Controllable self‐transport of bouncing droplets on ultraslippery surfaces with wedge‐shaped grooves

Yue, Chuchen; Dai, Qingwen; Yang, Xiaolong; Gachot, Carsten; Huang, Wei; Wang, Xiaolei

doi:10.1002/dro2.118

Droplet

2024

DOI: 10.1002/dro2.118

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Controllable self‐transport of bouncing droplets on ultraslippery surfaces with wedge‐shaped grooves

Chuchen Yue,

Qingwen Dai,

Xiaolong Yang

et al.

Abstract: Preventing the accretion of droplets on surfaces is vital and slippery liquid‐infused porous surfaces (SLIPS) have promising application prospects, such as surface self‐cleaning and droplet transportation. In this work, controllable self‐transport of bouncing droplets on ultraslippery surfaces with wedge‐shaped grooves is reported. The impact behaviors of droplets on SLIPS under various impact velocities and diameters are explored, which can be classified as hover, total bounce, partial bounce, Worthington jet… Show more

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Steerable droplet precise bouncing on a superhydrophobic surface with superhydrophilic stripes

Huang,

He,

Yin

et al. 2024

Applied Physics Letters

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The precise rebound of a droplet upon hitting a solid surface has garnered significant attention in recent years due to its critical applications in self-cleaning, printing industries, and the design of heat exchanger surfaces, among others. This study introduces an innovative approach that combines femtosecond laser processing with a high-temperature stearic acid modification to create surfaces that feature superhydrophilic (SHL) stripes on a superhydrophobic substrate. By controlling the offset distance between the droplet's impact point and the SHL stripe, we achieved a directional and precise rebound of the droplets. Our findings indicate that the lateral displacement of the droplet increases with the offset distance and always tilts toward the direction of the SHL stripe. This study also incorporates numerical simulations to validate the findings, shedding light on the energy conversion mechanisms at the liquid–solid interface during the impact, particularly during the retraction phase. This discovery is significant for more accurately predicting the specific landing spots of rebounding droplets.

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Steerable droplet precise bouncing on a superhydrophobic surface with superhydrophilic stripes

Huang,

He,

Yin

et al. 2024

Applied Physics Letters

View full text Add to dashboard Cite

show abstract

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Controllable self‐transport of bouncing droplets on ultraslippery surfaces with wedge‐shaped grooves

Cited by 1 publication

References 40 publications

Steerable droplet precise bouncing on a superhydrophobic surface with superhydrophilic stripes

Steerable droplet precise bouncing on a superhydrophobic surface with superhydrophilic stripes

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