Competition Between Crystallization‐Induced Expansion and Creep Compaction During Gypsum Formation, and Implications for Serpentinization

Skarbek, R. M.; Savage, H. M.; Kelemen, P. B.; Yancopoulos, D.

doi:10.1029/2017jb015369

Cited by 19 publications

(21 citation statements)

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“…Completely carbonated (listvenites) and hydrated (serpentinites) peridotites are, however, frequently observed in outcrops, Reaction-driven cracking has been observed in experiments involving both carbonation of olivine (Xing et al, 2018;Zhu et al, 2016) and hydration of magnesium oxide (Zheng et al, 2018). Other experiments on analogue systems have demonstrated that hydration reactions involving lime (Lambart et al, 2018;Wolterbeek et al, 2018) and bassanite (Skarbek et al, 2018) can produce significant crystallization-induced stresses. However, the conditions under which positive feedbacks (cracking) overcome negative feedbacks (clogging) remain relatively uncertain.…”

Section: Introductionmentioning

confidence: 99%

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

2020

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The motion of plates leads to cycling of chemically bound water and volatiles through the Earth's interior, having consequences for arc magmatism and seismic activity at subduction zones. Tectonically exhumed peridotite at the Earth's surface provides a substantial sink for water and carbon. The natural chemical disequilibrium that exists between exposed mantle peridotite and the surface waters/atmosphere could potentially be harnessed as a negative carbon emission technology. Understanding this process is therefore critical from both a petrological and environmental perspective. Retrograde metamorphism is physically complex, potentially involving an interplay between positive (cracking) and negative (clogging) feedbacks that may limit, or promote, fluid supply to unreacted minerals. Modeling studies are important in helping to constrain the conditions that control the extent of reaction in ultramafic rocks. This study builds on a previously reported model that describes olivine hydration/carbonation in a poroelastic medium, coupling fluid flow, elastic deformation, and mass transfer between chemically active phases. Here we extend this model to include brittle failure, which is crucial given the widely held hypothesis that reaction-driven cracking is the dominant positive feedback in these processes. Here we explore the use of phase-field methods to simulate brittle failure in a poroelastic medium, in the context of hydration (serpentinization) of peridotite. We show that reaction-driven cracking in this model can generate a positive feedback that, under certain conditions, can lead to 100% transformation of olivine to serpentine.

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Section: Introductionmentioning

confidence: 99%

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

2020

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“…As mentioned previously, it has been observed that the reaction rate decreases under large stress conditions (Skarbek et al, ; Wolterbeek et al, ; Zheng et al, ). Microstructural observations of Wolterbeek et al () indicated that reaction‐induced stresses shut down pathways for water into the sample, hampering ongoing reaction and limiting the magnitude of stress buildup to the values observed.…”

Section: Discrete Element Methods Model Formulationmentioning

confidence: 61%

“…The modeling of serpentinization proposed in this study provides additional information compared to previous studies (Kelemen & Hirth, 2012;Skarbek et al, 2018). In the present study, serpentinization was…”

Section: Modeling Serpentinization In Natural Conditionsmentioning

confidence: 73%

“…As mentioned previously, it has been observed that the reaction rate decreases under large stress conditions ( 2017) indicated that reaction-induced stresses shut down pathways for water into the sample, hampering ongoing reaction and limiting the magnitude of stress buildup to the values observed. Skarbek et al (2018) suggested that the stress limit could correspond to the strength of the material. During compaction, creep can occur, reducing the rate of reaction-induced fracturing.…”

Section: Modeling the Effect Of Pressure And Temperature During Serpementioning

confidence: 99%

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Modeling Porosity Evolution Throughout Reaction‐Induced Fracturing in Rocks With Implications for Serpentinization

et al. 2019

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Numerical modeling based on the discrete element method was used to explore the kinetics and mechanics of fractures induced by mineral volumetric expansion during rock hydration. Two systems were considered: the hydration of periclase into brucite and the hydration of peridotite into serpentine. We modeled the coupling between mineral transformation, stress, volume increase, and deformation by simulating the volumetric growth of discrete elements based upon an Avrami‐type kinetics equation. The model was implemented to consider the effects of stress and temperature on reaction kinetics as well as the alteration of material properties during hydration reactions. We were able to reproduce experimental evidences observed during the transformation of periclase into brucite, including volume growth, fracturing of periclase, formation of a porosity pulse, as well as the slow‐down effect of effective stress on the kinetics of the transformation. The model was also applied to study the serpentinization process. We estimated a bell‐shaped relationship between temperature and reaction rate of peridotite transformation following observations made during serpentinization experiments. For both periclase and peridotite systems, we characterized a relationship between the formation of a porosity pulse and the rate of fracture development within the medium. During serpentinization, the amplitude of the porosity pulse and the duration of this pulse depend on the reaction rate and, therefore, on the temperature. Our investigations provide geomechanical explanations on how native dihydrogen formed during serpentinization can be expelled and initiates its migration process.

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“…As a result, there is no consensus regarding the nature of deformation due to retrograde metamorphism (e.g., Ghofrani & Plack, 1993;Kuleci et al, 2017;Ostapenko & Yaroshenko, 1975;Skarbek et al, 2018;Van Noort et al, 2017;Wolterbeek et al, 2017;Zhu et al, 2016). Generation of stress due to crystallization has been mostly studied in environments where crystallization occurs within a porous medium whose matrix does not participate in the reaction.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of the Pressure of Crystallization of Ca(OH)₂: Implications for the Reactive Cracking Process

Lambart

Savage

Robinson

et al. 2018

Geochem Geophys Geosyst

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Mineral hydration and carbonation can produce large solid volume increases, deviatoric stress, and fracture, which in turn can maintain or enhance permeability and reactive surface area. Despite the potential importance of this process, our basic physical understanding of the conditions under which a given reaction will drive fracture (if at all) is relatively limited. Our hydration experiments on CaO under uniaxial loads of 0.1 to 27 MPa show that strain and strain rate are proportional to the square root of time and exhibit negative, power law dependence on uniaxial load, suggesting that (1) fluid transport via capillary flow is rate limiting and (2) decreasing strain rate with increasing confining pressure might be a limiting factor in reaction driven cracking at depth. However, our experiments also demonstrate that crystallization pressure due to hydration exceeds 27 MPa (consistent with a maximum crystallization pressure of 153 MPa for the same reaction, Wolterbeek et al., https://doi.org/10.1007/s11440-017-0533-5). As a result, full hydration can be achieved at crustal depths exceeding 1 km, which is relevant for engineered fracture systems.

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Competition Between Crystallization‐Induced Expansion and Creep Compaction During Gypsum Formation, and Implications for Serpentinization

Cited by 19 publications

References 75 publications

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

Modeling Porosity Evolution Throughout Reaction‐Induced Fracturing in Rocks With Implications for Serpentinization

Experimental Investigation of the Pressure of Crystallization of Ca(OH)₂: Implications for the Reactive Cracking Process

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Competition Between Crystallization‐Induced Expansion and Creep Compaction During Gypsum Formation, and Implications for Serpentinization

Cited by 19 publications

References 75 publications

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

Phase‐Field Modeling of Reaction‐Driven Cracking: Determining Conditions for Extensive Olivine Serpentinization

Modeling Porosity Evolution Throughout Reaction‐Induced Fracturing in Rocks With Implications for Serpentinization

Experimental Investigation of the Pressure of Crystallization of Ca(OH)2: Implications for the Reactive Cracking Process

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Experimental Investigation of the Pressure of Crystallization of Ca(OH)₂: Implications for the Reactive Cracking Process