Ice-phobic glass-substrate surfaces coated with polypeptides inspired by antifreeze protein

•We conducted experiments on the freezing of water disks in washers on polypeptide-coated surfaces.•The ice adhesion strength of the coated surfaces decreased by up to 67% compared with that of uncoated surfaces.•The coated surfaces could maintain their characteristics for up to 100 repetitions of t...

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Veröffentlicht in:International journal of refrigeration 2020-06, Vol.114, p.201-209
Hauptverfasser: Koshio, Kazuya, Waku, Tomonori, Hagiwara, Yoshimichi
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container_title International journal of refrigeration
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creator Koshio, Kazuya
Waku, Tomonori
Hagiwara, Yoshimichi
description •We conducted experiments on the freezing of water disks in washers on polypeptide-coated surfaces.•The ice adhesion strength of the coated surfaces decreased by up to 67% compared with that of uncoated surfaces.•The coated surfaces could maintain their characteristics for up to 100 repetitions of the ice removal.•The transparency of the glass plate was not changed by the coatin. The development of ice-phobic glass-substrate surfaces for industrial applications, such as preventing the formation of ice on vehicle windshields, is important. We have previously developed a glass surface coated with a polypeptide whose amino acid sequence is identical to part of an antifreeze protein. For this polypeptide, we showed that the ice adhesion strength was reduced by the coexistence of smooth surface parts exposing hydrophobic amino-acid residues and protrusion surface parts exposing hydrophilic amino-acid residues. In this report, we improve the experimental methods and conduct experiments on the freezing of water disks in steel washers on polypeptide-coated and uncoated surfaces. Under constant cooling surface temperatures, the ice adhesion strength of the coated surfaces decreased by up to 67% when compared with that of uncoated surfaces. Atomic force microscopy observations of the polypeptide-coated glass revealed small and large protrusions on the surface, which were formed by the aggregation of polypeptide. These protrusions and the smooth surface are primarily responsible for the reduced ice adhesion strength. In addition, repeated freezing of the water disks on the surfaces revealed that the coated surfaces could maintain their characteristics for up to 100 repetitions. In addition, the transparency of the glass plate was not changed by the coating. Thus, this polypeptide coating technique should be suitable for improving deicing properties of windshields, traffic lights, and surveillance cameras.
doi_str_mv 10.1016/j.ijrefrig.2020.01.025
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The development of ice-phobic glass-substrate surfaces for industrial applications, such as preventing the formation of ice on vehicle windshields, is important. We have previously developed a glass surface coated with a polypeptide whose amino acid sequence is identical to part of an antifreeze protein. For this polypeptide, we showed that the ice adhesion strength was reduced by the coexistence of smooth surface parts exposing hydrophobic amino-acid residues and protrusion surface parts exposing hydrophilic amino-acid residues. In this report, we improve the experimental methods and conduct experiments on the freezing of water disks in steel washers on polypeptide-coated and uncoated surfaces. Under constant cooling surface temperatures, the ice adhesion strength of the coated surfaces decreased by up to 67% when compared with that of uncoated surfaces. Atomic force microscopy observations of the polypeptide-coated glass revealed small and large protrusions on the surface, which were formed by the aggregation of polypeptide. These protrusions and the smooth surface are primarily responsible for the reduced ice adhesion strength. In addition, repeated freezing of the water disks on the surfaces revealed that the coated surfaces could maintain their characteristics for up to 100 repetitions. In addition, the transparency of the glass plate was not changed by the coating. 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The development of ice-phobic glass-substrate surfaces for industrial applications, such as preventing the formation of ice on vehicle windshields, is important. We have previously developed a glass surface coated with a polypeptide whose amino acid sequence is identical to part of an antifreeze protein. For this polypeptide, we showed that the ice adhesion strength was reduced by the coexistence of smooth surface parts exposing hydrophobic amino-acid residues and protrusion surface parts exposing hydrophilic amino-acid residues. In this report, we improve the experimental methods and conduct experiments on the freezing of water disks in steel washers on polypeptide-coated and uncoated surfaces. Under constant cooling surface temperatures, the ice adhesion strength of the coated surfaces decreased by up to 67% when compared with that of uncoated surfaces. Atomic force microscopy observations of the polypeptide-coated glass revealed small and large protrusions on the surface, which were formed by the aggregation of polypeptide. These protrusions and the smooth surface are primarily responsible for the reduced ice adhesion strength. In addition, repeated freezing of the water disks on the surfaces revealed that the coated surfaces could maintain their characteristics for up to 100 repetitions. In addition, the transparency of the glass plate was not changed by the coating. 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subjects Adhesive strength
Agent de couplage silane
Amino acids
Atomic force microscopy
Coating
Disks
Force d’adhérence de la glace
Freezing
Glass plates
Glass substrates
Ice adhesion strength
Ice formation
Icephobicity
Industrial applications
Polypeptide
Polypeptides
Proteins
Residues
Rugosité de surface
Silane coupling agent
Substrates
Surface roughness
Traffic signals
Traffic surveillance
Transparence
Transparency
Windshields
title Ice-phobic glass-substrate surfaces coated with polypeptides inspired by antifreeze protein
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