What question did this study set out to answer?

This work aims to change the freezing direction and control the morphology of water droplets on cold substrates using thermal patterns.

May 16, 2026

Manipulating the freezing direction of liquid via composite thermal patterns

Key Points

This work aims to change the freezing direction and control the morphology of water droplets on cold substrates using thermal patterns.
Composite thermal patterns were designed on a substrate to influence freezing behavior.
Theoretical and experimental analyses were conducted to investigate freezing process and morphology.
Droplet freezing characteristics were evaluated based on conductive and insulating areas.
Droplets frozen in conductive regions exhibited faster solidification compared to those in insulating regions.
The morphology of frozen droplets was successfully controlled by varying the thermal patterns.
Avoidance of pointy tips during freezing was achieved through careful manipulation of substrate design.

Abstract

It is natural that a water droplet freezes upward when deposited on a cold substrate, and a pointy tip forms at the center due to volume expansion during freezing. In this work, the local freezing direction can be changed via composite thermal patterns on a substrate, and the pointy tip of a frozen droplet can be avoided at the same time. Droplets freeze faster in the conductive regions than in the insulating areas. Consequently, the freezing direction and the morphology of the frozen droplet can be controlled by varying the insulating patterns on the substrate. Theoretical and experimental analyses were performed to investigate the effect of composite thermal patterns on the droplet freezing process and morphology. The findings of this work present an effective method for manipulating the anisotropic solidification process on cold substrates.

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Manipulating the freezing direction of liquid via composite thermal patterns

Key Points

Abstract

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