Adsorption of Ions at the Interface of Clay Minerals and Aqueous Solutions

Jia, Zengqiang; Wang, Qian; Zhu, Chang; Yang, Gang

doi:10.5772/65529

Cited by 4 publications

(2 citation statements)

References 89 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Interlayers of the naturally occurring clay minerals provide a confined environment to augment chemical reaction rates, increase selectivity of species, and stabilize reactive species. − The clay structural charges and interlayer cations promote a range of physical and chemical processes, including intercalation, swelling, adsorption, and reaction. Experimental ,, and theoretical (ab initio and classical molecular simulations) − studies on the interactions among CO 2 , water, and clay have focused mainly on adsorption, intercalation, and swelling of clay interlayers.…”

mentioning

confidence: 99%

Hydrophobic Nanoconfinement Enhances CO₂ Conversion to H₂CO₃

Dasgupta

Rempe

et al. 2023

J. Phys. Chem. Lett.

View full text Add to dashboard Cite

Understanding the formation of H2CO3 in water from CO2 is important in environmental and industrial processes. Although numerous investigations have studied this reaction, the conversion of CO2 to H2CO3 in nanopores, and how it differs from that in bulk water, has not been understood. We use ReaxFF metadynamics molecular simulations to demonstrate striking differences in the free energy of CO2 conversion to H2CO3 in bulk and nanoconfined aqueous environments. We find that nanoconfinement not only reduces the energy barrier but also reverses the reaction from endothermic in bulk water to exothermic in nanoconfined water. Also, charged intermediates are observed more often under nanoconfinement than in bulk water. Stronger solvation and more favorable proton transfer with increasing nanoconfinement enhance the thermodynamics and kinetics of the reaction. Our results provide a detailed mechanistic understanding of an important step in the carbonation process, which depends intricately on confinement, surface chemistry, and CO2 concentration.

show abstract

mentioning

confidence: 99%

Hydrophobic Nanoconfinement Enhances CO₂ Conversion to H₂CO₃

Dasgupta

Rempe

et al. 2023

J. Phys. Chem. Lett.

View full text Add to dashboard Cite

show abstract

“…These properties define the optimal conditions for a well-dispersed system as well as the coagulation, flotation, and dispersion characteristics in suspension systems. Clay minerals adsorb water molecules and hydrated cations in aqueous solutions, leading to hydration on their external and internal surfaces 53 , 54 .…”

Section: Introductionmentioning

confidence: 99%

Effects of type and distribution of clay minerals on the physico-chemical and geomechanical properties of engineered porous rocks

Iranfar

Karbala

Shakiba

et al. 2023

Sci Rep

View full text Add to dashboard Cite

The study of the properties of engineered rocks is of great importance to researchers in engineering sciences such as petroleum, mining, and civil engineering owing to their wide application in these fields. In the present study, a physico-chemical and geomechanical investigation was carried out on the effects of different clay minerals on porous rocks. Various chemical products formed during chemical interactions between cement, clay minerals, and water can change the pore structure and thus the rock characteristics. The results of the current study showed that increasing the clay content could remarkably reduce the porosity and permeability of the rock by an average of 86% and 6.76%, respectively. In this regard, samples containing kaolinite were further influenced due to their new pore structure. Moreover, a power relationship was found between sonic velocity and porosity, which can be used to predict rock properties. Chemical analysis indicated an amplification in quantities of chemical products, particularly calcium silicate hydrate and portlandite, due to an increase in clay content. The impacts of porosity and cementation quality as two main factors on rock strength have also been studied. The outcomes revealed that a reduction in porosity could compensate for detrimental effects of poor bond quality and consequently improved UCS by up to 30% in samples containing kaolinite, while decreasing the degree of cementation prevailed over the porosity reduction in specimens including illite and resulted in a 14% decrease in UCS. The effects of porosity and bond quality on UCS would cancel each other out in samples containing bentonite. It is worth noting that when it comes to changes in geomechanical characteristics, the dominant factor (i.e., porosity reduction or cementation quality) determines the ultimate effect of clay minerals on the properties of engineered porous rocks.

show abstract