Contact angles: history of over 200 years of open questions

Drelich, Jaroslaw; Бойнович, Л. Б.; Chibowski, Emil; Volpe, C. Della; Hołysz, Lucyna; Marmur, Abraham; Siboni, S.

doi:10.1680/jsuin.19.00007

Cited by 188 publications

(118 citation statements)

References 141 publications

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“…The bubble captive contact angle of 20° at a fresh barite surface is smaller than the reported sessile drop value of 38° [39]. The contact angle deviations may be due to the differences in experimental methods and conditions [40].…”

Section: Contact Angle Of Barite With Lauryl Phosphatementioning

confidence: 79%

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Lauryl Phosphate Flotation Chemistry in Barite Flotation

et al. 2020

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Barite has numerous applications including barium mud for oil well drilling, manufacture of elemental barium, filler for paper and rubber industries, and contrast material for X-ray radiology for the digestive system. Currently, froth flotation is the main method for the beneficiation of barite using fatty acid as a typical collector. In this research, it was found that lauryl phosphate is also a promising collector for barite flotation. Results from microflotation, contact angle, and zeta potential indicate that lauryl phosphate is adsorbed on the barite surface and thus achieves superior flotation efficiency at a wide pH range. The interfacial water structure and wetting characteristics of barite surface with/without lauryl phosphate adsorption were also evaluated by molecular dynamics simulations (MDS). The results from molecular dynamics simulations and interaction energy calculations are in accord with the experimental results, which suggest that lauryl phosphate might be a potential collector for the flotation of barite.

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Section: Contact Angle Of Barite With Lauryl Phosphatementioning

confidence: 79%

“…In this regard, the contact angles at the barite surface with lauryl phosphate, as a function of pH and concentration, are presented in . The contact angle deviations may be due to the differences in experimental methods and conditions [40].…”

Section: Contact Angle Of Barite With Lauryl Phosphatementioning

confidence: 99%

Lauryl Phosphate Flotation Chemistry in Barite Flotation

et al. 2020

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“…One of the first attempts for integrating the hydrophobic effect in ice releasing coatings are documented in the early 00s of the 21st century as spontaneous desire to interrelate the collected at that time scientific knowledge for the fundamentals of non-wettable plants with the chance to avert the adherence of ice on solid surfaces [99][100][101]. Considering concisely the wetting theory of Cassie-Baxter, described comprehensively elsewhere [102,103], the physical micro-nano-roughening of a given hydrophobic surface yields a solid-liquid interface at which the water droplet no longer retains complete contact with the solid at all interfacial points. In this extreme case, the inability of the liquid to penetrate the spacing among surface features leads to an apparent contact angle determined with the following equation: Accordingly, the icing of a single droplet is accompanied by the generation of a latent heat flux that warms the surface and the adjacent liquid droplets begin to evaporate instantly [98].…”

Section: Modus Operandi Of Superhydrophobic Coatings For Passive Icinmentioning

confidence: 99%

From Extremely Water-Repellent Coatings to Passive Icing Protection—Principles, Limitations and Innovative Application Aspects

Esmeryan¹

2020

Coatings

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The severe environmental conditions in winter seasons and/or cold climate regions cause many inconveniences in our routine daily-life, related to blocked road infrastructure, interrupted overhead telecommunication, internet and high-voltage power lines or cancelled flights due to excessive ice and snow accumulation. With the tremendous and nature-inspired development of physical, chemical and engineering sciences in the last few decades, novel strategies for passively combating the atmospheric and condensation icing have been put forward. The primary objective of this review is to reveal comprehensively the major physical mechanisms regulating the ice accretion on solid surfaces and summarize the most important scientific breakthroughs in the field of functional icephobic coatings. Following this framework, the present article introduces the most relevant concepts used to understand the incipiency of ice nuclei at solid surfaces and the pathways of water freezing, considers the criteria that a given material has to meet in order to be labelled as icephobic and clarifies the modus operandi of superhydrophobic (extremely water-repellent) coatings for passive icing protection. Finally, the limitations of existing superhydrophobic/icephobic materials, various possibilities for their unconventional practical applicability in cryobiology and some novel hybrid anti-icing systems are discussed in detail.

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“…The two individual surface tension components determined were then extrapolated to the polymers' respective processing temperatures (185 C for PLA and PP and 250 C for PA6) with Equation 3and with the summation of the components leading to the total surface tension values. 22,23 γ…”

Section: Composites Characterizationcontact Angle Measurementsmentioning

confidence: 99%

Impact of renewable carbon on the properties of composites made by using three types of polymers having different polarity

Rodriguez‐Uribe

Snowdon

Abdelwahab

et al. 2020

J of Applied Polymer Sci

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Pine wood derived biocarbon (BioC) is investigated as a renewable alternative to carbon black (CB) for plastics and composites applications. Three different polymers with different polarity were used to prepare the composites: polypropylene (PP), polylactic acid (PLA), and polyamide 6 (PA6). Comparatively, CB had a nodule size of $300 nm and surface area of 8 m 2 /g, whereas BioC showed an average particle size of $950 nm and surface area of $260 m 2 /g, respectively. CB, in the composites, was found in large aggregations in the flow direction (FD), while BioC particles showed a better dispersion. Aggregation of CB affected mostly the mechanical strength of the composites. Furthermore, it was found that the overall performance of composites was influenced more by the polarity of the phases, rather than the particle size or the surface area of the fillers. Even when the polarity of the particles had an expected trend (PA6 > PLA > PP with BioC > CB), the work of cohesion obtained for the composites was PA6-BioC > PP-BioC > PLA-BioC, showing, in particular, that the chain-to-chain intermolecular forces in neat PLA are stronger as compared to those developed by the particle-matrix interactions.

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Contact angles: history of over 200 years of open questions

Cited by 188 publications

References 141 publications

Lauryl Phosphate Flotation Chemistry in Barite Flotation

Lauryl Phosphate Flotation Chemistry in Barite Flotation

From Extremely Water-Repellent Coatings to Passive Icing Protection—Principles, Limitations and Innovative Application Aspects

Impact of renewable carbon on the properties of composites made by using three types of polymers having different polarity

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