Biphilic Surfaces with Optimum Hydrophobic Islands on a Superhydrophobic Background for Dropwise Flow Condensation

Chehrghani, Mirvahid Mohammadpour; Abbasiasl, Taher; Sadaghiani, Abdolali Khalili; Koşar, Ali

doi:10.1021/acs.langmuir.1c01844

Cited by 12 publications

(8 citation statements)

References 65 publications

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“…Employing the spraying method for fabrication has made the manufacturing process of these surfaces cost-effective. In addition, in most of the studies in the literature, the best performance of the engineered surfaces was at relatively low subcooling temperatures. ,,− However, the fabricated coating in this study showed its best ability at a subcooling temperature of 25.5 °C; therefore, this coating is applicable where a high subcooling temperature is required. Furthermore, the performance of the proposed surfaces in the industry has been investigated experimentally through various tests.…”

Section: Introductionmentioning

confidence: 69%

Enhancement of Dropwise Condensation Heat Transfer through a Sprayable Superhydrophobic Coating

et al. 2023

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Improving the shedding rate of condensed droplets has many applications in industries and daily problems, including increasing heat transfer and self-cleaning properties. One way to achieve this goal is by enhancement of the wetting properties of surfaces. In this research, the hierarchical superhydrophobic coating over aluminum has been applied using a relatively cost-effective method, spraying, which is also applicable to any metal surface used as a condenser. According to the results obtained from the experimental tests, the fabricated surface is highly superhydrophobic, with a contact angle of 158° and contact angle hysteresis of less than 5°. The results show that the presented surface increases the heat transfer coefficient by 20.6% at the subcooling temperature of 25.5 °C when the surface temperature and relative humidity are 70 °C and 98%, respectively. In addition, this coated surface showed great potential at lower surface temperatures by increasing the water condensation rate as much as 50.5% at the subcooling temperature of 12 °C, when the surface temperature and relative humidity are 11.25 °C and 70%, respectively. Therefore, it is found that for the fabricated superhydrophobic paint in the present study, the effectiveness of the dropwise condensation mode profoundly depends on surface temperatures besides subcooling temperatures. In other words, a surface with lower temperatures shows better performance for the same subcooling temperatures. In addition, various types of durability tests are carried out. The results reveal that this coating has good durability against high surface temperatures, submerged conditions for 30 days, imposing hot steam for 150 h, corrosion, and organic solvents. Hence, it is suitable for industrial applications.

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Section: Introductionmentioning

confidence: 69%

Enhancement of Dropwise Condensation Heat Transfer through a Sprayable Superhydrophobic Coating

et al. 2023

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“…Recent works also demonstrated various strategies to fabricate scalable biphilic surfaces. 41,42 Artificial nucleation cavities have also been incorporated to enhance HTC in flow boiling where boiling occurs inside micro and mini channels. 43 Recently, anti-icing surfaces utilizing controlled nucleation of ice on sacrificial structures have been developed.…”

Section: Engineered Nucleation Sitesmentioning

confidence: 99%

“…Hoque et al 40 showed that proper design of the biphilic surface can significantly enhance the condensation heat transfer performance. Recent works also demonstrated various strategies to fabricate scalable biphilic surfaces 41,42 . Artificial nucleation cavities have also been incorporated to enhance HTC in flow boiling where boiling occurs inside micro and mini channels 43 .…”

Section: Static Surface Structures and Chemistrymentioning

confidence: 99%

Manipulation of droplets and bubbles for thermal applications

Liang

Kumar

Ahmadi

et al. 2022

Droplet

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Liquid–vapor phase change including evaporation, boiling, and condensation is a ubiquitous process found in power generation, desalination, thermal management, building heating and cooling, and additive manufacturing. The dynamics of droplets and bubbles during phase change including nucleation, growth, and departure critically influence the thermal transport performance and system efficiency. This review will highlight recent advancements using static and dynamic strategies to manipulate droplets and bubbles for phase change applications and beyond.

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“…[23][24][25][26][27][28][29][30][31][32][33] However, these biphilic surfaces often involve complex geometries requiring precisely geometries design, multiple fabrication steps, and sophisticated equipment that make scaling up difficult and expensive. [34][35][36][37] Herein, instead of relying on structural manipulation, the water-repellent coatings of the superhydrophobic surfaces were tailored in this study to attain rapid droplet nucleation while retaining sufficient repellency to maintain jumping droplet departure. Inspired by the reports that soft, deformable surfaces promote water nucleation, [38,39] branched siloxanes (Siloxane2) with hydrophilic and hydrophobic molecular segments were prepared.…”

Section: Introductionmentioning

confidence: 99%

Hierarchically Branched Siloxane Brushes for Efficient Harvesting of Atmospheric Water

Song

Liu

et al. 2023

Small

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Atmospheric water harvesting is considered a viable source of freshwater to alleviate water scarcity in an arid climate. Water condensation tends to be more efficient on superhydrophobic surfaces as the spontaneous coalescence‐induced droplet jumping on superhydrophobic surfaces enables faster condensate removal. However, poor water nucleation on these surfaces leads to meager water harvest. A conventional approach to the problem is to fabricate micro‐ and nanoscale biphilic structures. Nonetheless, the process is complex, expensive, and difficult to scale. Here, the authors present an inexpensive and scalable method based on manipulating the water‐repellent coatings of superhydrophobic surfaces. Flexible siloxane can facilitate water nucleation, while a branched structure promotes efficient droplet jumping. Moreover, ToF‐SIMS analysis indicated that branched siloxane provides a better water‐repellent coating coverage than linear siloxane and the siloxanes comprise hydrophilic and hydrophobic molecular segments. Thus, the as‐prepared superhydrophobic surface, TiO2 nanorods coated with branched siloxanes harvested eight times more water than a typical fluoroalkylsilane (FAS)‐coated surface under a low 30% relative humidity and performed better than most reported biphasic materials.

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Biphilic Surfaces with Optimum Hydrophobic Islands on a Superhydrophobic Background for Dropwise Flow Condensation

Cited by 12 publications

References 65 publications

Enhancement of Dropwise Condensation Heat Transfer through a Sprayable Superhydrophobic Coating

Enhancement of Dropwise Condensation Heat Transfer through a Sprayable Superhydrophobic Coating

Manipulation of droplets and bubbles for thermal applications

Hierarchically Branched Siloxane Brushes for Efficient Harvesting of Atmospheric Water

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