Long‐Term Immersion Study for Durability of Interconnected Micropatterned Surfaces with Sustained Water Repellency

Seo Rim Park; Seungmin Oh; Woo Young Kim; Do Hyeog Kim; Sang Hoon Lee; Seungwoo Shin; Su Hyun Choi; Sin Kwon; Heedoo Lee; Seok Kim; Young Tae Cho

doi:10.1002/admi.202400144

Advanced Materials Interfaces (Aug 2024)

Long‐Term Immersion Study for Durability of Interconnected Micropatterned Surfaces with Sustained Water Repellency

Seo Rim Park,
Seungmin Oh,
Woo Young Kim,
Do Hyeog Kim,
Sang Hoon Lee,
Seungwoo Shin,
Su Hyun Choi,
Sin Kwon,
Heedoo Lee,
Seok Kim,
Young Tae Cho

Affiliations

Seo Rim Park: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Seungmin Oh: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Woo Young Kim: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Do Hyeog Kim: Department of Mechanical Engineering Changwon National University Changwon 51140 South Korea
Sang Hoon Lee: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Seungwoo Shin: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Su Hyun Choi: Department of Flexible & Printed Electronics Korea Institute of Machinery and Materials Daejeon 34103 South Korea
Sin Kwon: Department of Flexible & Printed Electronics Korea Institute of Machinery and Materials Daejeon 34103 South Korea
Heedoo Lee: Department of Biology and Chemistry Changwon National University Changwon 51140 South Korea
Seok Kim: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea
Young Tae Cho: Department of Smart Manufacturing Engineering Changwon National University Changwon 51140 South Korea

DOI: https://doi.org/10.1002/admi.202400144
Journal volume & issue: Vol. 11, no. 22
pp. n/a – n/a

Abstract

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Abstract The sustained water repellency of interconnected micropatterned surfaces is explored over an extended duration, with a focus on their resilience during a 90‐day water‐immersion test. Initially, the microstructure surfaces exhibit high water repellency, a characteristic of the Cassie–Baxter state. However, subsequent detailed temporal analyses reveal varying responses depending on the structural topology. The interconnected micropatterned surfaces exhibit remarkable long‐term resistance to water; this is attributed to the formation of large and stable air pockets enabled by their unique microcavity structures. In comparison, hierarchical microcavity surfaces with micropillars exhibit a notable decrease in water repellency, as evidenced by reduced contact angles, suggesting a transition to a wetting state owing to the emergence of surface hydrophilicity during long‐term water exposure. This study demonstrates the importance of stable air‐pocket effects, particularly in applications where the long‐term stability of liquid repellency is critical, and suggests the role of interconnected structures in maintaining water repellency over time.

Published in Advanced Materials Interfaces

ISSN: 2196-7350 (Online)
Publisher: Wiley-VCH
Country of publisher: Germany
LCC subjects: Science: Physics; Technology
Website: https://onlinelibrary.wiley.com/journal/21967350

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