Effects of chaotic advection on the timescales of cooling and crystallization of magma bodies at mid crustal levels

Petrelli, Maurizio; Omari, Kamal El; Guer, Yves Le; Perugini, Diego

doi:10.1002/2015gc006109

Cited by 20 publications

(12 citation statements)

References 81 publications

(173 reference statements)

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“…8a . It consists of a two-dimensional (2D) rectangular domain initially filled with a magma at the liquidus temperature 27 (Fig. 8a ).…”

Section: Methodsmentioning

confidence: 99%

“…In the numerical model, this viscosity formulation was regularized using the Papanastasiou’s method. A source-based enthalpy method 66 was used to model the liquid–solid phase change (i.e., the crystallization) 27 by ensuring that the relationship between temperature and the liquid fraction f showed in Supplementary Fig. 3 and discussed in the section entitled “Parametrization and validation of the thermal model” was satisfied.…”

Section: Methodsmentioning

confidence: 99%

“…For comparison, an open system consisting of progressive refilling by new parental magma is also modeled. Finally, we studied the effect of the development of convective motions within the system, accounting for the non-Newtonian rheology of the magma during the crystallization 27 and considering Rayleigh numbers (Ra) up to 10 9 . The numerical simulations started at the liquidus temperature (i.e., no crystals are present within the system) and continued until the attainment of a rheological behavior close to the jamming conditions 28 , i.e., when the melt extraction from the magmatic mush becomes most probable 29 .…”

Section: Introductionmentioning

confidence: 99%

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Timescales of water accumulation in magmas and implications for short warning times of explosive eruptions

Petrelli

Omari²,

Spina

et al. 2018

Nat Commun

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Water plays a key role in magma genesis, differentiation, ascent and, finally, eruption. Despite the recognized crucial function of water, there are still several issues that continue to blur our view about its role in magmatic systems. What are the timescales of H2O accumulation in crystallizing magmas? What are the ascent rates of water-rich residual melts leading to explosive eruptions? Here, we track the timescale of water accumulation in a residual melt resulting from crystallization of a hydrous CO2-bearing magmatic mass stored at mid- to deep-crustal levels in a subduction-related geodynamic setting. Our results indicate that, after a repose period ranging from few to several thousand years, water-rich melts with water concentrations larger than 6–9 wt.% can migrate towards the Earth surface in very short timescales, on the order of days or even hours, possibly triggering explosive eruptions with short warning times and devoid of long-term geophysical precursors.

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“…8a . It consists of a two-dimensional (2D) rectangular domain initially filled with a magma at the liquidus temperature 27 (Fig. 8a ).…”

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Timescales of water accumulation in magmas and implications for short warning times of explosive eruptions

Petrelli

Omari²,

Spina

et al. 2018

Nat Commun

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“…See the supporting information for methods and values used to plot data fields. Calculation details in supporting information [Androvandi et al, 2011;Caricchi et al, 2008Caricchi et al, , 2014Castruccio et al, 2010;Champallier et al, 2008;Cimarelli et al, 2011;Coetzee and Els, 2009;Dufek and Bergantz, 2005;Forien et al, 2011Forien et al, , 2015Girard and Stix, 2009;Grossmann and Lohse, 2001;Jellinek and DePaolo, 2003;Le Mével et al, 2016;Okumura et al, 2016Okumura et al, , 2015Parks et al, 2012;Petrelli et al, 2016;Pistone et al, 2012Pistone et al, , 2015Rutherford, 2008;Walker et al, 1999].…”

Section: 1002/2017jb014218mentioning

confidence: 99%

On the kinematics and dynamics of crystal‐rich systems

2017

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Partially molten rocks, often called a mush, are examples of a hydrogranular mixture where the dynamics are controlled by both fluid and crystal‐crystal interactions. An obstacle to progress in understanding high‐temperature hydrogranular systems has been the lack of adequate levels of description of microphysical processes. Here we rationalize the hydrogranular kinematic and dynamic states by applying the concept of particle (crystal) force chains. We exemplify this with discrete‐element computational fluid dynamic simulations of the intrusion of a basaltic melt into an olivine‐basalt mush, where crystal‐scale force chains, crystal transport, and melt mixing are resolved. To describe the microscale kinematics of the system, we introduce the coordination number and the fabric tensors of particle contacts and forces. We quantify the changing contact and force fabric anisotropy, coaxiality, and the connectedness of the mush, under dynamic conditions. To describe the dynamics, particle and fluid characteristic response times are derived. These are used to define local and bulk Stokes numbers, and viscous and inertia numbers, which quantify the multiphase coupling under crystal‐rich conditions. We employ the Sommerfeld number, which describes the importance of crystal‐melt lubrication, with a viscous number to illustrate the dynamic regimes of crystal‐rich magmas. We show that the notion of mechanical “lock up” is not uniquely identified with a particular crystal volume fraction and that distinct mechanical behaviors can emerge simultaneously within a crystal‐rich system. We also posit that this framework describes magmatic fabrics and processes which “unlock” a crystal mush prior to eruption or mixing.

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“…The detailed process of enclave formation is highly dynamic as it involves thermal exchange, crystallization, possible gas exsolution, and possible mechanical mixing between the melts and/or the host and inclusion minerals (e.g., Coombs et al, 2000;De Campos et al, 2004;Laumonier et al, 2014;Petrelli et al, 2016;Wiesmaier et al, 2015). Even when leaving aside the roles of volatiles and crystallization, the rheology of crystal-bearing magmas is generally complex because of the feedback between melt-crystal entrainment, crystal-crystal friction and collision, and intermittent lock-up of 5 crystals in contact with each other (e.g., Bergantz et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Numerical simulations of magmatic enclave deformation

Burgisser

Carrara

Annen

2020

Journal of Volcanology and Geothermal Research

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Present in both plutonic and volcanic rocks, enclaves are inclusions of magma into a compositionally distinct magmatic host. Classical links between their shapes and the dynamical conditions that prevailed during their formation have been drawn from fluid-fluid analogies and from solid rock mechanics. Magmas, however, are hydrogranular suspensions with a rheology distinct from these two-end-members. This work presents results from computational fluid dynamics with discrete element modeling (CFD-DEM) aimed at deforming crystal-rich enclaves in pure shear. The CFD-DEM approach explicitly resolves solid-solid interactions such as contact and friction while taking into account fluid coupling. The first series of deformation involved only pure fluids to validate the setup. The second series comprised seven runs aimed at reproducing magmatic conditions. Enclaves were made of a cylindrical suspension of particles embedded into a host with different characteristics. In both media, particles and fluids had densities, viscosities, elastic characteristics, and sizes tailored to the geological constraints of the Adamello batholith, Italy. Each run corresponds to a temperature along the two respective crystallization paths and span crystal contents from 10 to 62 vol.%. Results show that, to first order, deformation does not depend on differences in melt viscosities, crystal contents, or bulk viscosity contrast. This is due to the formation of force chains parallel to the main compression direction, which transmits stress across the enclave. A simple, first-order relationship could be fitted to our data to relate shear and enclave deformation, which we applied to the case of the Adamello pluton. There is a second-order dependence of deformation on the onset of particles contacts and force chains, which are both related to particle concentration. The main control of these second-order effects lies in the host crystal content. Enclave particles pack early, quickly erasing differences in initial content and building force chains parallel to the compression axis that transmit stresses to the host. Whether the host is able to transmit those stresses across its own volume is controlled by host crystal content.

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Effects of chaotic advection on the timescales of cooling and crystallization of magma bodies at mid crustal levels

Cited by 20 publications

References 81 publications

Timescales of water accumulation in magmas and implications for short warning times of explosive eruptions

Timescales of water accumulation in magmas and implications for short warning times of explosive eruptions

On the kinematics and dynamics of crystal‐rich systems

Numerical simulations of magmatic enclave deformation

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