The Influence of Plasma Composition on Mechanical Stresses in Substrate-Coating System

Sergey A. Shanin

doi:10.4028/www.scientific.net/KEM.712.93

Paper Titles

Non Catalytic Methane Formation from Syngas in the Dielectric Barrier Discharge Plasma, Initiated by Microsecond Pulses
p.71

Structural and Phase Transformations in Ti-B₄C System Formed when Melting the Composition Film/Substrate by an Intense Electron Beam
p.76

Structural Phase Transformations of the Surface Layer of SiC Ceramics Irradiated by Intense Electron Beam
p.81

The Research of Diamond Coatings Morphology Evolution under the Action of Reactive Ion Etching in Perpendicular Direction
p.87

The Influence of Plasma Composition on Mechanical Stresses in Substrate-Coating System
p.93

The Features of Diffusion and Mechanical Waves Interaction at the Initial Stage of Metal Surface Treatment by Particle Beam under Nonisothermal Conditions
p.99

Numerical Simulation of Temperature Field in Steel under Action of Electron Beam Heating Source
p.105

Textural Characteristics of Products Obtained by Electrochemical Oxidation of Copper and Cadmium Using Alternating Current
p.112

Electrolytic Behavior Silver Microphases and Nanophases on the Graphite Electrode Surface
p.117

HomeKey Engineering MaterialsKey Engineering Materials Vol. 712The Influence of Plasma Composition on Mechanical...

The Influence of Plasma Composition on Mechanical Stresses in Substrate-Coating System

Abstract:

The work calculates the stress-strain state (SSS) of substrate-coating system during plasma deposition of metals (Ti, Al, Cr) and nitrogen. The study demonstrates the influence of the concentration of deposited elements at the surfaces of growing coating on the redistribution of stresses. The paper establishes the dependence of the penetration depth of deposited elements into the substrate on their concentration at the surface of growing coating.

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Periodical:

Key Engineering Materials (Volume 712)

Pages:

93-98

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.712.93

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Online since:

September 2016

Authors:

Sergey A. Shanin*

Keywords:

Change of Composition, Deformation, Growing Coating, Stress, Width of Diffusion Zone

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