Computational models of melt transport from source to surface

Update: 2016-06-14

Description

Melt transport from partial melt sources in the asthenosphere through the lithosphere and crust involves many complexities. Reactive and rheological instabilities lead to strongly localised flow of melt through a deforming and reacting host rock. The resulting regimes of magmatic activity involve a wide range of time and length scales. Numerical modelling offers promising avenues of quantitative research into these phenomena. Yet, the complex nature of melt transport processes poses challenging computational problems requiring robust and efficient numerical techniques. Here, I will present some recent developments in computational magma dynamics, in terms of physical model description, computational methods, and scientific applications. The latter include melt transport across the flow-to-fracture transition for intraplate magmatism in a continental lithosphere, as well as volatile flux-driven reactive melt transport beneath mid-ocean ridges. These examples illustrate both opportunities and challenges for computational modelling of melt transport from source to surface.

Comments

In Channel

Melt migration at mid-ocean ridges: A tale in three acts

2016-07-1857:16

Discretizations and multigrid solver for problems related to fluid flow

2016-06-1741:13

3D Numerical Modelling of Compressible Coupled Magma/Mantle Dynamics With Adaptive Mesh Refinement

2016-06-1602:22:00

Seismic evidence for melt in the upper mantle

2016-06-1601:04:00

The permeability of deformable and reactive porous media

2016-06-1654:41

Salt fluxes from sea ice: simple models of reactively dissolved channels

2016-06-1648:37

Filtration Flow in Poro-Visco-Elastic Media

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Shear Induced Melt Bands: The Mechanics of their Formation and their Possible Role as Melt Conduits Beneath Mid-Ocean Ridges

2016-06-1601:04:00

The rapid advance and slow retreat of a mushy zone

2016-06-1642:29

Mixed Methods for Two-Phase Darcy-Stokes Mixtures of Partially Melted Materials with Regions of Zero Porosity

2016-06-1401:47:00

An Approach to Large Scale Computing of Problems form Science and Technology

2016-06-1401:18:00

Effect of partial melting on seismic velocity and attenuation: Polycrystal anelasticity at near-solidus temperatures

2016-06-1401:12:00

Melting in the deep mantle

2016-06-1447:02

A four-field mixed finite element method for the Biot model and its solution algorithms

2016-06-1447:56

Preconditioners for models of coupled magma/mantle dynamics

2016-06-1401:32:00

Suckale

2016-06-1448:51

Computational models of melt transport from source to surface

2016-06-1401:10:00

Modelling magma migration through the continental lithosphere: the importance of multiple pulses and channelized flow.

2016-06-1441:37

Melt-induced weakening of the lithosphere: theory, numerical implementation and geodynamic implications

2016-06-1454:01

Seismic imaging of mantle melting processes beneath volcanic arcs and backarc spreading centers

2016-06-1401:07:00

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Computational models of melt transport from source to surface

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Computational models of melt transport from source to surface

Vincenzo Abete

Computational models of melt transport from source to surface