Microstructural evolution and mechanical characterization for the AlCoCrFeNi<sub>2.1</sub> eutectic high‐entropy alloy under different temperatures

Li, Yafei; Zhou, Junling; Liu, Yifei; Lu, Chuanyang; Shi, Lei; Zheng, Wenjian; Jin, Weiya; Gao, Zengliang; Yang, Junxiao; He, Yanming

doi:10.1111/ffe.13970

Cited by 10 publications

(4 citation statements)

References 46 publications

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“…Furthermore, the dislocation climb-plus-glide mechanism may involve dislocation multiplication from Frank-Reed sources, which eventually leads to the tertiary creep behavior at an accelerated creep rate. As the above mechanisms are operated under the true stress condition in real specimens due to the incompressibility of plastic flow, the true stress and strain are given by 31,32…”

Section: Simplified Deformation-mechanism Based True-stress (Dmts) Modelmentioning

confidence: 99%

“…Furthermore, the dislocation climb‐plus‐glide mechanism may involve dislocation multiplication from Frank‐Reed sources, which eventually leads to the tertiary creep behavior at an accelerated creep rate. As the above mechanisms are operated under the true stress condition in real specimens due to the incompressibility of plastic flow, the true stress and strain are given by 31,32

ε goodbreak= \ln ((), 1 goodbreak+ ε_{0})

σ goodbreak= σ_{0} \exp ((), ε)

where σ 0 is the engineering (nominal) stress, ε is the true strain, and ε 0 is the engineering strain. Taking the true stress–strain relationship into Equation (1) and also considering dislocation multiplication by the first approximate of the Taylor series, the SSCR of dislocation‐climb‐plus glide

{\dot{ε}}_{cg}

can be calculated 21 :

{\dot{ε}}_{cg} goodbreak= ((), 1 goodbreak+ M ε_{cg}) A^{'} {(\frac{σ}{E})}^{n} goodbreak= ((), 1 goodbreak+ M ε_{cg}) A^{'} {(\frac{σ_{0}}{E})}^{n} \exp ((), n ε_{cg}) \approx A^{'} ((), 1 goodbreak+ M ε_{cg} goodbreak+ n ε_{cg}) {(\frac{σ_{0}}{E})}^{n} goodbreak= ((), 1 goodbreak+ M ε_{cg} goodbreak+ n ε_{cg}) {\dot{ε}}_{italicss 0}

where M is the dislocation multiplication factor and A' is expressed as

A^{'} goodbreak= A_{0} D_{0} \exp ((), \frac{- Q}{italicRT}) \frac{Eb}{kT} {(\frac{b}{d})}^{p}

…”

Section: Simplified Deformation‐mechanism Based True‐stress (Dmts) Modelmentioning

confidence: 99%

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Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

Wang

Zheng

et al. 2023

Fatigue Fract Eng Mat Struct

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For nuclear power generation as a carbon‐neutral energy source, in‐vessel retention (IVR) must be implemented to maintain the structural integrity of nuclear reactor pressure vessel (RPV) for more than 72 h under severe accidental conditions. This technology requires accurate prediction of creep deformation and life of RPV material being operated under pressure and extremely high‐temperature gradient. The current work develops a simplified deformation‐mechanism‐based true‐stress (DMTS) model for creep behavior/life‐prediction of SA508 Gr.3 steel, a typical RPV material, above the phase transformation temperatures (800–1000°C). This model is used to evaluate the time to specific creep strain (t3% and t5%) and rupture (tr), in comparison with popular empirical methods such as Orr–Sherby–Dorn (OSD) and Larson–Miller (LM). The simplified DMTS model achieves an excellent agreement with the experimental observations. The controlling deformation mechanisms are also discussed by metallurgical examinations, which provide the physical premise for the model development and application.

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Section: Simplified Deformation-mechanism Based True-stress (Dmts) Modelmentioning

confidence: 99%

ε goodbreak= \ln ((), 1 goodbreak+ ε_{0})

σ goodbreak= σ_{0} \exp ((), ε)

{\dot{ε}}_{cg}

can be calculated 21 :

{\dot{ε}}_{cg} goodbreak= ((), 1 goodbreak+ M ε_{cg}) A^{'} {(\frac{σ}{E})}^{n} goodbreak= ((), 1 goodbreak+ M ε_{cg}) A^{'} {(\frac{σ_{0}}{E})}^{n} \exp ((), n ε_{cg}) \approx A^{'} ((), 1 goodbreak+ M ε_{cg} goodbreak+ n ε_{cg}) {(\frac{σ_{0}}{E})}^{n} goodbreak= ((), 1 goodbreak+ M ε_{cg} goodbreak+ n ε_{cg}) {\dot{ε}}_{italicss 0}

where M is the dislocation multiplication factor and A' is expressed as

A^{'} goodbreak= A_{0} D_{0} \exp ((), \frac{- Q}{italicRT}) \frac{Eb}{kT} {(\frac{b}{d})}^{p}

…”

Section: Simplified Deformation‐mechanism Based True‐stress (Dmts) Modelmentioning

confidence: 99%

Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

Wang

Zheng

et al. 2023

Fatigue Fract Eng Mat Struct

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“…This also indicates that the addition of the element Al enhances the thermal stability of the alloy. The A973 alloy has high strengths below 673 K, approaching that of the coherent nanoprecipitation-strengthened superalloys and several eutectic alloys [19,26,28]. However, the thermal stability of the alloy is poor, and the properties of the alloy considerably decrease after 673 K. The thermal stability of the semi-coherent interface is much worse than that of the coherent interface.…”

Section: Tensile Propertiesmentioning

confidence: 99%

“…Furthermore, the presence of the element Al increases the oxidation resistance of the alloys [18]. The AlCoCrFeNi 2.1 eutectic high-entropy alloy, composed of the ordered FCC phase (L1 2 ) and the ordered body-centered cubic phase (B2), exhibits exceptional mechanical properties at temperatures below 973 K [19]. However, the temperature sensitivity of semi-coherent body-centered cubic (BCC) or B2 precipitates remains uncertain.…”

Section: Introductionmentioning

confidence: 99%

High-Temperature Mechanical Behavior of Cobalt-Free FeMnCrNi(Al) High-Entropy Alloys

Liu,

Jin,

Yang

et al. 2023

Metals

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The high-temperature properties of new alloys need to be investigated to guide the hot working process. The temperature sensitivity of various microstructures of Fe45Mn15Cr15Ni25 and Fe35Mn15Cr15Ni25Al10 cobalt-free high-entropy alloys was investigated using high-temperature tensile tests. For recrystallized alloys, the increase in aluminum (Al) atoms exacerbates the emergence of serration behavior, prolongs the strain hardening capacity, and delays the decrease in plasticity. The Fe35Mn15Cr15Ni25Al10 alloy, with a high-density precipitated phase, exhibits excellent mechanical properties at 673 K. It has a yield strength of 735 MPa, an ultimate tensile strength of 1030 MPa, and an elongation of 11%. Ultimately, it has been found that the addition of the element Al improves the strength, oxidation resistance, and thermal stability of the alloy. According to the solid solution strengthening model fitting and nanoindentation results, the temperature sensitivity of the yield strength of the alloy is primarily attributed to the solid solution strengthening and phase interface forces. There is relatively less variation in grain boundary strengthening and precipitation strengthening. The relationship between the mechanical properties and temperature of the alloy can be predicted to guide the machining process of the alloy.

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A review on the effect of various rolling regimes (cryo, cold, warm, hot) and post-annealing on high-entropy alloys: microstructure evolution, deformation mechanisms, and mechanical properties

Tayyebi,

DerakhshaniMolayousefi

2023

Archiv.Civ.Mech.Eng

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Microstructural evolution and mechanical characterization for the AlCoCrFeNi_2.1 eutectic high‐entropy alloy under different temperatures

Cited by 10 publications

References 46 publications

Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

High-Temperature Mechanical Behavior of Cobalt-Free FeMnCrNi(Al) High-Entropy Alloys

A review on the effect of various rolling regimes (cryo, cold, warm, hot) and post-annealing on high-entropy alloys: microstructure evolution, deformation mechanisms, and mechanical properties

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Microstructural evolution and mechanical characterization for the AlCoCrFeNi2.1 eutectic high‐entropy alloy under different temperatures

Cited by 10 publications

References 46 publications

Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

Creep behavior and life prediction of a reactor pressure vessel steel above phase‐transformation temperature via a deformation mechanism‐based creep model

High-Temperature Mechanical Behavior of Cobalt-Free FeMnCrNi(Al) High-Entropy Alloys

A review on the effect of various rolling regimes (cryo, cold, warm, hot) and post-annealing on high-entropy alloys: microstructure evolution, deformation mechanisms, and mechanical properties

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Product

Resources

About

Microstructural evolution and mechanical characterization for the AlCoCrFeNi_2.1 eutectic high‐entropy alloy under different temperatures