Tailoring microstructure and phase segregation for low friction carbon-based nanocomposite coatings
Tailoring microstructure and phase segregation for low friction carbon-based nanocomposite coatings
Friction has a direct relation with the energy efficiency and environmental cleanliness in all moving mechanical systems. To develop low friction coatings is extremely beneficial for preserving not only our limited energy resources but also the earth’s environment. This study proposes a new design for low friction carbon-based nanocomposite coatings by tailoring the microstructure and phase segregation,and thereby it contributes to better controlling the mechanical and tribological properties. Experimental findings and theoretical calculations reveal that high-hardness (18.2 GPa), high-adhesion strength (28 N) as well as low-internal stress (-0.8 GPa) can be achieved by a nanocrystallite/amorphous microstructure architecture for the nc-WC/a-C(Al) carbon-based nanocomposite coating;in particular low friction (~0.05) can be acquired by creating a strong thermodynamic driving force to promote phase segregation of graphitic carbon from the a-C structure so as to form a low shear strength graphitic tribo-layer on the friction contact surfaces. This design concept is general and has been successfully employed to fabricate a wide class of low friction carbon-based nanocomposite coatings
15782-15792
Zhou, Shengguo
02793824-a60e-481e-ae6e-55f2ab48e739
Wang, Liping
ef5828b8-d874-42db-bb25-713890281af2
Wang, S.C.
8a390e2d-6552-4c7c-a88f-25bf9d6986a6
Wood, R.J.K.
d9523d31-41a8-459a-8831-70e29ffe8a73
Xue, Qunji
7614cf46-0701-4942-bfcf-3d480aa3537a
2012
Zhou, Shengguo
02793824-a60e-481e-ae6e-55f2ab48e739
Wang, Liping
ef5828b8-d874-42db-bb25-713890281af2
Wang, S.C.
8a390e2d-6552-4c7c-a88f-25bf9d6986a6
Wood, R.J.K.
d9523d31-41a8-459a-8831-70e29ffe8a73
Xue, Qunji
7614cf46-0701-4942-bfcf-3d480aa3537a
Zhou, Shengguo, Wang, Liping, Wang, S.C., Wood, R.J.K. and Xue, Qunji
(2012)
Tailoring microstructure and phase segregation for low friction carbon-based nanocomposite coatings.
Journal of Materials Chemistry, 31, .
(doi:10.1039/C2JM30918A).
Abstract
Friction has a direct relation with the energy efficiency and environmental cleanliness in all moving mechanical systems. To develop low friction coatings is extremely beneficial for preserving not only our limited energy resources but also the earth’s environment. This study proposes a new design for low friction carbon-based nanocomposite coatings by tailoring the microstructure and phase segregation,and thereby it contributes to better controlling the mechanical and tribological properties. Experimental findings and theoretical calculations reveal that high-hardness (18.2 GPa), high-adhesion strength (28 N) as well as low-internal stress (-0.8 GPa) can be achieved by a nanocrystallite/amorphous microstructure architecture for the nc-WC/a-C(Al) carbon-based nanocomposite coating;in particular low friction (~0.05) can be acquired by creating a strong thermodynamic driving force to promote phase segregation of graphitic carbon from the a-C structure so as to form a low shear strength graphitic tribo-layer on the friction contact surfaces. This design concept is general and has been successfully employed to fabricate a wide class of low friction carbon-based nanocomposite coatings
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JMC-2012.pdf
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Published date: 2012
Organisations:
nCATS Group
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Local EPrints ID: 343480
URI: http://eprints.soton.ac.uk/id/eprint/343480
PURE UUID: 3d1cfbe5-d0bc-4875-88f4-f243526cd34a
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Date deposited: 05 Oct 2012 13:33
Last modified: 15 Mar 2024 02:47
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Author:
Shengguo Zhou
Author:
Liping Wang
Author:
Qunji Xue
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