Analysis of the mechanical properties of TiN/Ti multilayer coatings using indentation under a broad load range

Yuan, Zhanwei; Han, Yutao; Zang, Shun-lai; Chen, Jiao; He, Guangyu; Chai, Yuan; Yang, Zhiming; Fu, Qinqin

doi:10.1016/j.ceramint.2020.12.196

Cited by 34 publications

(4 citation statements)

References 46 publications

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“…Although these tr bolog cal coat ngs can be depos ted d rectly onto a su table substrate for h gh load carry ng capac ty, the base mater al must possess h gh hardness and elast c modulus. Mult -component coat ngs [60] n compar son to s ngle structured coat ngs feature two or more const tuents n the form of gra ns, part cles, or f bres. Although some s ngle layer coat ngs w th mult component arch tecture have been nvest gated [61], t s st ll a rather unexplored branch assoc ated w th tr bolog cal coat ngs.…”

mentioning

confidence: 99%

Smart Tribological Coating

Arjunan

Baroutaji

Robinson

et al. 2022

Encyclopedia of Smart Materials

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mentioning

confidence: 99%

Smart Tribological Coating

Arjunan

Baroutaji

Robinson

et al. 2022

Encyclopedia of Smart Materials

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“…Titanium (Ti) and its alloys, as a kind of "future metal", exhibit various excellent properties including high corrosion resistance, high strength, and biological compatibility. [1][2][3][4] However, the tradeoff of strength and ductility in Ti restricts the application of the Ti and its alloy. In the past decades, a variety of technological pathways for effectively mechanical properties of metallic materials have been developed including hierarchical nanotwinned structures, extreme grain refinement, dislocation architectures [5,6] and nanolaminate structures.…”

Section: Introductionmentioning

confidence: 99%

Layer thickness dependent plastic deformation mechanism in Ti/TiCu dual-phase nano-laminates

et al. 2023

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Crystalline/amorphous nanolaminate is an effective strategy to improve the mechanical properties of metallic materials, but the underlying deformation mechanism is still under the way of exploring. Here, the mechanical properties and plastic deformation mechanism of Ti/TiCu dual-phase nanolaminates (DPNLs) with different layer thickness are investigated using molecular dynamics simulations. The results indicate that the influence of the layer thickness on the plastic deformation mechanism in crystalline layer is negligible, while it affects the plastic deformation mechanism of amorphous layers distinctly. The crystallization of amorphous TiCu is exhibited in amorphous parts of the Ti/TiCu DPNLs, which is inversely proportional to the layer thickness. It is observed that the crystallization of the amorphous TiCu is a process driven by stress and heat. The Young’s modulus for the Ti/TiCu DPNLs are higher than that of composite material due to the amorphous/crystalline interfaces. Furthermore, the main plastic deformation mechanism in crystalline part: grain reorientation, transformation from hexagonal-close-packed-Ti to face-centered cubic-Ti and body-centered cubic-Ti, has also been displayed in present work. The results may provide a guideline for the design of high-performance Ti and its alloy.

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“…Unlike that of the multi-phase nitriding layer, the hardness of the single-phase TiN layer greatly differs from that of the matrix, which is prone to brittle fracture [15,16]. Therefore, the multi-phase nitriding layer with a hardness gradient has become a research hotspot.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the mechanical properties and microstructure of titanium surfaces designed by electromagnetic induction nitriding

Guan¹,

Xiang²,

Zhang³

et al. 2022

Mater. Res. Express

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Nitride has high hardness and excellent wear resistance. It is frequently prepared on a material surface to improve material performance. The nitriding layer can be prepared in different ways, so the bonding strength and microstructure between the nitriding layer and the matrix differ, which will directly affect the surface mechanical properties of the material. In this study, pure titanium (TA1) was nitrided using electromagnetic induction nitriding, and the microstructure of nitriding layer was analysed using X-ray photoelectron spectroscopy (XPS), scanning electron microscopy-electron backscatter diffraction (SEM-EBSD) and scanning electron microscopy-energy-dispersive X-ray spectroscopy (SEM-EDS). In addition, the mechanical properties of the nitriding layer were studied using a nanoindentation and scratch tester. The experimental result shows a 20 μm induction nitriding layer composed of TiN, Ti2N and α(N)-Ti. The compound layer (Ti2N and TiN) was approximately 3 μm. The surface was contaminated with C and O elements, and evident segregation bands were found between the induction nitriding layer and matrix. The induction nitriding layer can considerably improve the wear resistance of titanium alloy, but the bonding force between the induction nitriding layer and matrix decreases owing to the segregation band.

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Analysis of the mechanical properties of TiN/Ti multilayer coatings using indentation under a broad load range

Cited by 34 publications

References 46 publications

Smart Tribological Coating

Smart Tribological Coating

Layer thickness dependent plastic deformation mechanism in Ti/TiCu dual-phase nano-laminates

Analysis of the mechanical properties and microstructure of titanium surfaces designed by electromagnetic induction nitriding

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