Recent Progress in Bionic Condensate Microdrop Self‐Propelling Surfaces

Gong, X. G.; Gao, Xuefeng; Jiang, Lei

doi:10.1002/adma.201703002

Cited by 99 publications

(65 citation statements)

References 118 publications

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“…This may be because under the dew conditions, the water‐harvesting performance is determined by both the water capturing rate and the water removal efficiency, which require the surface to exhibit different wettability for each contribution; wettable surfaces favor droplet nucleation, whereas SHPo surfaces favor droplet removal. Since the droplet nucleation barrier on the SHPo surface is higher than that on the SHPi surface, the low condensation rate limits the overall water collection efficiency; additionally, if the droplets depart from the SHPo surface via coalescence‐induced jumping, the departing droplets would be evaporated in the air, causing a larger loss of water collection, despite fast droplet departure frequency on the SHPo surface …”

Section: Resultsmentioning

confidence: 99%

Tunable Wetting Patterns on Superhydrophilic/Superhydrophobic Hybrid Surfaces for Enhanced Dew‐Harvesting Efficacy

Hou

et al. 2019

Adv Materials Inter

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Dew collection is a promising strategy to address the water scarcity problem in arid regions. Inspired by the natural species, engineering superhydrophilic/superhydrophobic hybrid (SSH) surfaces has received much attention for water harvesting in recent years. However, it is still challenging to design a surface that is capable of fast condensate droplet capture and directional droplet transport, both of which are essential for efficient dew harvesting at low subcooling conditions. Herein, a convenient, straightforward method to fabricate SSH surfaces with superhydrophilic (SHPi) triangular patterns on the superhydrophobic (SHPo) substrates by using a laser ablation approach is presented. The triangle spacing is optimized to delicately control condensate droplet nucleation and directional water transport. It is found that water collection performance on the SSH surfaces exhibits remarkable dependence on the triangle spacing. The SSH surface with a triangle spacing of 1.5 mm enables fast condensate droplet nucleation, directional transport, and efficient departure, yielding an ≈54% or ≈21% enhancement of water collection rate compared to the uniform SHPo or SHPi surfaces. This study of exploiting multiple coupling effects of the surface features to enhance dew collection efficiency can provide important insights for developing high‐performance water‐harvesting systems via dew.

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Section: Resultsmentioning

confidence: 99%

Tunable Wetting Patterns on Superhydrophilic/Superhydrophobic Hybrid Surfaces for Enhanced Dew‐Harvesting Efficacy

Hou

et al. 2019

Adv Materials Inter

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“…Inspired by nature, [ 4–7 ] superhydrophobic surfaces with extreme repellency to water have attracted significant interest, owing to their potential applications in anti‐condensation, anti‐frosting, anti‐icing, anti‐fogging, and self‐cleaning activities. [ 8–20 ] Biomimetic superhydrophobic surfaces can be prepared via different approaches, including reactive ion etching, [ 21 ] chemical/physical processing, [ 22–25 ] lithographing, [ 26,27 ] and coating. [ 28–33 ] Among these approaches, the coating approach has been widely applied, owing to its simple preparation process, low equipment requirement, and wide application range.…”

Section: Introductionmentioning

confidence: 99%

Water‐Based Robust Transparent Superamphiphobic Coatings for Resistance to Condensation, Frosting, Icing, and Fouling

Song

Cheng

et al. 2020

Adv Materials Inter

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high fraction of the total energy consumption. For example, air-conditioners and refrigerators account for more than 10% and 32% of the total residential energy consumption in China, respectively. [2,3] Therefore, improvement of the energy efficiency characterizing heat exchangers plays a crucial role in reducing energy consumption. However, the occurrence of condensate films, frost layers, and fouling on the surfaces of conventional hydrophilic heat exchangers acts as a thermal barrier to significantly reduce in the heat transfer. One alternative, that is, a periodic heating process for complete melting of the frost, results in extra energy consumption. In addition, wet surfaces are prone to the dust deposition, breeding of bacteria, and corrosion acceleration.Inspired by nature, [4][5][6][7] superhydrophobic surfaces with extreme repellency to water have attracted significant interest, owing to their potential applications in anticondensation, anti-frosting, anti-icing, antifogging, and self-cleaning activities. [8][9][10][11][12][13][14][15][16][17][18][19][20] Biomimetic superhydrophobic surfaces can be prepared via different approaches, including reactive ion etching, [21] chemical/physical processing, [22][23][24][25] lithographing, [26,27] and coating. [28][29][30][31][32][33] Among these approaches, the coating approach has been widely applied, owing to its simple preparation process, low equipment requirement, and wide application range. However, organic solvents, such as ethanol, acetone, or butyl acetate, are frequently used to dissolve or disperse low surface energy substances during the preparation process. [34,35] Compared with organic solvents, water is a green, safe, and economical solvent. [36] A few strategies have been reported about preparing waterbased superhydrophobic coatings and even water-based superamphiphobic coatings. [37][38][39][40][41][42][43][44] The focus of the present studies is on the preparation of these coatings. However, high performances of water-based superhydrophobic coatings are neglected which are the key factors in wide, long-term, and efficient application, due to the difficulty in achieving them. For example, micro-sized or smaller condensate dewdrops on most water-based superhydrophobic coatings occur in the Wenzel state, although the contact angles (CAs) and sliding angles (SAs) of macro water droplets on these coatings are >150 and <10, respectively. [45] The Wenzel-state dewdrops may lead to Due to the considerable demand for improving energy conservation and emission reduction, superhydrophobic coatings mainly derived from organic solvents have attracted significant interest, based on their potential role in enhancing heat transfer. Although water-based coatings are relatively safe and economical, and contain low volatile organic compounds (VOCs), the realization of coatings with excellent anti-condensation, anti-frosting, antiicing, and passive self-cleaning properties remains challenging, owing to the Wenzel state of small-sized condensate microdrops. Herein, ...

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“…Generally, there are two forms of water condensation of moisture from the air: filmwise condensation and dropwise condensation. [17][18][19] Filmwise condensation refers to the condensate liquid forming a continuous film, while dropwise condensation refers to the harvesting of condensate liquids in the form of droplets. In consideration of heat-transfer efficiency during phase-change, dropwise condensation is over ten times more than that of filmwise condensation, and the heat-transfer performance of dropwise condensation can be further improved by fabricating micro/nano-structures on the substrate.…”

Section: Introductionmentioning

confidence: 99%