Erosive wear resistance of NCD coatings produced by pulsed microwave discharges
authors Almeida, FA; Derkaoui, N; Oliveira, FJ; Benedic, F; Silva, RF; Gicquel, A
nationality International
journal DIAMOND AND RELATED MATERIALS
author keywords Erosive wear; Adhesion; Nanocrystalline diamond; Pulsed microwave discharge
keywords NANOCRYSTALLINE DIAMOND FILMS; SOLID PARTICLE EROSION; CVD; DEPOSITION; CARBIDE
abstract Erosion tests on nanocrystalline diamond (NCD) films are relevant not only for the evaluation of the erosive wear resistance, anticipating applications where coated materials are exposed to particle impacts, but also as a way to evaluate their adhesion to the substrates. NCD films were grown on Si(3)N(4) ceramic by microwave plasma assisted deposition in continuous (CW) and pulsed (PW-50 Hz and PW-500 Hz) discharge modes in argon-rich gas mixture. The films grown in PW modes presented lower crystallite size and lower surface roughness than those grown in CW one, while the use of CF(4) plasma pre-treatment of the substrate lead to further film homogeneity. The erosive wear resistance of NCD was evaluated by solid particle impact using SiC (45-250 mu m size) as erodent material, with selected parameters accordingly to Hertzian stress field calculations. Film weight loss was undetectable until delamination took place. When tested with 150 mu m SiC particles, the CF(4) plasma pre-treated substrates yield a three-fold increase (15 min) in delamination time comparing to untreated specimens, while samples coated under PW-50 Hz conditions presented a six times lower erosion rate compared to CW ones. It is believed that the improved nucleation behaviour by the use of PW mode and its higher homogeneity on the CF(4) plasma pre-treated samples decrease the flaw population on the diamond/substrate interface, leading to improved adhesion levels. (C) 2009 Elsevier B.V. All rights reserved.
publisher ELSEVIER SCIENCE SA
issn 0925-9635
year published 2010
volume 19
issue 5-6
beginning page 484
ending page 488
digital object identifier (doi) 10.1016/j.diamond.2009.10.026
web of science category Materials Science, Multidisciplinary
subject category Materials Science
unique article identifier WOS:000278193600027
  ciceco authors
  impact metrics
times cited (wos core): 3
journal impact factor (jcr 2016): 2.561
5 year journal impact factor (jcr 2016): 2.103
category normalized journal impact factor percentile (jcr 2016): 67.091
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