Biomimetic Multiwalled Carbon Nanotube/Polydimethylsiloxane Nanocomposites with Temperature-Controlled, Hydrophobic, and Icephobic Properties

Sun, Yongyang; Wang, Yübo; Sui, Xin; Liang, Wenyan; He, Liang; Wang, Fangxin; Yang, Bin

doi:10.1021/acsanm.1c02275

Cited by 25 publications

(14 citation statements)

References 53 publications

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confidence: 99%

“…Electrical devices have been widely employed for active de-icing on a variety of surfaces [6][7][8] and utilize joule heating to raise the temperature of the accreted ice above 0 °C, facilitating its removal through a phase change to liquid water [9][10][11][12] . Proper thermal/electrical conductivity is required to maximize the de-icing efficiency while minimizing energy consumption 9,13,14 . Graphene-based heaters 6,15 , hot air pumping 16 , conductive polymer-based heaters [17][18][19] and, most commonly, metallic heating systems [20][21][22][23] have all been used to provide sufficient heat to melt the interfacial ice.…”

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Smart low interfacial toughness coatings for on-demand de-icing without melting

et al. 2022

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Ice accretion causes problems in vital industries and has been addressed over the past decades with either passive or active de-icing systems. This work presents a smart, hybrid (passive and active) de-icing system through the combination of a low interfacial toughness coating, printed circuit board heaters, and an ice-detecting microwave sensor. The coating’s interfacial toughness with ice is found to be temperature dependent and can be modulated using the embedded heaters. Accordingly, de-icing is realized without melting the interface. The synergistic combination of the low interfacial toughness coating and periodic heaters results in a greater de-icing power density than a full-coverage heater system. The hybrid de-icing system also shows durability towards repeated icing/de-icing, mechanical abrasion, outdoor exposure, and chemical contamination. A non-contact planar microwave resonator sensor is additionally designed and implemented to precisely detect the presence or absence of water or ice on the surface while operating beneath the coating, further enhancing the system’s energy efficiency. Scalability of the smart coating is demonstrated using large (up to 1 m) iced interfaces. Overall, the smart hybrid system designed here offers a paradigm shift in de-icing that can efficiently render a surface ice-free without the need for energetically expensive interface melting.

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Smart low interfacial toughness coatings for on-demand de-icing without melting

et al. 2022

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“…application of bioinspired CNT-based materials in nanopatterned surfaces. 132,133 Liz-Marza ´n et al reported classical sea-anemonelike CNT-based hollow capsules with magnetic and reinforced properties. The CNT-coated Fe 3 O 4 NP@PS spheres were used as the ''hair'' to provide the reinforcement.…”

Section: Nanopatterned Surfacesmentioning

confidence: 99%

“…Besides their potential as reinforcing materials with high mechanical strength and chemical stability, the unique nanoscale morphology, low hydrophilicity, and optical characteristics of assembled structures of CNTs are also instructive for the application of bioinspired CNT-based materials in nanopatterned surfaces. 132,133 Liz-Marzán et al reported classical sea-anemone-like CNT-based hollow capsules with magnetic and reinforced properties. The CNT-coated Fe 3 O 4 NP@PS spheres were used as the “hair” to provide the reinforcement.…”

Section: Applicationsmentioning

confidence: 99%

Bioinspired carbon nanotube-based materials

et al. 2022

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“…Combined with the surface micro/nano-structures, PDMS substrate can achieve superhydrophobicity, and the ice adhesion strength can be reduced to less than 20 kP a. 13,14 Oil infusion into PDMS substrates can reduce the ice adhesion even further (< 10 kP a). 15 However, the durability of the lubricated PDMS substrate is influenced by the depletion of the lubrication oil layer by the icing-deicing cycles.…”

Section: Introductionmentioning

confidence: 99%

General mechanism and mitigation for strong adhesion of frozen oil sands on solid substrates

Yang

Moradpour

You

et al. 2022

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Oil sands adhered on truck bed reduce transport capacity of the truck, require manual cleaning, and create hurdles for automated surface mining. Study on the adhesion properties of oil sands to solid substrates is important to minimize the fouling of substrates during mining operation. In this work, we study the influence of hydrophobicity and mechanical properties of the substrates on the adhesion strength of frozen oil sands. By using an adhesion force apparatus with temperature control, we measure the adhesion strength of both ice and frozen oil sands on six types of substrates with water contact angle from ∼20◦ to ∼130◦ and Young’s modulus from a few MPa to 300 GPa. A clear linear correlation between the adhesion strength of pure ice and that of frozen oil sands is observed. Furthermore, the adhesion strength increases with the load on the oil sands sample and reaches a plateau at ∼450 kPa. The maximum adhesion strength may be due to the limit of particle packing of oil sands. We also demonstrate that spray coating of anti-freezing liquids is effective for the mitigation of the adhesion of frozen oil sands. Substrates coated with various anti-freezing liquids showed undetectable oil sands adhesion strength at -20 ◦C with 0.06 MPa of load. The study on oil sands adhesion and potential fouling mitigation method may provide a potential solution to industries looking to reduce fouling of surfaces by frozen granular matter.

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Biomimetic Multiwalled Carbon Nanotube/Polydimethylsiloxane Nanocomposites with Temperature-Controlled, Hydrophobic, and Icephobic Properties

Cited by 25 publications

References 53 publications

Smart low interfacial toughness coatings for on-demand de-icing without melting

Smart low interfacial toughness coatings for on-demand de-icing without melting

Bioinspired carbon nanotube-based materials

General mechanism and mitigation for strong adhesion of frozen oil sands on solid substrates

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