Freeze‐dried graphene oxide modified with trimethylhexamethylene in the mix solvent for improved anti‐corrosion property of epoxy

Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with different functional groups to achieve better dispersion. Here, the importance of the preparation route on the coating systems performance was in...

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Published in	Journal of applied polymer science Vol. 137; no. 38
Main Authors	Hou, Weixin, Gao, Ya, Wang, John, Blackwood, Daniel J., Teo, Serena
Format	Journal Article
Language	English
Published	Hoboken, USA John Wiley & Sons, Inc 10.10.2020 Wiley Subscription Services, Inc
Subjects	adhesives Coatings composites Corrosion Curing agents Diamines Dispersion Functional groups glass transition Graphene Hydrophobicity Materials science Polymers Solvents thermogravimetric analysis Xylene
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Abstract	Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with different functional groups to achieve better dispersion. Here, the importance of the preparation route on the coating systems performance was investigated. It was found that a mixed polar/nonpolar solvent BuOH/xylene (3/1 vol/vol) was the best choice for forming the epoxy/GO coatings. Furthermore, it was found that when the freeze‐dried GO sonicated with the curing agent trimethylhexamethylene diamine in the mix solvent, the as‐prepared coating exhibited best performance, including better GO dispersion and hydrophobicity, higher adhesion, and anti‐corrosion property. Without any additional chemical to modify the GO, this optimized preparation route for epoxy/GO coatings will provide a guide for future similar research works, especially for the GO dispersion in nonaqueous systems. GO dispersion in epoxy/GO coatings prepared by different routes.
AbstractList	Abstract Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with different functional groups to achieve better dispersion. Here, the importance of the preparation route on the coating systems performance was investigated. It was found that a mixed polar/nonpolar solvent BuOH/xylene (3/1 vol/vol) was the best choice for forming the epoxy/GO coatings. Furthermore, it was found that when the freeze‐dried GO sonicated with the curing agent trimethylhexamethylene diamine in the mix solvent, the as‐prepared coating exhibited best performance, including better GO dispersion and hydrophobicity, higher adhesion, and anti‐corrosion property. Without any additional chemical to modify the GO, this optimized preparation route for epoxy/GO coatings will provide a guide for future similar research works, especially for the GO dispersion in nonaqueous systems. Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with different functional groups to achieve better dispersion. Here, the importance of the preparation route on the coating systems performance was investigated. It was found that a mixed polar/nonpolar solvent BuOH/xylene (3/1 vol/vol) was the best choice for forming the epoxy/GO coatings. Furthermore, it was found that when the freeze‐dried GO sonicated with the curing agent trimethylhexamethylene diamine in the mix solvent, the as‐prepared coating exhibited best performance, including better GO dispersion and hydrophobicity, higher adhesion, and anti‐corrosion property. Without any additional chemical to modify the GO, this optimized preparation route for epoxy/GO coatings will provide a guide for future similar research works, especially for the GO dispersion in nonaqueous systems. GO dispersion in epoxy/GO coatings prepared by different routes. Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with different functional groups to achieve better dispersion. Here, the importance of the preparation route on the coating systems performance was investigated. It was found that a mixed polar/nonpolar solvent BuOH/xylene (3/1 vol/vol) was the best choice for forming the epoxy/GO coatings. Furthermore, it was found that when the freeze‐dried GO sonicated with the curing agent trimethylhexamethylene diamine in the mix solvent, the as‐prepared coating exhibited best performance, including better GO dispersion and hydrophobicity, higher adhesion, and anti‐corrosion property. Without any additional chemical to modify the GO, this optimized preparation route for epoxy/GO coatings will provide a guide for future similar research works, especially for the GO dispersion in nonaqueous systems.
Author	Gao, Ya Wang, John Teo, Serena Blackwood, Daniel J. Hou, Weixin
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Snippet	Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO with... Abstract Graphene oxide (GO) reinforcement to enhance the property of epoxy has been reported many times; with most of the papers focusing on how to modify GO...
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SubjectTerms	adhesives Coatings composites Corrosion Curing agents Diamines Dispersion Functional groups glass transition Graphene Hydrophobicity Materials science Polymers Solvents thermogravimetric analysis Xylene
Title	Freeze‐dried graphene oxide modified with trimethylhexamethylene in the mix solvent for improved anti‐corrosion property of epoxy
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