A review of laboratory and numerical modelling in volcanology

Kavanagh, Janine; Engwell, Samantha; Martin, Simon

doi:10.5194/se-9-531-2018

Cited by 58 publications

(48 citation statements)

References 279 publications

(321 reference statements)

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“…In "Mode-I" deformation, linear elastic fracturing mechanics (LEFM) postulates that magma propagates as sheet intrusions through opening-mode, hydraulic fractures and bends the host rock elastically (e.g., Dahm, 2000;Delaney & Pollard, 1981;Rivalta et al, 2015). LEFM is demonstrated in laboratory models and assumed in the most common numerical models that involve a linearly elastic medium to simulate the host rock (e.g., Kavanagh et al, 2018;Maccaferri et al, 2010). Features predicted by LEFM have been observed in the field (Figure 1a): narrow, tapering tips of sheet intrusions, bending of the host rock around intrusion fronts, and a parabola-shaped cross-sectional opening profile (e.g., Airoldi et al, 2012;Daniels et al, 2012;Gudmundsson, 2002;Mastin & Pollard, 1988).…”

Section: Magma Emplacement Modelsmentioning

confidence: 99%

Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

Poppe

Galland

Winter

et al. 2020

Geochem Geophys Geosyst

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Two end‐member conceptual models are used to describe deformation of the Earth's crust induced by magma intrusion. “Mode I” fracturing assumes tensile or opening‐mode, elastic deformation, while “Mode II” fracturing assumes plastic shear‐mode deformation around a viscous indenter. Field observations of both mechanisms exist, but it remains unclear which mechanism dominates in which conditions. We describe intrusion geometries, host rock deformation, and geochemical magma‐host rock interactions around 53 exceptionally preserved, tephrite‐basanite Permian dike segments of 0.5‐ to 30‐cm thickness. These thin dikes, that is, “dikelets,” intruded Late‐Ordovician carbonate‐rich sedimentary rocks on Hovedøya island, Oslo Rift, Norway. Dikelets emplaced in preexisting fractures dominantly created cavities ahead of their narrow, tapering tips and are associated with bent host rock, broken bridges, and stepped segmented geometries. Other tips are blunt with dense brittle fracturing around them. Also, cross‐sectional intrusion segment opening profiles deviate from parabola‐shaped profiles typical for elastic media. The observations demonstrate that dominant opening‐mode host rock deformation can coexist with shear‐mode deformation locally. Alignment of most dikelet segments along the dominant host rock fracture directions highlights the control of local structural orientations on magma emplacement. Analysis of bulk major and trace element compositions, in situ micro‐XRF sample analysis and carbon and oxygen stable isotope compositions, suggests that thermochemical interactions between magma and the carbonate‐rich host rock produced a low‐viscosity mixture of magma, pore water, and gas. We propose that such low‐viscosity hybrid fluid may assist in the intrusion of magma in sedimentary rocks by filling the cavity ahead of propagating sheet intrusion tips.

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Section: Magma Emplacement Modelsmentioning

confidence: 99%

Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

Poppe

Galland

Winter

et al. 2020

Geochem Geophys Geosyst

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“…Menand (2014, 2016) built on these findings to investigate to effect of solidification on sill propagation, using two layers of gelatin of different stiffness to promote sill formation. Chanceaux and Menand (2014) scaled their experiments according to the procedure of Kavanagh et al (2013) and injected the fluid vertically at the base of the lower, less stiff silicone layer. They found four distinct regimes depending on both  and  (Fig.…”

Section: Intrusion Dynamicsmentioning

confidence: 99%

“…Air, gases Takada (1990), Muller et al (2001), Ito and Martel (2002), Rivalta et al (2005), Kervyn et al (2009), Menand et al (2010), Le Water, aqueous solutions (+ alcohol, glycerin) Takada (1990), McLeod and Tait (1999), Tait (2001, 2002), Kervyn et al (2009), Kavanagh et al (2006Kavanagh et al ( , 2013Kavanagh et al ( , 2015 Silicone oil Takada (1994), McLeod and Tait (1999), Watanabe et al (2002) Vegetable oil Takada (1990), Menand (2014, 2016), Daniels and Menand (2015) Sugar solution, Golden syrup Taisne and Tait (2009), Kervyn et al (2009) Parafin wax Taisne and Tait (2009)…”

Section: Supplementary Materialsmentioning

confidence: 99%

The contribution of experimental volcanology to the study of the physics of eruptive processes, and related scaling issues: A review

Roche

Carazzo

2019

Journal of Volcanology and Geothermal Research

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The experimental approach has become a major tool increasingly used by volcanologists in recent decades to investigate the physics of eruptive processes in complement to field and theoretical works. Researchers have developed various methodologies to study volcanic phenomena at reduced length scale. The works involve natural or analogue materials and their types range from first-order tests, to identify fundamental processes and make qualitative comparison with field observations, to more sophisticated experiments in which precise data obtained in a controlled environment can be used to validate outputs of theoretical models. Scaling is a central issue to ensure dynamic similarity between the small-scale experiments and the large-scale volcanic phenomena when natural conditions cannot be simulated due to inherent length scale difference and/or technical limitations. In this respect, dimensionless numbers are used to map physical regimes and to define scaling laws, which allow experimental results to be extrapolated to natural scale. This review presents the variety of experimental studies conducted to investigate subterraneous and aerial volcanic phenomena involving in particular fluid-particle mixtures. We focus on the major scaling issues and the physical regimes investigated, and we also highlight in a historical perspective some of the major advances achieved through experimental studies. Finally we conclude on some perspectives for future works.

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“…. (9) This formula calculates the probability that X equals a given value of k. λ is the mean of the distribution. If X represents the number of volcanic eruptions we have Pr(X ≥1) = 1 -Pr(x = 0).…”

Section: Prediction By Poisson Statisticsmentioning

confidence: 99%

“…1.2 Historical: Like Earthquakes, Tsunamis, Tides and Clouds, Volcanoes are theresults of a type of physical processes that take place inside the Earth. Janine L. Kavanagh, et.al [9], Lady Gryphon [11] and Paul W. Taylor [13] have given a good deal of information regarding the ancient belief and history of volcanoes. The Maoris used to worship Ruaumoko (Fig.1) the God of volcanoes and earthquakes in order to get themselves protected from the fury of earthquakes and volcanoes.…”

Section: Introductionmentioning

confidence: 99%

VOLCANOES, an Excellent Indicator of Heat within the Earth

Nair¹

2018

International Advanced Research Journal in Science, Engineering

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The paper is dedicated to Ruaumoko the Maori God of Volcanoes. To start with, a historical account of some ancient legends regarding volcanoes is given. There is a description of eruption of a volcano with special reference to the eruption of Mount Vesuvius. Formation of magma in the Earth In the review of literature, some research papers of few eminent authors pertaining to volcanic eruption precursors, magma chambers intrusion of magma, magma wagging, velocity of eruption and quantity of eruption are considered.

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A review of laboratory and numerical modelling in volcanology

Cited by 58 publications

References 279 publications

Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

Structural and Geochemical Interactions Between Magma and Sedimentary Host Rock: The Hovedøya Case, Oslo Rift, Norway

The contribution of experimental volcanology to the study of the physics of eruptive processes, and related scaling issues: A review

VOLCANOES, an Excellent Indicator of Heat within the Earth

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