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Auteurs principaux: Ghasemi, Mahyar, Seifi, Alireza, Kateb, Movaffaq, Gudmundsson, Jon Tomas, Brault, Pascal, Marashi, Pirooz
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2411.01328
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author Ghasemi, Mahyar
Seifi, Alireza
Kateb, Movaffaq
Gudmundsson, Jon Tomas
Brault, Pascal
Marashi, Pirooz
author_facet Ghasemi, Mahyar
Seifi, Alireza
Kateb, Movaffaq
Gudmundsson, Jon Tomas
Brault, Pascal
Marashi, Pirooz
contents The detailed mechanism of bonding in the cold spray process has remained elusive for both experimental and theoretical parties. Adiabatic shear instability and hydrodynamic plasticity models have been so far the most popular explanations. Here, using molecular dynamics simulation, we investigate their validity at the nanoscale. The present study has potential application for the fabrication of ultra-thin layers for the electronics industry. For this aim, we considered Ti nanoparticles of different diameters and Si substrates of different orientations. It is shown that very high spray velocities are required for a jet to be observed at the nanoscale. We propose a method for thermostating the substrate that enables utilizing high spray velocities. For the first time, we demonstrate an oscillatory behavior in both the normal and radial stress components within the substrate that can propagate into the particle. We have shown that neither the adiabatic shear instability model nor the hydrodynamic plasticity model can be ignored at the nanoscale. Besides, the formation of a low-resistance titanium silicide proper for electronic application is illustrated.
format Preprint
id arxiv_https___arxiv_org_abs_2411_01328
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Probing trade-off between critical size and velocity in cold-spray: An atomistic simulation
Ghasemi, Mahyar
Seifi, Alireza
Kateb, Movaffaq
Gudmundsson, Jon Tomas
Brault, Pascal
Marashi, Pirooz
Materials Science
Mesoscale and Nanoscale Physics
The detailed mechanism of bonding in the cold spray process has remained elusive for both experimental and theoretical parties. Adiabatic shear instability and hydrodynamic plasticity models have been so far the most popular explanations. Here, using molecular dynamics simulation, we investigate their validity at the nanoscale. The present study has potential application for the fabrication of ultra-thin layers for the electronics industry. For this aim, we considered Ti nanoparticles of different diameters and Si substrates of different orientations. It is shown that very high spray velocities are required for a jet to be observed at the nanoscale. We propose a method for thermostating the substrate that enables utilizing high spray velocities. For the first time, we demonstrate an oscillatory behavior in both the normal and radial stress components within the substrate that can propagate into the particle. We have shown that neither the adiabatic shear instability model nor the hydrodynamic plasticity model can be ignored at the nanoscale. Besides, the formation of a low-resistance titanium silicide proper for electronic application is illustrated.
title Probing trade-off between critical size and velocity in cold-spray: An atomistic simulation
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2411.01328