Modulation effect on mechanical properties of nanolayered MoN/MoSiN coatings

The combination of molybdenum nitride, MoN, and molybdenum silicon nitride, MoSiN, to be a naolayered MoN/MoSiN film was developed by the reactive radio frequency, r.f., magnetron sputtering system. The MoN and MoSiN building layers were designed and fabricated with a crystalline and an amorphous/na...

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Veröffentlicht in:	Surface & coatings technology 2022-04, Vol.436, p.128278, Article 128278
Hauptverfasser:	Liang, Bing-Hao, Hsieu, Fu-Shen, Wu, Fan-Bean
Format:	Artikel
Sprache:	eng
Schlagworte:	Coatings Crystal structure Crystallinity Magnetron sputtering Mechanical properties Modulation Modulus of elasticity Molybdenum MoN MoSiN Nanocrystals Nanolayer Scratch resistance Silicon nitride Thickness ratio Wear Wear resistance
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creator	Liang, Bing-Hao Hsieu, Fu-Shen Wu, Fan-Bean
description	The combination of molybdenum nitride, MoN, and molybdenum silicon nitride, MoSiN, to be a naolayered MoN/MoSiN film was developed by the reactive radio frequency, r.f., magnetron sputtering system. The MoN and MoSiN building layers were designed and fabricated with a crystalline and an amorphous/nanocrystalline feature, respectively. The effect of thickness modulation of the c-MoN and a-MoSiN layers on microstructure and mechanical properties of the MoN/MoSiN coatings were investigated. With a fixed 50.0 nm crystallines MoN building layer, the amorphous/nanocrystalline MoSiN building layer with a designed thickness of 25.0 nm would suppress the continuous growth of crystalline phases. For mechanical characterization, the change in modulation did not lead to significant influence on hardness and Young's modulus. When a large thickness ratio of c-MoN/a-MoSiN was applied, phenomenal increase in scratch and wear resistance was observed due to higher volumetric ratio of hard crystalline MoN layer and discontinuity of crystalline phase growth through building layers in the nanolayered MoN/MoSiN coatings. •Nanolayered crystalline MoN/amorphous MoSiN coatings are produced.•Modulation of the c-MoN/a-MoSiN is tuned from 50.0/50.0 to 50.0/12.5.•Coatign with high c-MoN ratio and discontinuity of crystalline phase shows superior mechanical properties.
doi_str_mv	10.1016/j.surfcoat.2022.128278
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When a large thickness ratio of c-MoN/a-MoSiN was applied, phenomenal increase in scratch and wear resistance was observed due to higher volumetric ratio of hard crystalline MoN layer and discontinuity of crystalline phase growth through building layers in the nanolayered MoN/MoSiN coatings. •Nanolayered crystalline MoN/amorphous MoSiN coatings are produced.•Modulation of the c-MoN/a-MoSiN is tuned from 50.0/50.0 to 50.0/12.5.•Coatign with high c-MoN ratio and discontinuity of crystalline phase shows superior mechanical properties.</abstract><cop>Lausanne</cop><pub>Elsevier B.V</pub><doi>10.1016/j.surfcoat.2022.128278</doi></addata></record>
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subjects	Coatings Crystal structure Crystallinity Magnetron sputtering Mechanical properties Modulation Modulus of elasticity Molybdenum MoN MoSiN Nanocrystals Nanolayer Scratch resistance Silicon nitride Thickness ratio Wear Wear resistance
title	Modulation effect on mechanical properties of nanolayered MoN/MoSiN coatings
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