeneous Smentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Inversion of coeval shear and normal stress of Piton de la Fournaise flank displacement

et al. 2016

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“…Since then, the role of sheared sill intrusions as a trigger of flank instability has been tested numerically. Using the observed geometry of the Piton des Neiges sill zone, Cayol et al (2014) computed that the injection of sills in a volcanic edifice undergoing extension would generate an averaged shear displacement of 3.7 m per sill, or a total lateral displacement of 180-260 m for the sill zone. In addition, (Chaput et al, 2014a) showed that the injection of a sill could be sufficient to activate a detachment such as the one found at Piton des Neiges.…”

Section: Implication For the Role Of Sill Intrusions In Volcano Flankmentioning

confidence: 99%

“…Each sill would activate slip on the detachment, progressively increasing flank instability and eventually leading to flank failure. This model has been tested by numerical simulations, which show that sill intrusions in a volcanic edifice under extension may indeed yield lateral flank displacements, and may also activate a pre-existing detachment (Cayol et al, 2014;Chaput et al, 2014a). However, there is to date no observational constraints that sill intrusions cause a shear displacement during their emplacement.…”

Section: Introductionmentioning

confidence: 99%

Evidence of sheared sills related to flank destabilization in a basaltic volcano

et al. 2016

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International audiencePiton des Neiges basaltic volcano (La Réunion) has been deeply dissected by erosion, exposing large volumes of debris avalanche deposits. To shed light on the factors that led to volcano flank destabilizations, we studied the structure, the crystallographic and magnetic fabrics of the substratum of a debris avalanche unit. This substratum is a complex of N50 seaward-dipping sills that has been exposed by the avalanche. Structural observations show that the sill plane in contact with the avalanche is one of the latest intrusions in the sill complex. In this uppermost sill, the anisotropy of magnetic susceptibility (AMS) is correlated to the crystallographic preferred orientation of magmatic silicate minerals, allowing us to use AMS as a proxy to infer the magmatic flow. The AMS fabric across the intrusion is strongly asymmetric, which reveals that the contact sill was emplaced with a normal shear displacement of its hanging wall. The shear displacement and the magma flow in the intrusion are both directed toward the NNE, i.e. toward the sea, which is also the direction of the slope and of the debris avalanche runout. Because all the sills in the intrusion complex have a similar dip and dip direction, it is likely that several of them also underwent a cointrusive slip toward the NNE. We conclude that this cointrusive normal slip, repeated over many intrusions of the sill complex, increased the flank instability of the volcano. This incre-mental instability may have ended up into the observed debris avalanche deposit. At Piton de la Fournaise, the active volcano of La Réunion, sill intrusion and cointrusive flank displacement have been inferred from geophys-ical studies for the April 2007 eruption. By providing direct evidence of sheared sills, our study substantiates the idea that repeated sill intrusions may eventually trigger flank destabilizations in basaltic volcanoes

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What triggers caldera ring-fault subsidence at Ambrym volcano? Insights from the 2015 dike intrusion and eruption

Shreve

Grandin

Smittarello

et al. 2021

Preprint

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Surface deformation accompanying dike intrusions is dominated by uplift and horizontal motion directly related to the intrusions. In some cases, it includes subsidence due to associated magma reservoir deflation. When reservoir deflation is large enough, it can form, or reactivate pre-existing, caldera ring-faults. Ring-fault reactivation, however, is rarely observed during moderate-sized eruptions. On February 21st, 2015 at Ambrym volcano in Vanuatu, a basaltic dike intrusion produced more than 1 meter of co-eruptive uplift, as measured by InSAR, SAR correlation, and Multiple Aperture Interferometry (MAI). Here we show that an average of ∼40 cm of slip occurred on a normal caldera ring-fault during this moderate-sized (VEI<3) event, which intruded a volume of ∼24×10 6 m 3 and erupted ∼9.3×10 6 m 3 of lava (DRE). Using the 3D Mixed Boundary Element Method, we explore the stress change imposed by the opening dike and the depressurizing reservoir on a passive, frictionless fault. Normal fault slip is promoted when stress is transferred from a depressurizing reservoir beneath one of Ambrym's main craters. After estimating magma compressibility, we provide an upper-bound on the critical fraction (f = 7%) of magma extracted from the reservoir to trigger fault slip. We infer that broad basaltic calderas may form in part by hundreds of subsidence episodes no greater than a few meters, as a result of magma extraction from the reservoir during moderatesized dike intrusions.

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Sheared sheet intrusions as mechanism for lateral flank displacement on basaltic volcanoes: Applications to Réunion Island volcanoes

Cited by 16 publications

References 93 publications

Inversion of coeval shear and normal stress of Piton de la Fournaise flank displacement

Inversion of coeval shear and normal stress of Piton de la Fournaise flank displacement

Evidence of sheared sills related to flank destabilization in a basaltic volcano

What triggers caldera ring-fault subsidence at Ambrym volcano? Insights from the 2015 dike intrusion and eruption

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