Water on hydroxylated silica surfaces: Work of adhesion, interfacial entropy, and droplet wetting

Bistafa, Carlos; Surblys, Donatas; Kusudo, Hiroki; Yamaguchi, Yasutaka

doi:10.1063/5.0056718

Cited by 29 publications

(29 citation statements)

References 70 publications

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“…Furthermore, we evaluated the apparent contact angle of the nanobubbles θ app and that of the nanodroplet θ droplet by least-squares circular fitting to a contour of the gas–liquid interface away from the wall. 30,33–35 Masuduzzaman and Kim reported the importance of the definition of the solid–liquid boundary position for the evaluation of the apparent contact angle. 41 In this study, the solid–liquid interface was defined as the position where the fluid density becomes zero which gives a consistent mechanical balance near the three-phase contact lines.…”

Section: Resultsmentioning

confidence: 99%

“…2. Specifically, the liquid–gas and solid–gas interfacial tensions were calculated based on Bakker's equation, 30–37 which describes the relationships between the fluid stress anisotropy and interfacial tensions. The solid–liquid interfacial tension was quantified by the thermodynamic integration (TI) method that calculates the minimum work needed to separate the liquid from the solid surface per area, which corresponds to the interfacial free energy.…”

Section: Resultsmentioning

confidence: 99%

“…The solid–liquid interfacial tension was quantified by the thermodynamic integration (TI) method that calculates the minimum work needed to separate the liquid from the solid surface per area, which corresponds to the interfacial free energy. 30,34,35,43 These types of calculation methods of interfacial tensions are called the “mechanical route” 32 and “thermodynamic route”, 30,34,35,43 respectively. The details of the methods used for the calculation of interfacial tensions are described in the Methods section.…”

Section: Resultsmentioning

confidence: 99%

“…This is an implementation of the TI method for the calculation of the solid–liquid interfacial free energy. 34,43…”

Section: Methodsmentioning

confidence: 99%

“…In this study, by integrating well-proven mechanical and thermodynamic insights 30–37 into MD simulations, we quantified the liquid–gas, solid–gas, and solid–liquid interfacial tensions of nitrogen surface nanobubbles at graphite/water interfaces. The resulting contact angles evaluated by substituting these three interfacial tensions into Young's equation agreed well with those measured from the apparent shapes of the surface nanobubbles.…”

Section: Introductionmentioning

confidence: 99%

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Quantifying interfacial tensions of surface nanobubbles: How far can Young's equation explain?

et al. 2022

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

“…This is an implementation of the TI method for the calculation of the solid–liquid interfacial free energy. 34,43…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantifying interfacial tensions of surface nanobubbles: How far can Young's equation explain?

et al. 2022

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Wettability of Graffiti Coatings by Green Nanostructured Fluids

Bartman,

Hołysz,

Balicki

et al. 2023

ChemPhysChem

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Green nanostructured fluids (GNFs), specifically water‐in‐oil nanoemulsions (w/o NEs), were investigated as professional “brush on, wipe off” nanodetergents for the effective removal of various challenging graffiti coatings. The efficacy of the advanced nanodetergents in eradicating resilient graffiti coatings was evaluated using various methods to assess the surface properties of forming graffiti coatings. The surface properties of these coatings were examined by assessing their wettability by water, surface free energy, and topography to obtain information on the intermolecular interactions with the nanodetergent during the wetting and graffiti removal process. Our findings revealed significant variations in the coating removal rate and efficacy of green nanostructured fluids, which are stabilized using surfactants derived from saccharides or amino acids. A water‐in‐oil nanoemulsion, stabilized by caprylyl/capryl glucoside, demonstrated exceptional efficiency at cleaning graffiti paints based on alkyd resin and containing various additives such as nitrocellulose or bitumen, from any hard surface within a short time period. However, a w/o NE, stabilized by sodium cocoyl glycinate, also showed effective removal of graffiti paints containing durable bitumen, albeit at a slower rate on. These green nanostructured fluids can be used as specific nanodetergents for the comprehensive removal of various graffiti coatings, but require a specified action time to prevent damage to the original substrate beneath the paint coating.

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Adhesion energy, spreading coefficient and interfacial tension as an efficient tool for assessing biocide performance

Nguyen

Balasubramanian

Richardson

2022

J Surfact & Detergents

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It is estimated that microbiologically influenced corrosion (MIC) contributes to 20%-50% of the total cost of corrosion. Biocides are often used to counter MIC. Normally, the choice of a biocide is based on planktonic kill studies as well as cost of the treatment chemicals. Sessile kill studies have significant advantages over planktonic studies but usually take 8 weeks to complete. Furthermore, both sessile kill and planktonic studies only provide phenomenological results and therefore do not explain the mechanisms. To bridge this gap, we have calculated spreading coefficient and work of adhesion from contact angle measurements as a tool for assessing the performance of a biocide. This novel method provides insights into how biocides interact with a biofilm on a surface and is quicker than sessile kill study. Based on surface energy calculations, we have identified parameters that will aide in the prediction of biofilm removal and prevention. For example, surfactants with a positive spreading coefficient on a substrate and having a stronger affinity for the substrate than the biofilm (i.e., a lower interfacial tension) are effective in biofilm prevention. On the other hand, surfactants with a low interfacial tension with a substrate are effective in biofilm removal. Given the diversity of surfaces to which bacteria attach (carbon steel, near wellbore, membrane, etc.), this rapid technique is a good prediction tool for the effectiveness of a biocide application. This paper will provide an overview of the technique and discuss some examples of surfactants that can be used for biofilm removal and prevention.

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Water on hydroxylated silica surfaces: Work of adhesion, interfacial entropy, and droplet wetting

Cited by 29 publications

References 70 publications

Quantifying interfacial tensions of surface nanobubbles: How far can Young's equation explain?

Quantifying interfacial tensions of surface nanobubbles: How far can Young's equation explain?

Wettability of Graffiti Coatings by Green Nanostructured Fluids

Adhesion energy, spreading coefficient and interfacial tension as an efficient tool for assessing biocide performance

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