Thermo-responsive Fluorinated Organogels Showing Anti-fouling and Long-Lasting/Repeatable Icephobic Properties

Buddingh, Jasmine V.; Nakamura, Satoshi; Liu, Guojun; Hozumi, Atsushi

doi:10.1021/acs.langmuir.2c01647

Cited by 9 publications

(8 citation statements)

References 51 publications

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“…In the case of ice shedding from a uniform elastomeric coating through interfacial cavitation, τ is linked to the shear modulus ( G ), coating thickness ( l ), and ice adhesion work ( w a ) by eq ,, τ ∝ G w normala / l Decreasing w a is achieved through hydrophobic polymers, while G reduction involves lightly cross-linked rubbers or organogels (rubbers imbued with organic lubricants). However, these materials are often soft and weak, limiting practical applications. − Moreover, many reported materials display mediocre τ values ranging from 5 to 50 kPa. − …”

Section: Introductionmentioning

confidence: 99%

Hard Epoxy Coating with Lasting Low Ice Adhesion Strength

Buddingh,

Liu

2023

ACS Appl. Polym. Mater.

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A high-hardness (H) coating typically has an elevated ice adhesion strength (τ), while a soft coating tends to shed ice easily. We recently reported a one-step process for a bilayer polyurethane coating that achieved both high H and low τ, effectively decoupling H from τ. However, these low τ values remained stable only through 12 icing/deicing cycles, beyond which τ rapidly increased. To maintain consistently low τ, another bilayer coating is prepared using a diamine, an epoxy compound, and poly(glycidyl methacrylate) with poly(dimethylsiloxane) (PDMS) side chains. This coating features a bulk hardness of 0.31 ± 0.03 GPa, PDMS nanopools in the matrix, and a liquid-like PDMS brush layer on the surface. A silicone oil mixture (SOm) can be added to the formulation before coating formation. Increasing the SOm content enlarges PDMS/SOm nanopools and surface roughness. Lubricated coatings are produced by applying SOm or individual silicone oils (SOs) of varying viscosities to preformed nonporous and microporous coatings. This study compares ice-shedding properties of these coatings over 30 icing/deicing cycles. Results show that the smooth bilayer epoxy coating, lubricated with 1.55 g/m2 SOm, maintains τ values <5 kPa, 100 times lower than glass, after 30 icing/deicing cycles. This marks the first polymer coating to simultaneously exhibit high H alongside such consistently low τ values over numerous icing/deicing cycles.

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Section: Introductionmentioning

confidence: 99%

Hard Epoxy Coating with Lasting Low Ice Adhesion Strength

Buddingh,

Liu

2023

ACS Appl. Polym. Mater.

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“…These novel AmOG offer a promising solution in developing long-lasting anti-icing materials. In the literature, many stimuliresponsive organogels, which offer better functionalities when used as SLIPS, have been reported [212,213,213,214]. Organogels have emerged as a revolutionary alternative to traditional SLIPS.…”

Section: 4mentioning

confidence: 99%

Durability of Slippery Liquid-Infused Surfaces: Challenges and Advances

et al. 2023

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Slippery liquid-infused porous surfaces (SLIPS) have emerged as a unique approach to creating surfaces that can resist fouling when placed in contact with aqueous media, organic fluids, or biological organisms. These surfaces are composed of essentially two components: a liquid lubricant that is locked within the protrusions of a textured solid due to capillarity. Drops, immiscible to the lubricant, exhibit high mobility and very-low-contact-angle hysteresis when placed on such surfaces. Moreover, these surfaces are shown to resist adhesion to a wide range of fluids, can withstand high pressure, and are able to self-clean. Due to these remarkable properties, SLIPS are considered a promising candidate for applications such as designing anti-fouling and anti-corrosion surfaces, drag reduction, and fluid manipulation. These collective properties, however, are only available as long as the lubricant remains infused within the surface protrusions. A number of mechanisms can drive the depletion of the lubricant from the interior of the texture, leading to the loss of functionality of SLIPS. Lubricant depletion is one challenge that is hindering the real-world application of these surfaces. This review mainly focuses on the studies conducted in the context of enhancing the lubricant retention abilities of SLIPS. In addition, a concise introduction of wetting transitions on structured as well as liquid-infused surfaces is given. We also discuss, briefly, the mechanisms that are responsible for lubricant depletion.

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“…Superhydrophobic coatings, [ 1–4,19–22 ] slippery liquid‐infused porous surfaces (SLIPS), [ 23 ] coatings using phase‐changing materials, [ 24 ] soft organogels, [ 11,25–28 ] photothermal coatings, [ 29 ] coatings with fracture‐controlled surfaces, [ 30 ] mechanically robust coatings with lightly‐cross‐linked surfaces, [ 13 ] and coatings with low interfacial toughness [ 31 ] have been explored for ice shedding with pros and cons for each type. For example, superhydrophobic surfaces are typically fragile and susceptible to frost, while a SLIPS tends to lose its lubricant after few icing/de‐icing cycles.…”

Section: Introductionmentioning

confidence: 99%

Ice‐Shedding Endurance Enhancement of Lubricated Polyurethane NP‐GLIDE Coating Through Dual Cross‐Linking with Covalent and Hydrogen Bonds

Zheng,

Lai,

Liu

2023

Adv Funct Materials

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An NP‐GLIDE coating, featuring a liquid‐like polymer brush layer on its surface and nanopools of a grafted liquid ingredient for dewetting enablement within its matrix, is normally covalently cross‐linked (CX). This paper introduces a dually cross‐linked (DX) NP‐GLIDE coating, employing urethane bonds and H─bonds for crosslinking. Both the DX and CX coatings, utilizing poly(dimethyl siloxane) (PDMS) as the dewetting enabler, exhibit low ice adhesion strengths (τ). Post‐lubrication with silicone oil (SO), ice is readily shed under gravity from the coatings. The DX coating maintains low τ over numerous icing/de‐icing cycles, outlasting the CX coating. This durability is likely due to the lubricant‐loss‐responsive nature of the DX matrix. The matrix increases its H─bond cross‐links responding to lubricant loss and the cross‐linking density increase triggers additional lubricant release into the PDMS brush layer. This cyclic process persists over time. Under optimal conditions after 31 icing/de‐icing cycles, the lubricated DX coating demonstrates an impressively low τ of 1.8 ± 0.5 kPa. In contrast, the lubricated CX counterpart has a τ of 32 ± 11 kPa, while plain glass records a τ of 325 ± 14 kPa. This study underscores the significant potential of dual cross‐linking for enhancing ice‐shedding endurance of coatings.

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Thermo-responsive Fluorinated Organogels Showing Anti-fouling and Long-Lasting/Repeatable Icephobic Properties

Cited by 9 publications

References 51 publications

Hard Epoxy Coating with Lasting Low Ice Adhesion Strength

Hard Epoxy Coating with Lasting Low Ice Adhesion Strength

Durability of Slippery Liquid-Infused Surfaces: Challenges and Advances

Ice‐Shedding Endurance Enhancement of Lubricated Polyurethane NP‐GLIDE Coating Through Dual Cross‐Linking with Covalent and Hydrogen Bonds

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