Graphene oxide gluing layer enabling macroscale tribology applications of pristine graphene

Mingi Choi; Ivan V. Vlassiouk; Won Seok Kim; Jeong Han Kim; Anirudha V. Sumant; Ji Woong Jang; Junho Suh; Young Jun Jang; Songkil Kim

doi:10.26599/FRICT.2025.9441092

Graphene oxide gluing layer enabling macroscale tribology applications of pristine graphene

Mingi Choi
, Ivan V. Vlassiouk
, Won Seok Kim
, Jeong Han Kim
, Anirudha V. Sumant
, Ji Woong Jang
, Junho Suh
, Young Jun Jang
, Songkil Kim

Functional Hybrid Nanomaterials

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

Abstract

In recent studies of two-dimensional (2D) nanomaterial-based solid lubricants, the importance of durability has been emerging for real engineering-scale applications. To achieve this, a transfer layer formation is essential to prevent the wear of the mechanical systems. However, it has been challenging for pristine graphene (PG) to induce a material transfer due to chemical inertness. In this study, we suggest an easy-to-process strategy to promote the huge material transfer of the PG onto the counterpart contacting material. We utilized graphene oxide (GO) as a gluing layer between the PG film and the counterpart contact surface to realize the superior tribological performance. The high interaction energy of the GO from its functional groups makes a contribution to the material transfer of PG, which is unveiled by a systematic analysis of the counterpart contact surface and the wear track. The huge solid transfer layer not only makes a wear-resistant contact interface between the transfer layer and the underlying film by densification and oxidation, but also reduces surface interaction energies, finally resulting in a significant improvement in durability.

Original language	English
Article number	9441092
Journal	Friction
Volume	13
Issue number	10
DOIs	https://doi.org/10.26599/FRICT.2025.9441092
State	Published - Oct 2025

Funding

This research was supported by the National Research Foundation of Korea (NRF) Global Basic Research Laboratory grant funded by the Korea government (MSIT) (No. RS-2025-02216195) and by the Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Korea government (MOTIE) (No.20214000000140). Work performed at the Center for Nanoscale Materials, a U.S. Department of Energy Office of Science User Facility, was supported by the U.S. DOE, Office of Basic Energy Sciences, under Contract No. DE-AC02-06CH11357. It was partially supported by 2022 BK21 FOUR Program of Pusan National University. This research was conducted using the atomic force microscope, tribometer, and scanning electron microscope at the PNU Hybrid Innovative Manufacturing Engineering Center, which is the NFEC Core Facility supported by Korea Basic Science Institute.

Keywords

graphene oxide (GO)
macroscale tribology
pristine graphene (PG)
solid lubrication
transfer layer

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10.26599/FRICT.2025.9441092

Cite this

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title = "Graphene oxide gluing layer enabling macroscale tribology applications of pristine graphene",

abstract = "In recent studies of two-dimensional (2D) nanomaterial-based solid lubricants, the importance of durability has been emerging for real engineering-scale applications. To achieve this, a transfer layer formation is essential to prevent the wear of the mechanical systems. However, it has been challenging for pristine graphene (PG) to induce a material transfer due to chemical inertness. In this study, we suggest an easy-to-process strategy to promote the huge material transfer of the PG onto the counterpart contacting material. We utilized graphene oxide (GO) as a gluing layer between the PG film and the counterpart contact surface to realize the superior tribological performance. The high interaction energy of the GO from its functional groups makes a contribution to the material transfer of PG, which is unveiled by a systematic analysis of the counterpart contact surface and the wear track. The huge solid transfer layer not only makes a wear-resistant contact interface between the transfer layer and the underlying film by densification and oxidation, but also reduces surface interaction energies, finally resulting in a significant improvement in durability.",

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AU - Sumant, Anirudha V.

AU - Jang, Ji Woong

AU - Suh, Junho

AU - Jang, Young Jun

AU - Kim, Songkil

N1 - Publisher Copyright: © The Author(s) 2025.

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N2 - In recent studies of two-dimensional (2D) nanomaterial-based solid lubricants, the importance of durability has been emerging for real engineering-scale applications. To achieve this, a transfer layer formation is essential to prevent the wear of the mechanical systems. However, it has been challenging for pristine graphene (PG) to induce a material transfer due to chemical inertness. In this study, we suggest an easy-to-process strategy to promote the huge material transfer of the PG onto the counterpart contacting material. We utilized graphene oxide (GO) as a gluing layer between the PG film and the counterpart contact surface to realize the superior tribological performance. The high interaction energy of the GO from its functional groups makes a contribution to the material transfer of PG, which is unveiled by a systematic analysis of the counterpart contact surface and the wear track. The huge solid transfer layer not only makes a wear-resistant contact interface between the transfer layer and the underlying film by densification and oxidation, but also reduces surface interaction energies, finally resulting in a significant improvement in durability.

AB - In recent studies of two-dimensional (2D) nanomaterial-based solid lubricants, the importance of durability has been emerging for real engineering-scale applications. To achieve this, a transfer layer formation is essential to prevent the wear of the mechanical systems. However, it has been challenging for pristine graphene (PG) to induce a material transfer due to chemical inertness. In this study, we suggest an easy-to-process strategy to promote the huge material transfer of the PG onto the counterpart contacting material. We utilized graphene oxide (GO) as a gluing layer between the PG film and the counterpart contact surface to realize the superior tribological performance. The high interaction energy of the GO from its functional groups makes a contribution to the material transfer of PG, which is unveiled by a systematic analysis of the counterpart contact surface and the wear track. The huge solid transfer layer not only makes a wear-resistant contact interface between the transfer layer and the underlying film by densification and oxidation, but also reduces surface interaction energies, finally resulting in a significant improvement in durability.

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Graphene oxide gluing layer enabling macroscale tribology applications of pristine graphene

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