Atomic-scale analysis of nanoindentation behavior of high-entropy alloy

Li, Jia; Fang, Qihong; Liu, Bin; Liu, Youwen; Liu, Yong

doi:10.1142/s2424913016500016

Cited by 56 publications

(16 citation statements)

References 50 publications

(55 reference statements)

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“…This is because the α‐(Fe, Ni) phase resists plastic deformation by reducing plane slippage and preventing interplanar dislocation as the plastic deformation of crystalline metals can be attributed to the slip dislocations. [ 44 ] Thus, the α‐(Fe, Ni) phase shows higher hardness than the γ‐(Ni, Fe) phase.…”

Section: Resultsmentioning

confidence: 99%

Understanding Deformation Behavior in Sintered Fe36Ni Alloy Through Nanoindentation Experiments and Molecular Dynamics Simulation

Sahni,

Bhowmick,

Upadhyaya

2023

Adv Eng Mater

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In this work, the nanoindentation‐induced deformation behavior in sintered Fe36Ni is investigated using experiments and molecular dynamics simulations. The Fe36Ni alloy is synthesized through the powder metallurgy route. A microstructural study of the sintered sample reveals the formation of both hard α‐(Fe, Ni) and soft γ‐(Ni, Fe) phases due to compositional inhomogeneity, and increasing the sintering temperature enhances the γ‐(Ni, Fe) phase formation. The experimentally measured nanoindentation features are correlated to atomistic origin using molecular dynamics simulation. Deformation behavior is explored using local shear strain and atomic displacement plot, and a detailed investigation of various dislocation nucleation and their interaction is performed to gain insights into the mechanisms governing plastic deformation. The plastic deformation of α‐(Fe, Ni) phase is governed by dislocation with Burger's vector b = ½ <111> and b = <100> whereas, sessile dislocations such as Stair‐rod (b = 1/6 <110>), Frank (b = 1/3 <111>), and Hirth lock (b = 1/3 <100>) are found to be responsible for the plastic deformation and also contribute in strain hardening of γ‐(Ni, Fe) phase.

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Section: Resultsmentioning

confidence: 99%

Understanding Deformation Behavior in Sintered Fe36Ni Alloy Through Nanoindentation Experiments and Molecular Dynamics Simulation

Sahni,

Bhowmick,

Upadhyaya

2023

Adv Eng Mater

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“…In particular, the hardness of tantalum film at DC-100 W was significantly lower than that reported in the literature because of its great sputtering atoms ability on the film surface, [19,24,26] which attributes to the grain growth of beta and the large surface roughness. [28][29][30] However, an abnormal hardness of Ta films with a value of 17.64 GPa was found at DC-30 W. Combining XRD (Fig. 2(b)) and SEM (Fig.…”

Section: Electrical and Mechanical Properties Of Ta Filmsmentioning

confidence: 94%

Structure, phase evolution and properties of Ta films deposited using hybrid high-power pulsed and DC magnetron co-sputtering

Huang¹,

He²,

Yi³

2022

Chinese Phys. B

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Crystalline phase and microstructure control are critical for obtaining desired properties of Ta films deposited by magnetron sputtering. Structure, phase evolution, and properties of Ta films deposited by using hybrid high power impulse magnetron sputtering (HiPIMS) and direct current magnetron sputtering (DCMS) under different fractions of DCMS power where Ta ion to Ta neutral ratios of the deposition flux were changed are investigated. The results revealed that the number of Ta ions arriving on the substrate/growing film play an important role in structure and phase evolution of Ta films. It can effectively avoid the unstable arc discharge under low pressure and show a higher deposition rate by hybrid high power impulse magnetron sputtering (HiPIMS) and direct current magnetron sputtering (DCMS) compared with only high power impulse magnetron sputtering (HiPIMS). Meanwhile, the high hardness α-Ta films can be directly deposited by hybrid co-sputtering compared to those prepared by direct current magnetron sputtering (DCMS). In the co-sputtering technology, pure α-Ta phase film with extremely fine, dense and uniform crystal grains were obtained, which shows smooth surface roughness (3.22 nm), low resistivity (38.98 μΩ·cm) and abnormal high hardness (17.64 GPa).

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“…The EAM potentials are capable of describing HEAs, such as FeNiCrCoCu HEAs. [ 44 ] However, due to the difficulty for establishing the atomic potential functions of the multiple‐element systems, the atomic potentials for HEAs are very scarce and limit the application of MD methods. The several other potentials in HEAs are proposed, including the EAM‐Morse hybrid potential function, [ 45 ] the modified embedded atom method (MEAM) potential function, [ 46 ] the average‐atom interatomic potential, [ 47 ] and the classic Lennard‐Jones (LJ) potential function.…”

Section: Methodsmentioning

confidence: 99%

Microstructures and Properties of High‐Entropy Materials: Modeling, Simulation, and Experiments

Fang

Liaw

2020

Adv Eng Mater

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The performances of high‐entropy materials (HEMs), including high‐entropy alloys, high‐entropy ceramics, and high‐entropy polymers, with unique characteristics (high mixing entropy, serious lattice distortion, and short‐range order) determined by experiments are out of the ordinary, such as the excellent mechanical properties. The important research methods on HEMs are briefly introduced from the physical modeling, multiscale simulation, and experiments at various scales. The microstructures (dislocation, twinning, grain boundary, and phase) and performances (mechanical property, physical property, chemical property, optical property, medical property, and irradiation property) are summarized. Future directions of research and development with a focus on modeling and simulation in HEMs are discussed. In the next, HEMs with the unique properties would be promising candidates for industrial applications beyond conventional alloys.

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Atomic-scale analysis of nanoindentation behavior of high-entropy alloy

Cited by 56 publications

References 50 publications

Understanding Deformation Behavior in Sintered Fe36Ni Alloy Through Nanoindentation Experiments and Molecular Dynamics Simulation

Understanding Deformation Behavior in Sintered Fe36Ni Alloy Through Nanoindentation Experiments and Molecular Dynamics Simulation

Structure, phase evolution and properties of Ta films deposited using hybrid high-power pulsed and DC magnetron co-sputtering

Microstructures and Properties of High‐Entropy Materials: Modeling, Simulation, and Experiments

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