4.7 Article

Residual stress and tribological behavior of hydrogen-free Al-DLC films prepared by HiPIMS under different bias voltages

Journal

SURFACE & COATINGS TECHNOLOGY
Volume 445, Issue -, Pages -

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.surfcoat.2022.128713

Keywords

DLC film; bias voltage; HiPIMS; sp(3) bonds; Residual stress

Funding

  1. National Natural Science Foundation of China [52101081]
  2. Guangdong Special Support Program [2019BT02C629]
  3. Science and Technology Programs of Guangdong Province [2021A1515010692]
  4. Science and Technology Programs of Guangzhou [202007020008]
  5. Young Talent Support Project of Guangzhou Association for Science and Technology [QT20220101145]

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Hydrogen-free Al-DLC films were prepared using HiPIMS technology under different bias voltages, and the influences of substrate bias voltage on the film properties were studied. The results showed that bias voltage reduced film roughness, increased film disorder and the content of sp(3) bonds. Furthermore, residual stress and film hardness were also affected by the substrate bias voltage.
Hydrogen-free Al-DLC films were prepared by HiPIMS technology under different bias voltages through an Al-C composite target. Surface and cross-sectional morphologies, chemical composition, microphase structure and bonding state, residual stress, hardness and elastic modulus, friction coefficient and wear resistance of Al-DLC films were investigated to study the influences of substrate bias voltage. Results show that bias voltage decreased film roughness (Ra) from 3.83 nm to 1.16 nm through ion bombardment. The increase of negative bias voltage improved film disorder and altered the content of sp(3) bonds. However, the existence of sp(3) bonds should not be responsible for residual stress. Local distortions generated by film disorder together with the mismatch between film and substrate give rise to residual compressive stress in Al-DLC films. Film hardness is in the range of 10 GPa to 17 GPa which is affected by the content of sp(3) bonds and film disorder. The lowest wear rate of Al-DLC film is 6.07 x 10(-8) mm(3)/Nm. Besides graphitization, friction can also generate more sp(3) bonds at wear interface between Al-DLC film and the counterpart ball.

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