Stability criteria for nanocrystalline alloys

Author(s)

Kalidindi, Arvind Rama; Schuh, Christopher A

Additional downloads

Stability criteria.pdf (1.393Mb)

Abstract

Alloying nanocrystalline materials to stabilize them against grain growth is proving a critical enabling strategy for the processing and usage of bulk nanocrystalline parts. Alloying elements that segregate strongly to grain boundaries can lead to a preference for nanocrystalline structure, and to be most stable the grain boundary segregated state would need to be preferred to forming any other phase or solute configuration, including a solid solution, ordered compounds, or solute precipitates. In this paper, a stability criterion is developed by comparing the enthalpy of the grain boundary segregated state against such stable bulk phases. This enthalpic criterion is also translated into a lattice model framework to enable the use of Monte Carlo simulations to incorporate entropic and geometric effects in assessing nanocrystalline stability. Monte Carlo simulations show that entropy can play a role in stabilizing nanocrystalline states, leading to duplex structures, and also in forming a grain boundary network preferentially over a disordered or amorphous-like bulk phase. Keywords: Nanocrystalline; Alloy; Grain boundary; Segregation; Intermetallic

Date issued

2017-06

URI

https://hdl.handle.net/1721.1/123688

Department

Massachusetts Institute of Technology. Department of Materials Science and Engineering

Journal

Acta Materialia

Publisher

Elsevier BV

Citation

Kalidindi, Arvind and Christopher A. Schuh. "Stability criteria for nanocrystalline alloys." Acta Materialia 132 (June 2017): 128-137 © 2017 Acta Materialia Inc

Version: Author's final manuscript

ISSN

1359-6454