Atomic insights into shock-induced alloying reaction of premixed Ni/Al nanolaminates

In material processing and handling processes, premixed interlayer often replace the ideal Ni/Al interface, which would become a new origin of alloying reaction. This work investigates shock-induced reaction mechanism and kinetics of premixed Ni/Al nanolaminates with molecular dynamics simulations and theoretical analysis. The reaction is found to be driven by the crystallization evolution in premixed interlayer and the diffusion of premixed atoms. Among them, multi-stage reaction patterns are strongly manifested by the crystallization evolution characteristics. Specifically, crystallization-dissolution-secondary growth and crystallization-dissolution of B2 phase respectively correspond to the solid-state and solid-liquid reaction cases, where crystallizations are fitted well by Johnson-Mehl-Avrami kinetics model. Interestingly, the different growth mechanisms of B2 grain are revealed, namely nuclei coalescence and atomic diffusion. Moreover, the analysis of microscopic diffusion theory indicates a certain non-random diffusion nature for solid-state reaction initiation, but near-purely random diffusion for solid-liquid reaction initiation. The diffused Al atoms possess a limited diffusion coefficient and enhanced diffusion correlation, resulting in extremely slow mixing rate in Ni layer. In addition, the influence law of Ni concentration in premixed interlayer on reactivity parameters can be quantitatively described by a quadratic function.

Automated summary

This study investigates the shock-induced reaction mechanism and kinetics of premixed Ni/Al nanolaminates using molecular dynamics simulations and theoretical analysis. The reaction is found to be driven by the crystallization evolution in the premixed interlayer and the diffusion of premixed atoms. The study reveals multi-stage reaction patterns and different growth mechanisms of B2 grain. Microscopic diffusion theory analysis suggests a non-random diffusion nature for solid-state reaction initiation and purely random diffusion for solid-liquid reaction initiation.