First principle study of magnetism and vacancy energetics in a near equimolar NiFeMnCr high entropy alloy

Congyi Li, Junqi Yin, Khorgolkhuu Odbadrakh, Brian C. Sales, Steven J. Zinkle, G. Malcolm Stocks, Brian D. Wirth

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Abstract

We report the results of ab initio calculations of a novel NiFeMnCr high entropy alloy (HEA) with potential applications as a high performance structural material. The bulk and defect property variations due to chemical disordering and magnetic frustration have been studied using both supercell and coherent potential approximation-based techniques. While magnetic frustration due to the presence of multiple 3d transition metals can severely affect the accuracy of vacancy formation energy in first-principles calculations, this effect should be suppressed at intermediate and high temperatures. An efficient approach to evaluate the chemical potential in HEA is constructed and implemented. Vacancy formation energies are computed based on the chemical potential. The statistical distribution of formation energies is weakly dependent upon the chemical identity of the vacancy. On the other hand, the calculated vacancy migration energies show that Fe is more likely to have a large migration barrier than Cr, Mn, or Ni. Finally, atomic-level stresses are computed. A qualitative model to explain the elemental segregation trend in HEA is built upon the atomic-level stress calculation results and provides a reasonable qualitative agreement with ion irradiation experimental data of a NiFeMnCr HEA.

Original languageEnglish
Article number155103
JournalJournal of Applied Physics
Volume125
Issue number15
DOIs
StatePublished - Apr 21 2019

Funding

The computational work made use of the National Energy Research Scientific Computing Center (NERSC), a U.S. Department of Energy Office of Science User Facility operated under Contract No. DE-AC02-05CH11231, and the Oak Ridge Leadership Computing Facility at Oak Ridge National Laboratory, which is supported by the Office of Science of the Department of Energy under Contract No. DE-AC05-00OR22725. Funding support was provided in part by the Office of Fusion Energy Sciences, U.S. Department of Energy (DOE) (Grant No. DE-SC0006661 with the University of Tennessee). The KKR-CPA modeling work and magnetic measurements were supported by the Materials Science and Engineering Division, Basic Energy Sciences, DOE.

FundersFunder number
Materials Science and Engineering Division
Office of Science of the Department of Energy
U.S. Department of Energy Office of ScienceDE-AC02-05CH11231
U.S. Department of Energy
Basic Energy Sciences
Fusion Energy Sciences

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