Formation and Dissolution of Surface Metal Carbonate Complexes: Implications for Interfacial Carbon Mineralization in Metal Silicates

Zare, Siavash; Funk, Andreas; Qomi, Mohammad Javad Abdolhosseini

doi:10.1021/acs.jpcc.2c02981

Cited by 9 publications

(5 citation statements)

References 83 publications

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“…Such surface complexations can lead to proton-or ligand-promoted dissolution. [117][118][119][120][121][122]…”

Section: Molecular Insights Into the Surface Stability Of Diopsidementioning

confidence: 99%

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

Aguila,

Hardee,

Schaef

et al. 2023

Environ. Sci.: Nano

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“…Such surface complexations can lead to proton-or ligand-promoted dissolution. [117][118][119][120][121][122]…”

Section: Molecular Insights Into the Surface Stability Of Diopsidementioning

confidence: 99%

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

Aguila,

Hardee,

Schaef

et al. 2023

Environ. Sci.: Nano

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“…The Microprocess of Wet scCO 2 Mineralization. The adsorption−complexation process is widely accepted for the microprocess of wet scCO 2 mineralization, 50 as shown in Figure 5. In this process, the water dissolved in scCO 2 forms a thin water film of only a few nanometers thick on the mineral surface (a).…”

Section: Mineralization Microprocessmentioning

confidence: 99%

Section: Mineralization Microprocessmentioning

confidence: 99%

The Future of CO₂ Geological Sequestration: An Overview of Mineralization in Aqueous and Supercritical States

Wu,

Qu,

Gao

et al. 2024

Energy Fuels

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CO 2 mineralization is a safe and stable geological sequestration method that plays an important role in reducing and mitigating global carbon emission. Currently, the Carbfix project in Iceland and the Wallula project in the United States represent two different mineralization sequestration modes of CO 2 aqueous solution and wet supercritical CO 2 . In the microscopic process, the main difference between the two is that the CO 2 aqueous solution follows the dissolution−precipitation theory, and wet scCO 2 follows the adsorption−complexation process. We verified the changes of the components before and after mineralization as well as the evolution of the morphology and structure through different characterization methods and established three mineralization models. Furthermore, starting from the chemical reaction mechanism of the two methods, we modified the crystallization kinetics Avrami equation, and obtained the theoretical law of the mineralization rate under different conditions. Eventually, the effects of temperature, pressure, ore size and type, additives and water content on the mineralization efficiency were further explored. This paper discusses the various challenges to mineralization sequestration and its potential opportunities, especially in the field of biomineralization. These results are important for understanding the mechanism of CO 2 mineralization under geological conditions and proposing a potential strategy for the enhancement of sequestration efficiency.

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“…Extending the notion of bond order parameters in modeling covalent systems, [24] reactive force fields, such as ReaxFF [25] and AIREBO, [26] provide a classical compromise with DFT-level accuracy and accelerate calculations by orders of magnitude. Properly parameterized ReaxFF potentials can simulate chemical reactions at the solid, liquid, and gas interfaces and these potentials have already advanced our understanding of a range of complex geochemical reactions from interfacial carbon mineralization [27][28][29] to the maturation of organic matter. [30,31] Previously, we developed an H/C/O/Cl ReaxFF potential [32] to model the oxidation of organic matter with oxychlorine reagents, which remain limited to very low pH due to the absence of alkaline or earth alkaline cations in the parameter set to balance the charged reactive fluid.…”

Section: Introductionmentioning

confidence: 99%

A ReaxFF Potential for Modeling Organic Matter Degradation with Oxybromine Oxidants

Hur,

Abousleiman,

Hull

et al. 2024

ChemPhysChem

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Oxidation of organic matter with oxybromine oxidants is ushering in a new era of enhanced hydrocarbon recovery. While these potent reagents are being tested in laboratory and field experiments, there is a pressing demand to delineate the molecular processes governing oxidation reactions at geological depth. Here, we parameterize a ReaxFF potential to model the oxidative decompositions of aliphatic and aromatic hydrocarbons in the presence of water‐NaBr solutions that contain oxybromine (BrOn)‐ oxidizers. Our parameterization results in a reliable empirical bond‐order potential that accurately calculates bond energies, exhibiting an RMSE of ~1.18 eV, corresponding to 1.36 % average error. Reproducing bond dissociation and binding energies from Density Functional Theory (DFT), our parameterization proves transferable to aqueous environments. This H/C/O/Na/Br ReaxFF potential accurately reproduces the oxidation pathways of small hydrocarbons with oxybromine oxidizers. This force field captures proton and oxygen transfer, C‐C bond tautomerization, and cleavage, leading to ring‐opening and chain fragmentation. Molecular dynamic simulations demonstrate the oxidative degradation of aromatic and aliphatic kerogen‐like moieties in bulk solutions. We envision that such reactive force fields will be useful to understand better the oxidation reactions of organic matter formed in geological reservoirs for enhanced shale gas recovery and improved carbon dioxide treatments.

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Formation and Dissolution of Surface Metal Carbonate Complexes: Implications for Interfacial Carbon Mineralization in Metal Silicates

Cited by 9 publications

References 83 publications

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

The Future of CO₂ Geological Sequestration: An Overview of Mineralization in Aqueous and Supercritical States

A ReaxFF Potential for Modeling Organic Matter Degradation with Oxybromine Oxidants

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Formation and Dissolution of Surface Metal Carbonate Complexes: Implications for Interfacial Carbon Mineralization in Metal Silicates

Cited by 9 publications

References 83 publications

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

Emerging investigator series: kinetics of diopside reactivity for carbon mineralization in mafic–ultramafic rocks

The Future of CO2 Geological Sequestration: An Overview of Mineralization in Aqueous and Supercritical States

A ReaxFF Potential for Modeling Organic Matter Degradation with Oxybromine Oxidants

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The Future of CO₂ Geological Sequestration: An Overview of Mineralization in Aqueous and Supercritical States