The effects of grain size and temperature on mechanical properties of CoCrNi medium-entropy alloy

Zhang, Can; Han, Ben; Shi, Mingxing

doi:10.1007/s00894-023-05502-x

Cited by 5 publications

(1 citation statement)

References 74 publications

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“…The interatomic potential between Fe, Cr, Ni, and Mn atoms was described using the 2NN MEAM (modified embedded-atom method) potential reported by Choi et al [40]. This potential has been shown to provide reliable results in studies of atomistic-level phenomena, including NiCo, NiFe [41], CoCrNi [42], CrFeCoNi [43], and FeMnCrNi [44]. Since the potential function applicable to the five-element alloy is generally adapted to its subsystem, a quaternary MEAM potential function degenerated from the five-element potential function was used in our MD simulations.…”

Section: Model and Radiation Damage Processmentioning

confidence: 99%

Properties of radiation-induced point defects in austenitic steels: a molecular dynamics study

Guo,

Liang,

Wan

2024

Modelling Simul. Mater. Sci. Eng.

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Austenitic steels are recognized as excellent structural materials for pressurized water reactors (PWRs) due to their outstanding mechanical properties and radiation resistance. However, compared to the widely studied FeCrNi series of steels, little is known about the radiation resistance of FeCrNiMn steel. In this study, the generation and evolution of radiation-induced defects in FeCrNiMn steel were investigated by molecular dynamics (MD) simulations. The results showed that more defect atoms were produced in the thermal spike stage, but fewer defects survived at the end of the cascades in FeCrNiMn compared to pure Fe. Point defect properties were analyzed by molecular static (MS), and the formation energies of defects in FeCrNiMn were lower than those of pure Fe, while the migration energies were higher. Compared to FeCrNi, FeCrNiMn had smaller migration energies and a larger overlap of vacancy and interstitial migration energies. The low vacancy formation energies and widely overlapping migration energies suggested that the number of point defects in the thermal spike stage was higher, but the possibility of recombination was greater. Additionally, Mn exhibited the smallest interstitial formation energy and migration energy. The difference in defect migration energies revealed that vacancy and interstitial defects migrate through different alloy constituent elements. This study revealed the underlying mechanism for the excellent irradiation resistance of FeCrNiMn.

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