2021
DOI: 10.1038/s41467-021-23511-3
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Slippery damper of an overlay for arresting and manipulating droplets on nonwetting surfaces

Abstract: In diverse processes, such as fertilization, insecticides, and cooling, liquid delivery is compromised by the super-repellency of receiving surfaces, including super-hydro-/omni-phobic and superheated types, a consequence of intercalated air pockets or vapor cushions that promote droplet rebounds as floating mass-spring systems. By simply overlaying impacting droplets with a tiny amount of lubricant (less than 0.1 vol% of the droplet), their interfacial properties are modified in such a way that damper-roller … Show more

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Cited by 36 publications
(27 citation statements)
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“…The method is beneficial to the applications like spraying or coating. [105] The specific live-oligomeric surfactant in the impacting droplet can even induce its uniform spreading Oppositely charged polyelectrolytes Water Hydrophobic surface [18] Aerosol OT surfactant Water Superhydrophobic surface [103] A live-oligomeric surfactant Water Superhydrophobic surface [104] Surfactant and polymer Water Wired and curved superhydrophobic surface [105] Shape distortion Electric field Water Hydrophobic surface [107,108] Electromagnetic field Ferrofluid Solid surface [109] Hot droplet Heating Water Superhydrophobic surface [110][111][112][113] Overlayer Low surface tension liquid Water, oil Superhydrophobic surface, superomniphobic surface, superheated surface [15] on the superhydrophobic surface by jamming at the contact line between the droplet and the superhydrophobic surface, which is desirable for high-requirement printing. [104] Shape Distortion: In the nature, raindrops may oscillate before the impact due to the droplet collisions, which would cause the distortion of the millimeter-sized droplet shape.…”
Section: Bouncing Suppressionmentioning
confidence: 99%
See 3 more Smart Citations
“…The method is beneficial to the applications like spraying or coating. [105] The specific live-oligomeric surfactant in the impacting droplet can even induce its uniform spreading Oppositely charged polyelectrolytes Water Hydrophobic surface [18] Aerosol OT surfactant Water Superhydrophobic surface [103] A live-oligomeric surfactant Water Superhydrophobic surface [104] Surfactant and polymer Water Wired and curved superhydrophobic surface [105] Shape distortion Electric field Water Hydrophobic surface [107,108] Electromagnetic field Ferrofluid Solid surface [109] Hot droplet Heating Water Superhydrophobic surface [110][111][112][113] Overlayer Low surface tension liquid Water, oil Superhydrophobic surface, superomniphobic surface, superheated surface [15] on the superhydrophobic surface by jamming at the contact line between the droplet and the superhydrophobic surface, which is desirable for high-requirement printing. [104] Shape Distortion: In the nature, raindrops may oscillate before the impact due to the droplet collisions, which would cause the distortion of the millimeter-sized droplet shape.…”
Section: Bouncing Suppressionmentioning
confidence: 99%
“…Han et al first used a micro/nanothickness (from ≈300 nm to ≈300 μm) overlayer as a damper to help millimeter-scale droplet deposit on superrepellent surfaces. [15] The overlaying can be achieved via microfluidics [115][116][117][118][119][120][121][122][123][124] or counter spraying [15] etc. The overlayer first contacts and pins the super-repellent surface, and then consumes the kinetic energy of the impacting compound droplet via viscous dissipation inside the compound droplet.…”
Section: Bouncing Suppressionmentioning
confidence: 99%
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“…Inspired by lotus leaves and beetles, wettability, especially heterogeneous wettability, provides an effective way to manipulate droplet behaviors. [19][20][21][22][23][24][25] In this work, we fabricate droplet-based springs using two parallel plates with heterogeneous wettability, and investigate their non-Hookean elastic mechanics under pressing and stretching. We demonstrate that the nonlinear behaviors of the spring can be well manipulated by the droplet volume, droplet number, and especially the wettability patterns on the parallel plates.…”
Section: Doi: 101002/smll202200875mentioning
confidence: 99%