Nanotribological behavior of diamond surfaces using molecular dynamics with fractal theory and experiments

Jen Fin Lin; Te Hua Fang; Cheng Da Wu; Ko Han Houng

doi:10.1016/j.cap.2009.06.004

Nanotribological behavior of diamond surfaces using molecular dynamics with fractal theory and experiments

Jen Fin Lin, Te Hua Fang, Cheng Da Wu, Ko Han Houng

機械工程學系

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11 引文斯高帕斯（Scopus）

摘要

The frictional and indented behavior of a diamond asperity on a diamond plate was carried out using a molecular dynamics (MD) and experiments. The contact load, contact area, dynamic frictional force, and dynamic frictional coefficient increased as the contact interference increased at a constant loading velocity. The microcontact and frictional behavior can be evaluated between a rigid smooth hemisphere to a deformable rough flat plane by combined the deformed behavior of the asperity obtained from MD results with the fractal and statistic parameters. The comparison and the discrepancy of simulated results and nanoindentation and scratching experimental results will be discussed. Crown

原文	English
頁（從 - 到）	266-271
頁數	6
期刊	Current Applied Physics
卷	10
發行號	1
DOIs	https://doi.org/10.1016/j.cap.2009.06.004
出版狀態	Published - 2010 1月

All Science Journal Classification (ASJC) codes

材料科學(全部)
物理與天文學 (全部)

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10.1016/j.cap.2009.06.004

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abstract = "The frictional and indented behavior of a diamond asperity on a diamond plate was carried out using a molecular dynamics (MD) and experiments. The contact load, contact area, dynamic frictional force, and dynamic frictional coefficient increased as the contact interference increased at a constant loading velocity. The microcontact and frictional behavior can be evaluated between a rigid smooth hemisphere to a deformable rough flat plane by combined the deformed behavior of the asperity obtained from MD results with the fractal and statistic parameters. The comparison and the discrepancy of simulated results and nanoindentation and scratching experimental results will be discussed. Crown",

author = "Lin, {Jen Fin} and Fang, {Te Hua} and Wu, {Cheng Da} and Houng, {Ko Han}",

note = "Funding Information: The authors gratefully acknowledge the support of this research by the National Science Council of Taiwan, under Grant Nos. NSC 95-2221-E150-033 and NSC 95-2221-E150-066. Copyright: Copyright 2009 Elsevier B.V., All rights reserved.",

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AU - Lin, Jen Fin

AU - Fang, Te Hua

AU - Wu, Cheng Da

AU - Houng, Ko Han

N1 - Funding Information: The authors gratefully acknowledge the support of this research by the National Science Council of Taiwan, under Grant Nos. NSC 95-2221-E150-033 and NSC 95-2221-E150-066. Copyright: Copyright 2009 Elsevier B.V., All rights reserved.

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N2 - The frictional and indented behavior of a diamond asperity on a diamond plate was carried out using a molecular dynamics (MD) and experiments. The contact load, contact area, dynamic frictional force, and dynamic frictional coefficient increased as the contact interference increased at a constant loading velocity. The microcontact and frictional behavior can be evaluated between a rigid smooth hemisphere to a deformable rough flat plane by combined the deformed behavior of the asperity obtained from MD results with the fractal and statistic parameters. The comparison and the discrepancy of simulated results and nanoindentation and scratching experimental results will be discussed. Crown

AB - The frictional and indented behavior of a diamond asperity on a diamond plate was carried out using a molecular dynamics (MD) and experiments. The contact load, contact area, dynamic frictional force, and dynamic frictional coefficient increased as the contact interference increased at a constant loading velocity. The microcontact and frictional behavior can be evaluated between a rigid smooth hemisphere to a deformable rough flat plane by combined the deformed behavior of the asperity obtained from MD results with the fractal and statistic parameters. The comparison and the discrepancy of simulated results and nanoindentation and scratching experimental results will be discussed. Crown

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Nanotribological behavior of diamond surfaces using molecular dynamics with fractal theory and experiments

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