Stabilization and strengthening of nano-crystalline materials by alloying

Abstract

The goal of the proposed research is to advance the fundamental understanding of the thermodynamic and kinetic mechanisms of grain stabilization in nano-materials. The model systems chosen for this project are Cu-Ta alloys stabilized by Zener pinning of grain boundaries (GBs) (kinetic mechanism), and Cu-Bi alloys stabilized by reduction of the GB free energy (thermodynamic mechanism). A wide range of atomistic computer simulation methods will be applied to investigate the thermodynamics and kinetics of GBs in the chosen alloys and the effect of GB segregation on their mechanical behavior. This will require the development of a new interatomic potential for the Cu-Bi system and computationally efficient algorithms for GB free energy calculations in the high-throughput mode. The simulations will be performed on both polycrystalline samples, representing collective behavior of multiple GBs, and on individual, crystallographically characterized boundaries. In the latter case, the goal will be to establish a link between GB structure, bicrystallography, and thermodynamic and kinetic factors of thermal stability. This project will contribute to the fundamental knowledge base needed for the optimization of synthesis and processing routes and discovery of new thermally stable nanocrystalline alloys. The proposed research is synergistic with experimental work on stabilized nanocrystalline alloys conducted at the Army Research Laboratory.

Document Details

Document Type

DoD Grant Award

Publication Date

Feb 14, 2019

Source ID

W911NF1810110

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