Atomistic Insights into Impact-Induced Energy Release and Deformation of Core–Shell-Structured Ni/Al Nanoparticle in an Oxygen Environment
Kexin Zhu, Yifan Xie, Jian-Li Shao, Pengwan Chen

TL;DR
This study uses simulations to explore how Ni/Al nanoparticles deform and release energy during high-speed impacts in oxygen-rich environments.
Contribution
The work provides atomic-level insights into the coupling of mechanical deformation and chemical reactions in Ni/Al nanoparticles under impact.
Findings
Al fragments directly, while Ni undergoes plastic deformation, melting, and fragmentation with increasing impact velocity.
Energy release depends on nanoparticle deformation, with oxidative combustion and intermetallic reactions being key sources.
Oxygen concentration significantly affects the efficiency of energy release during impact events.
Abstract
In actual atmospheric environments, Ni/Al composites subjected to high-velocity impact will undergo both intermetallic reaction and oxidative combustion simultaneously, and the coupling of mechanical and multiple chemical processes leads to extremely complex characteristics of energy release. This work employs ReaxFF molecular dynamics simulations to investigate the impact-induced deformation and energy release of a core–shell-structured Ni/Al nanoparticle in an oxygen environment. It was found that Al directly undergoes fragmentation, while Ni experiences plastic deformation, melting, and fragmentation in sequence as the impact velocity increased. This results in the final morphology of the nanoparticles being an ellipsoidal-clad nanoparticle, spherical Ni/Al melt, and debris cloud. Furthermore, these deformation characteristics are strongly related to the material property of the…
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Taxonomy
TopicsEnergetic Materials and Combustion · Ion-surface interactions and analysis · Graphene research and applications
