Mechanical property evaluation of ZrSiN films deposited by a hybrid superimposed high power impulse- medium frequency sputtering and RF sputtering system

Autor:	Bih-Show Lou, Jyh-Wei Lee, Yu-Chuan Wu, Zhen-Yu Chen, Qi-Lin Tang
Rok vydání:	2019
Předmět:	010302 applied physics Materials science 02 engineering and technology Surfaces and Interfaces General Chemistry engineering.material 021001 nanoscience & nanotechnology Condensed Matter Physics Microstructure 01 natural sciences Surfaces Coatings and Films Amorphous solid Solid solution strengthening Coating Sputtering 0103 physical sciences Materials Chemistry Surface roughness engineering Composite material High-power impulse magnetron sputtering 0210 nano-technology Power density
Zdroj:	Surface and Coatings Technology. 376:59-67
ISSN:	0257-8972
DOI:	10.1016/j.surfcoat.2018.03.103
Popis:	The high power impulse magnetron sputtering (HiPIMS) technique has been studied intensively due to its high peak power density and high ionization rate. The drawback, low deposition rate, of the HiPIMS can be improved by superimposing the middle-frequency (MF) pulses during the off-time of HiPIMS pulsing. In this study, a hybrid coating system consisting of a radio frequency power supply and a superimposed HiPIMS-MF sputtering system was used to deposit the ZrN and ZrSiN coatings with different Si contents ranging from 0 to 11.5 at.%. The Zr target surface status was maintained at the transition mode by a plasma emission monitoring system for keeping high deposition rate. The microstructure of ZrSiN film changed from a fine columnar to a featureless structure when the Si content was higher than 4.7 at.%. The maximum hardness of 33.4 GPa was obtained for the film containing 4.7 at.% Si due to the solid solution hardening and grain refinement strengthening effects. The film hardness further decreased to 20.9 GPa as the Si concentration increased to 11.5 at.%, which can be attributed to the formation of large amount of soft amorphous SiNx phase. On the other hand, the corrosion resistance of ZrSiN film increased with increasing Si content due to the effective reduction of grain size, lower surface roughness, and further densification of microstructure by amorphous SiNx phase. The corrosion resistance of AISI304 stainless steel substrate can be effectively improved to 8 to 15 times better by the ZrSiN coating. The 4.7 at.% Si contained ZrSiN coating had the highest hardness, good adhesion and corrosion resistance in this work.
Databáze:	OpenAIRE
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