Hsin-I Lu scite author profile

Nanocasting technique was used to obtain a biomimetic superhydrophobic electroactive polyimide (SEPI) surface structure from a natural Xanthosoma sagittifolium leaf. An electroactive polyimide (EPI) was first synthesized through thermal imidization. An impression of the superhydrophobic Xanthosoma sagittifolium leaf was then nanocasted onto the surface of the EPI so that the resulting EPI was superhydrophobic and would prevent corrosion. Polydimethylsiloxane (PDMS) was then used as a negative template to transfer the impression of the superhydrophobic surface of the biomimetic EPI onto a cold-rolled steel (CRS) electrode. The superhydrophobic electroactive material could be used as advanced coatings that protect metals against corrosion. The morphology of the surface of the as-synthesized SEPI coating was investigated using scanning electron microscopy (SEM). The surface showed numerous micromastoids, each decorated with many nanowrinkles. The water contact angle (CA) for the SEPI coating was 155°, which was significantly larger than that for the EPI coating (i.e., CA = 87°). The significant increase in the contact angle indicated that the biomimetic morphology effectively repelled water. Potentiodynamic and electrochemical impedance spectroscopic measurements indicated that the SEPI coating offered better protection against corrosion than the EPI coating did.

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Advanced anticorrosive coatings prepared from electroactive polyimide/graphene nanocomposites with synergistic effects of redox catalytic capability and gas barrier properties

Chang¹,

Hsu²,

Lu³

et al. 2014

Express Polym. Lett.

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Enhancement of physical properties of electroactive polyimide nanocomposites by addition of graphene nanosheets

Chang

Lai

et al. 2013

Polym. Int.

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Electroactive polyimide (EPI) nanocomposites with amino-capped aniline trimer and 4 -(4,4 -isopropylidene-diphenoxy) bis(phthalic anhydride) as monomers, and functionalized with carboxyl-graphene nanosheets, were prepared by thermal imidization. The as-prepared electroactive polyimide/graphene nanocomposite (EPGN) materials were then characterized by Fourier transform infrared spectroscopy and transmission electron microscopy. In situ monitoring of the redox behavior of the as-prepared EPGN materials was performed by cyclic voltammetry studies. The effects of material composition on the mechanical, thermal, thermal transport, dielectric and molecular barrier properties of EPGN membranes were investigated by dynamic mechanical analysis, TGA, DSC, the transient plane source technique, LCR meter and gas permeability analyzer, respectively. It should be noted that all the properties of the EPGN membranes were found to improve substantially over those of non-electroactive polyimide and EPI. For example, upon loading of 1 wt% graphene, EPGN membranes were found to have an increase of over 20%, 5%, 65% and 20% in mechanical strength, thermal stability, thermal conductivity and dielectric constant, respectively, and a reduction of over 20% in gas permeability.

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Enhancement of physical properties of electroactive polyimide nanocomposites by addition of graphene nanosheets

Chang¹,

Lu²,

Lai³

et al. 2015

Polym. Int.

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Corrigendum to “Room-temperature cured hydrophobic epoxy/graphene composites as corrosion inhibitor for cold-rolled steel” [Carbon 66 (2014) 144–153]

Chang

Hsu

Lu³

et al. 2015

Carbon

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Hsin-I Lu

Novel anticorrosion coatings prepared from polyaniline/graphene composites

Room-temperature cured hydrophobic epoxy/graphene composites as corrosion inhibitor for cold-rolled steel

Nanocasting Technique to Prepare Lotus-leaf-like Superhydrophobic Electroactive Polyimide as Advanced Anticorrosive Coatings

Advanced anticorrosive coatings prepared from electroactive polyimide/graphene nanocomposites with synergistic effects of redox catalytic capability and gas barrier properties

Enhancement of physical properties of electroactive polyimide nanocomposites by addition of graphene nanosheets

Enhancement of physical properties of electroactive polyimide nanocomposites by addition of graphene nanosheets

Corrigendum to “Room-temperature cured hydrophobic epoxy/graphene composites as corrosion inhibitor for cold-rolled steel” [Carbon 66 (2014) 144–153]

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