Chemo‐mechanics of cemented granular solids subjected to precipitation and dissolution of mineral species

Buscarnera, Giuseppe; Das, Arghya

doi:10.1002/nag.2486

Cited by 27 publications

(4 citation statements)

References 61 publications

(94 reference statements)

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“…Relatively fewer works addressed porous media such as soils [8] and rocks [e.g. 46,11,47,16,6,29,32,23], mostly focusing on the evolution of the mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

Reactive transport under stress: Permeability evolution in deformable porous media

Roded

Paredes

Holtzman

2018

Earth and Planetary Science Letters

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We study reactive transport in a stressed porous media, where dissolution of the solid matrix causes two simultaneous, competing effects: pore enlargement due to chemical deformation, and pore compaction due to mechanical weakening. We use a novel, mechanistic pore-scale model to simulate flooding of a sample under fixed confining stress. Our simulations show that increasing the stress inhibits the permeability enhancement, increasing the injected volume required to reach a certain permeability, in agreement with recent experiments. We explain this behavior by stress concentration downstream, in the less dissolved (hence stiffer) outlet region. As this region is also less conductive, even its small compaction has a strong bottleneck effect that curbs the permeability.Our results also elucidate that the impact of stress depends on the dissolution regime. Under wormholing conditions (slow injection, i.e. high Damkohler number, Da), the development of a sharp dissolution front and high porosity contrast accentuates the bottleneck effect. This reduces transport heterogeneity, promoting wormhole competition. Once the outlet starts eroding, the extreme focusing of transport and hence dissolution-characteristic of wormholing-becomes dominant, diminishing the bottleneck effect and hence the impact of stress at breakthrough. In contrast, at high flow rates (low Da), incomplete reaction upstream allows some of the reagent to traverse the sample, causing a more uniform dissolution. The continuous dissolution and its partial counteraction by compaction at the outlet provides a steady, gradual increase in the effect of stress. Consequently, the impact of stress is more pronounced at high Da during early stages (low permeability), and at low Da close to breakthrough. Our work promotes understanding of the interplay between dissolution and compaction and its effect on the hydromechanical property evolution, with important implications for processes ranging from diagenesis and weathering of rocks, to well stimulation and carbon geosequetration.This further enhances their conductivity relative to other, less conductive regions, leading eventually to runaway permeability increase [12,4,18,39].In many cases, for instance in the subsurface, the medium is under appreciable stress, such that dissolution ("chemical deformation") also induces mechanical deformation. Chemomechanical deformation and the coupled changes in the transport and mechanical properties is key in many applications, such as enhanced energy recovery and carbon geosequestration [35,26,11,32,44,7]. A large body of literature exists on rough fractures, due to their importance, e.g. dominance of fracture flow, and their quasi two-dimensional (2-D) nature, which simplifies experimental setup and imaging as well as numerical simulations [e.g. 22, 14, 15, 19, 2]. Relatively fewer works addressed porous media such as soils [8] and rocks [e.g. 46, 11, 47, 16, 6, 29, 32, 23], mostly focusing on the evolution of the mechanical properties.The evolution of transport properties i...

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“…Relatively fewer works addressed porous media such as soils [8] and rocks [e.g. 46,11,47,16,6,29,32,23], mostly focusing on the evolution of the mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

Reactive transport under stress: Permeability evolution in deformable porous media

Roded

Paredes

Holtzman

2018

Earth and Planetary Science Letters

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“…In their approach, the mechanical effects of grain crushing and bond degradation are related to the changes of a micromechanically-inspired internal variable derived from the microscale via statistical homogenization. The extension of this approach to incorporate chemical bond and grain degradation has been proposed by Buscarnera and Das (2016).…”

Section: Introductionmentioning

confidence: 99%

A finite deformation multiplicative plasticity model with non–local hardening for bonded geomaterials

Oliynyk

Ciantia

Tamagnini

2021

Computers and Geotechnics

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“…The evolution of the mechanical properties in fault cores is tightly coupled to the other physical phenomena, as changes in grain size will correlate to changed surface area, having an effect on chemical reactions (Buscarnera and Das, 2016;Stefanou and Sulem, 2014;Viswanath and Das, 2019;Zhang and Buscarnera, 2018), will feature heat energy being released due to friction and grain breakage, and are associated with changes in porosity, which will affect the pore water pressure (Rattez, 2018;Rattez, Stefanou and Sulem, 2018;Rattez et al, 2018a,b). As such, being accurately able to characterise this evolution in grain size is a pressing need in order to be able to develop a comprehensive model of fault mechanics.…”

Section: Introductionmentioning

confidence: 99%

A Cosserat Breakage Mechanics model for brittle granular media

Collins-Craft

Stefanou

Sulem

et al. 2020

Journal of the Mechanics and Physics of Solids

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This paper introduces a Breakage Mechanics model formulated in the framework of Cosserat continuum theory. This formulation allows us to account for the interaction of grain size evolution with shear band formation in a physically motivated and thermodynamically consistent way. We provide an upscaling procedure that introduces material parameters accounting for the contribution of the Cosserat rotations, as well as the micro-inertia of the entire grain size distribution. A particular highlight of the new formulation is the capacity to describe an evolving internal Cosserat length that takes account of the complete grain size distribution and its evolution. In addition, we specify a particular model that requires no additional calibration relative to the same model in the classical continuum. We apply this model to the study of a layer sheared under constant volume which simulates the fast undrained deformation observed in seismogenic faults. Through linear stability analysis we use the model to examine the effect of grain size polydispersity on the thickness of shear bands. By implementing the model using the finite element method we provide an explanation for the geological formation of double cataclastic shear bands.

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Chemo‐mechanics of cemented granular solids subjected to precipitation and dissolution of mineral species

Cited by 27 publications

References 61 publications

Reactive transport under stress: Permeability evolution in deformable porous media

Reactive transport under stress: Permeability evolution in deformable porous media

A finite deformation multiplicative plasticity model with non–local hardening for bonded geomaterials

A Cosserat Breakage Mechanics model for brittle granular media

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