A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

Peng, Bo; Liao, Peng; Jiang, Yi

doi:10.1021/acs.langmuir.4c00274

Cited by 4 publications

(1 citation statement)

References 100 publications

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“…10 DLVO theory has been thoroughly derived to describe the colloidal stability of hard-shell nanoparticles in a variety of electrolyte concentrations, 11,12 surface charge composition, 13,14 solvent environments, 15 and many other scenarios. [15][16][17][18][19][20] For the purposes of this perspective, DLVO theory can be summarized by Eq. 1:…”

Section: Solvation At Non-porous Interfaces 11 Colloidal Stability An...mentioning

confidence: 99%

Solvation of Nanoscale Materials

Mapile,

Svensson Grape,

Brozek

2024

Preprint

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The utility of colloidal nanomaterials in energy storage devices, high-definition displays, and industrial coatings depends on their solution processibility and stability. Traditional theories of solvation and colloidal stability, namely Derjaguin- Landau-Verwey-Overbeek (DLVO) and Flory-Huggins theories, describe classical approaches to solvation and colloidal sta- bility of hard-shell colloids and macromolecules, respectively. In contrast, the solution-state behavior of polymers, proteins, and related macromolecules must be understood in terms of solvent interactions, which become especially important due to the accessible cavities of hydrophobic and hydrophilic moieties in these systems. The colloidal stability of permanently porous materials, such as nanoparticles of metal-organic frameworks (nanoMOFs), on the other hand, challenges conventional notions of colloidal stability due to the presence of both internal and external surfaces, and because their external surfaces are mostly empty space. To develop nanoMOFs and other porous colloids into useful materials, we must understand the solvation of porous interfaces. Here, we discuss classical models of solvation and colloidal stability for non-porous and pseudo-porous (proteins and polymers) materials as a basis to propose that the colloidal stability of porous materials likely involves self- assembled solvation shells and strong solvent interactions with the molecular components of the nanomaterial.

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Section: Solvation At Non-porous Interfaces 11 Colloidal Stability An...mentioning

confidence: 99%

Solvation of Nanoscale Materials

Mapile,

Svensson Grape,

Brozek

2024

Preprint

View full text Add to dashboard Cite

show abstract

Sustainable access to π-conjugated molecular building blocks via phosphine-free, ppm palladium level Suzuki-Miyaura reaction in water

Mattiello,

Ghiglietti,

Fappani

et al. 2024

Catalysis Today

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Solvation of Nanoscale Materials

Mapile,

Svensson Grape,

Brozek

2024

Chem. Mater.

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The utility of colloidal nanomaterials in energy storage devices, high-definition displays, and industrial coatings depends on their solution processability and stability. Traditional theories of solvation and colloidal stability, namely, Derjaguin–Landau–Verwey–Overbeek (DLVO) and Flory–Huggins theories, describe classical approaches to solvation and colloidal stability of hard-shell colloids and macromolecules, respectively. In contrast, the solution-state behavior of polymers, proteins, and related macromolecules must be understood in terms of solvent interactions, which become especially important due to the accessible cavities of hydrophobic and hydrophilic moieties in these systems. The colloidal stability of permanently porous materials, such as nanoparticles of metal–organic frameworks (nanoMOFs), on the other hand, challenges conventional notions of colloidal stability due to the presence of both internal and external surfaces and because their external surfaces are mostly empty space. To develop nanoMOFs and other porous colloids into useful materials, we must understand the solvation of porous interfaces. Here, we discuss classical models of solvation and colloidal stability for nonporous and pseudoporous (proteins and polymers) materials as a basis to propose that the colloidal stability of porous materials likely involves self-assembled solvation shells and strong solvent interactions with the molecular components of the nanomaterial.

show abstract

A Meta-Analysis to Revisit the Property–Aggregation Relationships of Carbon Nanomaterials: Experimental Observations versus Predictions of the DLVO Theory

Cited by 4 publications

References 100 publications

Solvation of Nanoscale Materials

Solvation of Nanoscale Materials

Sustainable access to π-conjugated molecular building blocks via phosphine-free, ppm palladium level Suzuki-Miyaura reaction in water

Solvation of Nanoscale Materials

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