Structural damage in graphene oxide coatings onto Nb substrates upon laser irradiation

R.V. Tolentino-Hernandez; F.A. Garcia-Pastor; H. Baez-Medina; E. Jimenez-Melero; F. Caballero-Briones

doi:10.1016/j.surfcoat.2021.128013

Structural damage in graphene oxide coatings onto Nb substrates upon laser irradiation

R.V. Tolentino-Hernandez, F.A. Garcia-Pastor, H. Baez-Medina, E. Jimenez-Melero, F. Caballero-Briones^*

^*Corresponding author for this work

Metallurgy and Materials

Research output: Contribution to journal › Article › peer-review

Abstract

In this work graphene oxide (GO) coatings were obtained on Nb substrates by electrophoretic deposition (EPD), using a ramp of stepped potential and variable deposition time, to evaluate the feasibility as a protective coating against the exposition to a 20 W Yb laser (1070 nm). Laser irradiation constitutes a first approximation to the potential damage by local high heat loads that could occur in a Tokamak-type fusion reactor. GO coatings can act as the first barrier against exposure to the fusion reactor plasma, but the coating may experience local high heat loads and simultaneous exposure to energetic particles. The GO/Nb coatings were irradiated with different laser power-frequency settings. With X-ray photoelectron spectroscopy, the bonding evolution of the coatings was followed for each deposition time. Scanning electron microscopy was used to evaluate the coating morphology before and after laser irradiation, whereas Raman spectroscopy was used to evaluate the structural evolution of GO coatings, crystallinity, and disorder in the graphene oxide. An increase of the crystallite size due to sp² restoration was observed for the films prepared up to 10 s/V. Atomic force microscopy was used to study the film morphology and to estimate the film thickness by comparing the z-offset between the substrate and coating topography images. Film thickness reduces from ca. 280 nm to 100 nm with the increase in the time at each voltage step. Coating tolerance against laser-induced damage was observed up to 34% of the full laser power, where the coating was damaged and local metal melting was observed. The coating damage occurs between 4.9 × 10⁸ MW/m² and 2.5 × 10⁹ MW/m² and higher power levels triggered the occurrence of melting in the metallic substrate. The reduction in laser damage is attributed to the enhanced thermal dissipation by the sp² dominion as the crystallite size increases. GO coatings prepared by electrophoresis are shown to be promising to protect nuclear components against damage for high heat loads.

Original language	English
Article number	128013
Number of pages	10
Journal	Surface and Coatings Technology
Volume	431
Early online date	24 Dec 2021
DOIs	https://doi.org/10.1016/j.surfcoat.2021.128013
Publication status	Published - 15 Feb 2022

Bibliographical note

Funding Information:
This work was financed through the CONACYT 40798 grant and SIP-IPN 2021-1513 project. R. V. Tolentino-Hernandez was financed by CONACYT and BEIFI-IPN grants. The authors thank Dr. Adrian Martinez-Rivas at CIC-IPN for the acquisition of SEM images; to MSc Alejandra Garcia-Sotelo at CINVESTAV Zacatenco for Raman measurements, to Ing. Wilian Cauich-Ruiz for the XPS measurements at the National Laboratory of Nano and Biomaterials (LANNBIO), funded by FOMIX-Yucatán and CONACYT and to S. A. Pacheco-Buendia for technical support in collecting the XRD diffractograms.

Publisher Copyright:
© 2021 Elsevier B.V.

Keywords

Electrophoretic deposition
Graphene oxide coatings
Laser irradiation
sp restoration
Substrate protection

ASJC Scopus subject areas

General Chemistry
Condensed Matter Physics
Surfaces and Interfaces
Surfaces, Coatings and Films
Materials Chemistry

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Cite this

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title = "Structural damage in graphene oxide coatings onto Nb substrates upon laser irradiation",

abstract = "In this work graphene oxide (GO) coatings were obtained on Nb substrates by electrophoretic deposition (EPD), using a ramp of stepped potential and variable deposition time, to evaluate the feasibility as a protective coating against the exposition to a 20 W Yb laser (1070 nm). Laser irradiation constitutes a first approximation to the potential damage by local high heat loads that could occur in a Tokamak-type fusion reactor. GO coatings can act as the first barrier against exposure to the fusion reactor plasma, but the coating may experience local high heat loads and simultaneous exposure to energetic particles. The GO/Nb coatings were irradiated with different laser power-frequency settings. With X-ray photoelectron spectroscopy, the bonding evolution of the coatings was followed for each deposition time. Scanning electron microscopy was used to evaluate the coating morphology before and after laser irradiation, whereas Raman spectroscopy was used to evaluate the structural evolution of GO coatings, crystallinity, and disorder in the graphene oxide. An increase of the crystallite size due to sp2 restoration was observed for the films prepared up to 10 s/V. Atomic force microscopy was used to study the film morphology and to estimate the film thickness by comparing the z-offset between the substrate and coating topography images. Film thickness reduces from ca. 280 nm to 100 nm with the increase in the time at each voltage step. Coating tolerance against laser-induced damage was observed up to 34% of the full laser power, where the coating was damaged and local metal melting was observed. The coating damage occurs between 4.9 × 108 MW/m2 and 2.5 × 109 MW/m2 and higher power levels triggered the occurrence of melting in the metallic substrate. The reduction in laser damage is attributed to the enhanced thermal dissipation by the sp2 dominion as the crystallite size increases. GO coatings prepared by electrophoresis are shown to be promising to protect nuclear components against damage for high heat loads.",

keywords = "Electrophoretic deposition, Graphene oxide coatings, Laser irradiation, sp restoration, Substrate protection",

author = "R.V. Tolentino-Hernandez and F.A. Garcia-Pastor and H. Baez-Medina and E. Jimenez-Melero and F. Caballero-Briones",

note = "Funding Information: This work was financed through the CONACYT 40798 grant and SIP-IPN 2021-1513 project. R. V. Tolentino-Hernandez was financed by CONACYT and BEIFI-IPN grants. The authors thank Dr. Adrian Martinez-Rivas at CIC-IPN for the acquisition of SEM images; to MSc Alejandra Garcia-Sotelo at CINVESTAV Zacatenco for Raman measurements, to Ing. Wilian Cauich-Ruiz for the XPS measurements at the National Laboratory of Nano and Biomaterials (LANNBIO), funded by FOMIX-Yucat{\'a}n and CONACYT and to S. A. Pacheco-Buendia for technical support in collecting the XRD diffractograms. Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",

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AU - Tolentino-Hernandez, R.V.

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AU - Jimenez-Melero, E.

AU - Caballero-Briones, F.

N1 - Funding Information: This work was financed through the CONACYT 40798 grant and SIP-IPN 2021-1513 project. R. V. Tolentino-Hernandez was financed by CONACYT and BEIFI-IPN grants. The authors thank Dr. Adrian Martinez-Rivas at CIC-IPN for the acquisition of SEM images; to MSc Alejandra Garcia-Sotelo at CINVESTAV Zacatenco for Raman measurements, to Ing. Wilian Cauich-Ruiz for the XPS measurements at the National Laboratory of Nano and Biomaterials (LANNBIO), funded by FOMIX-Yucatán and CONACYT and to S. A. Pacheco-Buendia for technical support in collecting the XRD diffractograms. Publisher Copyright: © 2021 Elsevier B.V.

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N2 - In this work graphene oxide (GO) coatings were obtained on Nb substrates by electrophoretic deposition (EPD), using a ramp of stepped potential and variable deposition time, to evaluate the feasibility as a protective coating against the exposition to a 20 W Yb laser (1070 nm). Laser irradiation constitutes a first approximation to the potential damage by local high heat loads that could occur in a Tokamak-type fusion reactor. GO coatings can act as the first barrier against exposure to the fusion reactor plasma, but the coating may experience local high heat loads and simultaneous exposure to energetic particles. The GO/Nb coatings were irradiated with different laser power-frequency settings. With X-ray photoelectron spectroscopy, the bonding evolution of the coatings was followed for each deposition time. Scanning electron microscopy was used to evaluate the coating morphology before and after laser irradiation, whereas Raman spectroscopy was used to evaluate the structural evolution of GO coatings, crystallinity, and disorder in the graphene oxide. An increase of the crystallite size due to sp2 restoration was observed for the films prepared up to 10 s/V. Atomic force microscopy was used to study the film morphology and to estimate the film thickness by comparing the z-offset between the substrate and coating topography images. Film thickness reduces from ca. 280 nm to 100 nm with the increase in the time at each voltage step. Coating tolerance against laser-induced damage was observed up to 34% of the full laser power, where the coating was damaged and local metal melting was observed. The coating damage occurs between 4.9 × 108 MW/m2 and 2.5 × 109 MW/m2 and higher power levels triggered the occurrence of melting in the metallic substrate. The reduction in laser damage is attributed to the enhanced thermal dissipation by the sp2 dominion as the crystallite size increases. GO coatings prepared by electrophoresis are shown to be promising to protect nuclear components against damage for high heat loads.

AB - In this work graphene oxide (GO) coatings were obtained on Nb substrates by electrophoretic deposition (EPD), using a ramp of stepped potential and variable deposition time, to evaluate the feasibility as a protective coating against the exposition to a 20 W Yb laser (1070 nm). Laser irradiation constitutes a first approximation to the potential damage by local high heat loads that could occur in a Tokamak-type fusion reactor. GO coatings can act as the first barrier against exposure to the fusion reactor plasma, but the coating may experience local high heat loads and simultaneous exposure to energetic particles. The GO/Nb coatings were irradiated with different laser power-frequency settings. With X-ray photoelectron spectroscopy, the bonding evolution of the coatings was followed for each deposition time. Scanning electron microscopy was used to evaluate the coating morphology before and after laser irradiation, whereas Raman spectroscopy was used to evaluate the structural evolution of GO coatings, crystallinity, and disorder in the graphene oxide. An increase of the crystallite size due to sp2 restoration was observed for the films prepared up to 10 s/V. Atomic force microscopy was used to study the film morphology and to estimate the film thickness by comparing the z-offset between the substrate and coating topography images. Film thickness reduces from ca. 280 nm to 100 nm with the increase in the time at each voltage step. Coating tolerance against laser-induced damage was observed up to 34% of the full laser power, where the coating was damaged and local metal melting was observed. The coating damage occurs between 4.9 × 108 MW/m2 and 2.5 × 109 MW/m2 and higher power levels triggered the occurrence of melting in the metallic substrate. The reduction in laser damage is attributed to the enhanced thermal dissipation by the sp2 dominion as the crystallite size increases. GO coatings prepared by electrophoresis are shown to be promising to protect nuclear components against damage for high heat loads.

KW - Electrophoretic deposition

KW - Graphene oxide coatings

KW - Laser irradiation

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KW - Substrate protection

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DO - 10.1016/j.surfcoat.2021.128013

M3 - Article

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ER -

Structural damage in graphene oxide coatings onto Nb substrates upon laser irradiation

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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