In-situ TEM studies on stick-slip friction characters of sp2 nanocrystallited carbon films

Fan, Xue; Hu, Zelong; Huang, Wenchao

doi:10.1007/s40544-021-0551-z

Cited by 7 publications

(1 citation statement)

References 50 publications

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“…However, due to the structural characteristics of graphene, friction studies for graphene are mainly at the nanoscale. − As the research scale becomes smaller, the details of friction changes are more prominent, and many friction behaviors that cannot be observed in macroscopic friction are found. , Among them, the stick–slip behavior is a common phenomenon in graphene nanofriction, and scholars have proposed the P–T model to explain this behavior . In the nanofriction of graphene on a silicon oxide substrate, Lee et al first observed the friction-strengthening behavior of graphene in experiments and proposed the fold theory to explain this behavior.…”

Section: Introductionmentioning

confidence: 99%

Effect of Normal Load on the Nanofriction Behavior of Graphene on Stainless-Steel Substrate: Implication for Nanoscale Lubrication

Guo,

Bai,

Dou

et al. 2024

ACS Appl. Nano Mater.

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Graphene on a stainless steel substrate will appear as localized bulges, and these bulges will lead to large fluctuations in friction force, which is the key to influencing the lubrication efficiency of graphene. Here, the effect of normal load on the nanofriction behavior of the bulged graphene on a stainless steel substrate is investigated. In the normal load study interval from 20 to 110 nN, an increment of 10 nN of normal load can increase friction force the more the normal load increases, and the two are not linearly correlated. The friction force in the graphene bulge region consists of two parts: the first part originates from the interaction of the graphene material itself in contact with the tip, and the second part originates from the resistance due to the pileup of graphene deformation in front of the tip. The nonlinear correlation between the normal load and friction force is mainly related to the pile-up effect of bulged graphene. In addition, the friction force increase due to the graphene bulge region needs to go through a process, which is divided into two stages. The first stage is the increase in friction force due to the tip starting to contact the bulged graphene and the contact area increasing. The second stage is the increase in friction force due to the graphene regulating its configuration and repeatedly interacting with the tip. The normal load is linearly related to the first stage but not linearly related to the second stage. The nonlinear correlation between the normal load and friction force is mainly related to the second stage of friction force rise. Therefore, the change of normal load affects the stacking effect and the ability to regulate the configuration of bulged graphene, which leads to a nonlinear increase of friction force. This contributes to the application of graphene for nanolubrication of stainless-steel components in MEMS.

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Section: Introductionmentioning

confidence: 99%

Effect of Normal Load on the Nanofriction Behavior of Graphene on Stainless-Steel Substrate: Implication for Nanoscale Lubrication

Guo,

Bai,

Dou

et al. 2024

ACS Appl. Nano Mater.

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Phononic Friction in Monolayer/Bilayer Graphene

et al. 2022

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Metastable hybridized structure transformation in amorphous carbon films during friction—A study combining experiments and MD simulation

et al. 2023

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Amorphous carbon films have attracted substantial interest due to their exceptional mechanical and tribological properties. Previous studies revealed that the amorphous carbon films exhibited lower coefficient of friction (COF) because of the transformation in bond structure from sp3-C to sp2-C during friction processes. However, the mechanism for such a transformation during friction is not well understood. This study is conducted to get an insight into the metastable transformation in amorphous carbon film during friction by means of experiments and molecular dynamics (MD) simulation. Relevant wear tests showed that wear of the film changed from an abrasive wear mode to a mixture of abrasion and adhesive wear, resulting in a decrease in growth rate of the wear rate after the running-in stage. It is worth noting that the sp3-C atoms were increased during the running-in stage when the films contained lower sp3/sp2 ratios. However, the formed sp3-C atoms could only be short-lived and gradually transformed to sp2-C atoms with the graphitization generated on the wearing surface of the films. The radial distribution function and translational order parameter indicated that the films’ high sp3/sp2 ratio led to an increased sp2-C proportion on the wear scar after friction, which caused an increased structural ordering.

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In-situ TEM studies on stick-slip friction characters of sp2 nanocrystallited carbon films

Cited by 7 publications

References 50 publications

Effect of Normal Load on the Nanofriction Behavior of Graphene on Stainless-Steel Substrate: Implication for Nanoscale Lubrication

Effect of Normal Load on the Nanofriction Behavior of Graphene on Stainless-Steel Substrate: Implication for Nanoscale Lubrication

Phononic Friction in Monolayer/Bilayer Graphene

Metastable hybridized structure transformation in amorphous carbon films during friction—A study combining experiments and MD simulation

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