Coarsening droplets for frosting delay on hydrophilic slippery liquid-infused porous surfaces

Droplet Pub Date : 2024-02-17 DOI:10.1002/dro2.106
Jyotirmoy Sarma, Deepak Monga, Zongqi Guo, Fangying Chen, Xianming Dai
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Abstract

Frosting occurs due to the freezing of condensed water droplets on a supercooled surface. The nucleated frost propagates through interdroplet bridges and covers the entire surface, resulting from the deposition of highly supersaturated vapor surrounding tiny droplets. While inhibition of the formation of frost bridges is not possible, the propagation of frost can be delayed by effectively removing tiny droplets. Passive technologies, such as superhydrophobic surfaces (SHS) and hydrophobic slippery liquid-infused porous surfaces (SLIPS), rely on static growth and direct contact with densely distributed droplets. However, use of these approaches in delaying frost propagation involves challenges, as the interdroplet distance remains small. Here, we report a new approach of spontaneous droplet movement on hydrophilic SLIPS to delay the formation of interdroplet frost bridges. Surface tension forces generated by the hydrophilic oil meniscus of a large water droplet efficiently pull neighboring droplets with a diameter of less than 20 μm from all directions. This causes a dynamic separation between water droplets and an adjacent frozen droplet. Such a process delays the formation and propagation of interdroplet frost bridges. Consequently, there is significant delay in frosting on hydrophilic SLIPS compared to those on SHS and hydrophobic SLIPS.

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在亲水性滑液注入多孔表面上粗化液滴以延迟结霜时间
结霜是由于过冷表面上的冷凝水滴冻结而产生的。由于小水滴周围沉积了高度过饱和的水蒸气,成核的霜通过水滴间的桥传播并覆盖整个表面。虽然无法抑制霜桥的形成,但可以通过有效清除微小水滴来延缓霜的传播。被动技术,如超疏水表面(SHS)和疏水性滑液注入多孔表面(SLIPS),依赖于静态生长和与密集分布的水滴直接接触。然而,由于液滴间的距离仍然很小,因此使用这些方法来延迟霜冻的传播是一项挑战。在此,我们报告了一种在亲水性 SLIPS 上实现液滴自发运动以延迟液滴间霜桥形成的新方法。大水滴的亲水性油半月板产生的表面张力能有效地从各个方向拉动直径小于 20 μm 的相邻水滴。这就造成了水滴与相邻冻结水滴之间的动态分离。这一过程会延迟水滴间霜桥的形成和传播。因此,与 SHS 和疏水性 SLIPS 相比,亲水性 SLIPS 上的结霜时间明显延迟。
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Issue Information Front Cover, Volume 3, Number 4, October 2024 Inside Back Cover, Volume 3, Number 4, October 2024 Back Cover, Volume 3, Number 4, October 2024 Inside Front Cover, Volume 3, Number 4, October 2024
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