Atomistic computer simulations of water interactions and dissolution of inorganic glasses

Du, Jincheng; Rimsza, Jessica

doi:10.1038/s41529-017-0017-y

Cited by 57 publications

(63 citation statements)

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“…As a result, direct correlation to experimental reaction rates cannot be reliably extracted due to size and timescale limitations. In order to make direct comparison with experimental results of dissolution rates, combining MD simulations to generate glass structure with Monte Carlo simulations that extend to longer time scales might be necessary as we recently reported . The results could however be analyzed to examine the structural and compositional changes at the interface and their correlation to the overall reaction rates.…”

Section: Discussionmentioning

confidence: 99%

“…use of a reactive potential is critical for analyzing all the reactions and material transport inside the glass and solution. Recent improvements of reactive MD force fields have allowed for several advances in the modeling of silica‐water interactions . In one of the most recent studies of sodium silicate hydration with the ReaxFF, leaching of sodium into water and accumulation at the interface of the leached Na + ions was observed along with proton transport inside the glass in the first nanosecond of reaction.…”

Section: Introductionmentioning

confidence: 99%

“…Recent improvements of reactive MD force fields have allowed for several advances in the modeling of silica-water interactions. [33][34][35][36][37][38] In one of the most recent studies of sodium silicate hydration with the ReaxFF, 39 leaching of sodium into water and accumulation at the interface of the leached Na + ions was observed along with proton transport inside the glass in the first nanosecond of reaction. Another recent study with the same ReaxFF potential studied the continuation of these simulations for a longer time (3 ns) and for different temperatures.…”

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confidence: 99%

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Hydration and reaction mechanisms on sodium silicate glass surfaces from molecular dynamics simulations with reactive force fields

Mahadevan

2020

J Am Ceram Soc

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Recent development of reactive force fields have enabled molecular dynamics simulations of interactions between silicate glasses and water at the atomistic scale. While multicomponent silicate glasses encompass a wide variety of compositions and properties, one common structural feature in these glasses is the combination of the network structure that is made up of silica tetrahedra linked through corner sharing interspersed with network modifiers like alkali and alkaline‐earth ions that break up the Si–O–Si linkages by forming nonbridging oxygen. In reactions with water, ion exchange between alkali ions in the glass and proton or hydronium in the solution, as well as hydrolysis reaction of the Si–O–Si linkages and subsequent silanol formation, is observed and well documented. We have used a set of recently developed reactive force field to investigate the reactions between water and the surfaces of silica and sodium silicate glasses of different compositions for reactions up to 8 nanoseconds. Our results indicate sodium leaching into water and diffusion of water molecules up to 25 Å into the glass surface. We examined the structural and compositional changes inside the glass and around the diffused ions and use these to explain the rates of silanol formation at the surface. We also observed proton transport in the glass which has an indirect influence on the silanol formation rates. While the surface of the glass was rough to start with, it undergoes further modification into a hydrated gel‐like structure in the glass for up to 5 Å in the higher alkali containing glasses. It was found that the leached sodium ions remain close to the interface and that fragments of silicate network from the surface is capable of dislodging from the bulk glass and enter the aqueous solution. These simulations thus provide insights into the formation and structure of an alteration layers commonly observed in multicomponent silicate glasses corroded in aqueous solutions.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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Hydration and reaction mechanisms on sodium silicate glass surfaces from molecular dynamics simulations with reactive force fields

Mahadevan

2020

J Am Ceram Soc

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“…The multiscale nature of corrosion, where atomistic surface processes (which are difficult or impossible to identify by lab experiments) end up in macroscopic dissolution (which is accurately measurable), requires modeling and crossvalidation on all length scales, in which atomic level models 207 typically inform the meso and macroscopic scales. Commonalities in modeling of the different materials exist, especially on the most fundamental quantum mechanical and the most macroscopic rate theory scales, with opportunities for cross-fertilization, particularly at the intermediate mesoscale.…”

Section: Silicate Glass Crystalline Ceramic and Metal Corrosion: Simentioning

confidence: 99%

“…The expected development of more accurate potentials will open up the possibility to study reaction, diffusion, defect formation, and migration at the extended atomic scale for more materials. 207 Modeling at the intermediate length and times scale is most prominently represented by stochastic models based on cellular automata and Monte Carlo modeling, 222,223 which are especially appropriate to model pitting corrosion, 222 and gel layer microstructure evolution during glass corrosion, 224 but have been explored to a much lesser degree for ceramic corrosion.…”

Section: Silicate Glass Crystalline Ceramic and Metal Corrosion: Simentioning

confidence: 99%

A comparative review of the aqueous corrosion of glasses, crystalline ceramics, and metals

et al. 2018

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All materials can suffer from environmental degradation; the rate and extent of degradation depend on the details of the material composition and structure as well as the environment. The corrosion of silicate glasses, crystalline ceramics, and metals, particularly as related to nuclear waste forms, has received a lot of attention. The corrosion phenomena and mechanisms of these materials are different, but also have many similarities. This review compares and contrasts the mechanisms of environmental degradation of glass, crystalline ceramics, and metals, with the goal of identifying commonalities that can seed synergistic activities and advance the current knowledge in each area.npj Materials Degradation (2018) 2:15 ; doi:10.1038/s41529-018-0037-2 INTRODUCTIONNew research activity focused on the environmental degradation of silicate glasses, crystalline ceramics, and metals relevant to nuclear waste forms and containers has recently been described.

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Borosilicate and Boroaluminosilicate Glasses

Deng

2022

Atomistic Simulations of Glasses

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Atomistic computer simulations of water interactions and dissolution of inorganic glasses

Cited by 57 publications

References 100 publications

Hydration and reaction mechanisms on sodium silicate glass surfaces from molecular dynamics simulations with reactive force fields

Hydration and reaction mechanisms on sodium silicate glass surfaces from molecular dynamics simulations with reactive force fields

A comparative review of the aqueous corrosion of glasses, crystalline ceramics, and metals

Borosilicate and Boroaluminosilicate Glasses

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