Micro-replication platform for studying the structural effect of seed surfaces on wetting properties

Shin, Seung-woo; Choi, Su Hyun; Baasanmunkh, Shukherdorj; Kim, Seok; Choi, Hyeok Jae; Cho, Young Tae

doi:10.1038/s41598-022-09634-7

Cited by 5 publications

(5 citation statements)

References 46 publications

(40 reference statements)

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“…These samples were prepared to investigate systematically how the combined influence of surface geometry and wettability impacts both the evaporation dynamics and resulting patterns formed by deposited particles. [32,[41][42][43][44] Figure 1C portrays the fabricated microstructured surfaces, featuring micropillars with a diameter (d) and pitch (p) of 4.5 and 40 μm, respectively, as well as the microcavities with a wall thickness (t) and hexagonal side length (l) of 3 and 40 μm, respectively. To investigate the wetting and evaporation dynamics of these samples in the context of sensing applications, a test system was designed using liquid droplets blended with nanoparticles, simulating the analyte-laden colloidal suspension.…”

Section: Wetting Properties and Evaporation Dynamicsmentioning

confidence: 99%

Multifunctional Microcavity Surfaces for Robust Capture and Direct Rapid Sampling of Concentrated Analytes

Shin,

Oh,

Park

et al. 2023

Small Structures

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Evaporation patterns of liquid droplets containing nanoparticles or colloids have extensive applications in diagnostics and printing. Controlling these patterns by studying the evaporation behavior of colloidal droplets on surfaces is important for enhancing sensing platforms. In this study, A liquid‐repellent microcavity surface is introduced to robustly capture deposited analytic particles. The proposed microcavity surface maintains stable air pockets for liquid repellency and strong pinning for the spatial stabilization of the evaporating droplet, thereby resulting in a coffee‐ring concentration. This microcavity surface also acts as a “microcontainer” for the deposited particles, thereby protecting them against external damage. To demonstrate the multifaceted capabilities of microcavity surfaces, further comparison is done of three different surface structures, planar, micropillared, and that with microcavities in a hexagonal arrangement, by analyzing their evaporation dynamics and dried deposit patterns. The microcavity surface exhibits superior particle capture, thereby revealing its applicability in on‐site testing. Using the direct rapid sampling of analytical materials, the potential of the fabricated microcavity surface for point‐of‐care testing is demonstrated. The proposed microcavity surfaces suggest new avenues for the development of more robust and sensitive sensing platforms.

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Section: Wetting Properties and Evaporation Dynamicsmentioning

confidence: 99%

Multifunctional Microcavity Surfaces for Robust Capture and Direct Rapid Sampling of Concentrated Analytes

Shin,

Oh,

Park

et al. 2023

Small Structures

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“…These structures are crafted using methods such as lithography [7], sol-gel [8], selfassembly [9,10], direct replication using Anodic Aluminum Oxide (AAO) [11][12][13][14], and SPPW [15][16][17]. Nanoimprint lithography (NIL) [18][19][20][21][22], a technology employing roll imprinting to create nanopatterns by coating a resin that cures with ultraviolet light, is particularly esteemed for its simplicity and cost-effectiveness. However, the nature of NIL, involving the transfer of thin layered materials through pressure to create patterns on a new surface, imposes limitations on achieving structures with high aspect ratios.…”

Section: Introductionmentioning

confidence: 99%

Formation of Multiscale Porous Surfaces via Evaporation-Induced Aggregation of Imprinted Nanowires with Highly Viscous Photocurable Materials

Kim,

Shin,

Kim

et al. 2024

Preprint

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Numerous structures at the nano- and microscale manifest distinctive properties with far-reaching implications across diverse fields, including electronics, electricity, medicine, and surface engi-neering. Established methods such as nanoimprint lithography, photolithography, and self-assembly play crucial roles in the fabrication of nano- and microstructures; however, they exhibit limitations in generating high-aspect-ratio structures when utilizing high-viscosity pho-tocurable resins. In response to this inherent challenge, we propose a highly cost-effective ap-proach facilitating the direct replication of high-aspect-ratio structures, specifically nanowires, through the utilization of anodized aluminum substrates. This study elucidates the streamlined fabrication process for multiscale porous surfaces achieved through the evaporation-induced in-tegration of solid nanowires printed with high-viscosity photocurable resin.

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“…[25,26] We focused on the main water-repellent surface production methods: coating with low-surfaceenergy materials [27][28][29][30][31] and generating nano/microstructures via lithography and template replication. [32][33][34][35][36][37][38] However, surface coatings are limited by their lack of durability, often requiring frequent reapplication to maintain effectiveness. [39][40][41] Previous studies on longterm water-resistance stability have revealed a significant reduction in contact angles over time.…”

Section: Introductionmentioning

confidence: 99%

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

Park,

Oh,

Kim

et al. 2024

Adv Materials Inter

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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.

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Micro-replication platform for studying the structural effect of seed surfaces on wetting properties

Cited by 5 publications

References 46 publications

Multifunctional Microcavity Surfaces for Robust Capture and Direct Rapid Sampling of Concentrated Analytes

Multifunctional Microcavity Surfaces for Robust Capture and Direct Rapid Sampling of Concentrated Analytes

Formation of Multiscale Porous Surfaces via Evaporation-Induced Aggregation of Imprinted Nanowires with Highly Viscous Photocurable Materials

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

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