A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet

A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet

This study aims on the dynamic and tribological characterization of a Single Layer Graphene Sheet (SLGS) including the effects of a graphene cantilever’s deflection. A 10 x 10 nm graphene model is developed, which is modally analyzed for both Zigzag and Armchair lattices. A typical Atomic Force Micr...

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Main Authors: Grigoriadis Kyriakos, Palaiologos Alexandros, Zavos Anastasios, Nikolakopoulos Pantelis G.
Format: Article
Language:English
Published: EDP Sciences 2018-01-01
Series:MATEC Web of Conferences
Online Access:https://doi.org/10.1051/matecconf/201818801029
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spelling doaj-a80794e1d87042bda9acb7018c1aee8d2021-02-02T08:07:33ZengEDP SciencesMATEC Web of Conferences2261-236X2018-01-011880102910.1051/matecconf/201818801029matecconf_iceaf-v2018_01029A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene SheetGrigoriadis KyriakosPalaiologos AlexandrosZavos AnastasiosNikolakopoulos Pantelis G.This study aims on the dynamic and tribological characterization of a Single Layer Graphene Sheet (SLGS) including the effects of a graphene cantilever’s deflection. A 10 x 10 nm graphene model is developed, which is modally analyzed for both Zigzag and Armchair lattices. A typical Atomic Force Microscope (AFM) cantilever with carbon coated tip is also modeled during the simulation. The friction forces applied on the tip during its movement can be evaluated. The real contact area is characterized as the carbon atom tip is interlinked with the graphene atoms via the Lennard-Jones model. This study confirmed that the deformation of the AFM cantilever, is important to predict more accurately the tribological behaviour of graphene and the effect of its lattice orientation to its frictional properties. Therefore, this simulation provides an interesting way to understand the complex interaction between the cantilever tip and the sample in different contact conditions.https://doi.org/10.1051/matecconf/201818801029
collection DOAJ
language English
format Article
sources DOAJ
author Grigoriadis Kyriakos
Palaiologos Alexandros
Zavos Anastasios
Nikolakopoulos Pantelis G.
spellingShingle Grigoriadis Kyriakos
Palaiologos Alexandros
Zavos Anastasios
Nikolakopoulos Pantelis G.
A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
MATEC Web of Conferences
author_facet Grigoriadis Kyriakos
Palaiologos Alexandros
Zavos Anastasios
Nikolakopoulos Pantelis G.
author_sort Grigoriadis Kyriakos
title A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
title_short A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
title_full A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
title_fullStr A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
title_full_unstemmed A Tribological Simulation for a Typical Carbon Coated AFM Cantilever Interacting with a Monolayer Graphene Sheet
title_sort tribological simulation for a typical carbon coated afm cantilever interacting with a monolayer graphene sheet
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2018-01-01
description This study aims on the dynamic and tribological characterization of a Single Layer Graphene Sheet (SLGS) including the effects of a graphene cantilever’s deflection. A 10 x 10 nm graphene model is developed, which is modally analyzed for both Zigzag and Armchair lattices. A typical Atomic Force Microscope (AFM) cantilever with carbon coated tip is also modeled during the simulation. The friction forces applied on the tip during its movement can be evaluated. The real contact area is characterized as the carbon atom tip is interlinked with the graphene atoms via the Lennard-Jones model. This study confirmed that the deformation of the AFM cantilever, is important to predict more accurately the tribological behaviour of graphene and the effect of its lattice orientation to its frictional properties. Therefore, this simulation provides an interesting way to understand the complex interaction between the cantilever tip and the sample in different contact conditions.
url https://doi.org/10.1051/matecconf/201818801029
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