C-Al2O3 coatings prepared by cathode plasma electrolytic deposition on TC4 substrate for better high temperature oxidation resistance

The Al2O3 coating prepared by cathode plasma electrolytic deposition (CPED) method usually has porous structure, which is not conductive to its application in the field of high temperature oxidation resistance. In this paper, carbon doped Al2O3 (C-Al2O3) coatings were prepared by adding glycerol to...

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Published inSurface & coatings technology Vol. 405; p. 126585
Main Authors Zhang, Shuguang, Zhao, Chao, Zhang, Jin, Lian, Yong, He, Yedong
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 15.01.2021
Elsevier BV
Subjects
Aluminum oxide
C-Al2O3 coatings
Carbon
Cathode plasma electrolytic deposition
Cathodes
Cathodic coating (process)
Coatings
Decrease porosity
Doping
Electrical resistivity
Electrodeposition
Electrolytes
First principles
Glycerol
High temperature
High temperature oxidation resistance
Oxidation
Oxidation resistance
Oxidation tests
Porosity
Substrates
X ray photoelectron spectroscopy
Cathode plasma electrolytic deposition
Glycerol
High temperature oxidation resistance
Decrease porosity
C-Al2O3 coatings
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Abstract The Al2O3 coating prepared by cathode plasma electrolytic deposition (CPED) method usually has porous structure, which is not conductive to its application in the field of high temperature oxidation resistance. In this paper, carbon doped Al2O3 (C-Al2O3) coatings were prepared by adding glycerol to the electrolytes, and coatings with reduced porosity and better high temperature oxidation resistance were obtained. SEM, EDS, XRD, XPS, high temperature oxidation test and first-principles calculation were used to study the structures and performances of the coatings. The results show that by adding glycerol to the electrolytes, the porosity of the obtained coatings is reduced. The doping of carbon (C) causes the XRD peaks of Al2O3 and XPS spectrum of Al2p and O1s.to shift to the left. The decrease in porosity is closely related to the increase in electrical conductivity of the coating caused by the doping of C, which reduces the band-gap of Al2O3. The coating with low C content shows the best high temperature oxidation resistance, while high C content coatings exhibit poorer high temperature oxidation resistance. Related mechanism is disclosed in the paper. •C-Al2O3 coatings were deposited onto TC4 by CPED using glycerol as carbon source.•The presence of C leaded to a decreased porosity of the coatings.•Coatings with low C content showed the best high temperature oxidation resistance.
AbstractList The Al2O3 coating prepared by cathode plasma electrolytic deposition (CPED) method usually has porous structure, which is not conductive to its application in the field of high temperature oxidation resistance. In this paper, carbon doped Al2O3 (C-Al2O3) coatings were prepared by adding glycerol to the electrolytes, and coatings with reduced porosity and better high temperature oxidation resistance were obtained. SEM, EDS, XRD, XPS, high temperature oxidation test and first-principles calculation were used to study the structures and performances of the coatings. The results show that by adding glycerol to the electrolytes, the porosity of the obtained coatings is reduced. The doping of carbon (C) causes the XRD peaks of Al2O3 and XPS spectrum of Al2p and O1s.to shift to the left. The decrease in porosity is closely related to the increase in electrical conductivity of the coating caused by the doping of C, which reduces the band-gap of Al2O3. The coating with low C content shows the best high temperature oxidation resistance, while high C content coatings exhibit poorer high temperature oxidation resistance. Related mechanism is disclosed in the paper.
The Al2O3 coating prepared by cathode plasma electrolytic deposition (CPED) method usually has porous structure, which is not conductive to its application in the field of high temperature oxidation resistance. In this paper, carbon doped Al2O3 (C-Al2O3) coatings were prepared by adding glycerol to the electrolytes, and coatings with reduced porosity and better high temperature oxidation resistance were obtained. SEM, EDS, XRD, XPS, high temperature oxidation test and first-principles calculation were used to study the structures and performances of the coatings. The results show that by adding glycerol to the electrolytes, the porosity of the obtained coatings is reduced. The doping of carbon (C) causes the XRD peaks of Al2O3 and XPS spectrum of Al2p and O1s.to shift to the left. The decrease in porosity is closely related to the increase in electrical conductivity of the coating caused by the doping of C, which reduces the band-gap of Al2O3. The coating with low C content shows the best high temperature oxidation resistance, while high C content coatings exhibit poorer high temperature oxidation resistance. Related mechanism is disclosed in the paper. •C-Al2O3 coatings were deposited onto TC4 by CPED using glycerol as carbon source.•The presence of C leaded to a decreased porosity of the coatings.•Coatings with low C content showed the best high temperature oxidation resistance.
ArticleNumber 126585
Author He, Yedong
Zhang, Jin
Lian, Yong
Zhang, Shuguang
Zhao, Chao
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Keywords Cathode plasma electrolytic deposition
Glycerol
High temperature oxidation resistance
Decrease porosity
C-Al2O3 coatings
Language English
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Snippet The Al2O3 coating prepared by cathode plasma electrolytic deposition (CPED) method usually has porous structure, which is not conductive to its application in...
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StartPage 126585
SubjectTerms Aluminum oxide
C-Al2O3 coatings
Carbon
Cathode plasma electrolytic deposition
Cathodes
Cathodic coating (process)
Coatings
Decrease porosity
Doping
Electrical resistivity
Electrodeposition
Electrolytes
First principles
Glycerol
High temperature
High temperature oxidation resistance
Oxidation
Oxidation resistance
Oxidation tests
Porosity
Substrates
X ray photoelectron spectroscopy
Title C-Al2O3 coatings prepared by cathode plasma electrolytic deposition on TC4 substrate for better high temperature oxidation resistance
URI https://dx.doi.org/10.1016/j.surfcoat.2020.126585
https://www.proquest.com/docview/2481935230
Volume 405
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