Laves Phase Formation and Its Effect on Mechanical Properties in P91 Steel

Xia, Zhen; Wang, Chuan-Yang; Zhao, Yanfen; Zhang, Guodong; Zhang, Lu; Meng, Xianglong

doi:10.1007/s40195-015-0318-5

Cited by 17 publications

(9 citation statements)

References 22 publications

(35 reference statements)

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“…The effect of Laves phase on the mechanical properties, beneficial or detrimental, mainly depends on the volume fraction and mean size of Laves phase in the RHEAs. With increasing mean size and volume fraction of Laves phase, crack initiation and crack growth would rapidly increase [48]. In this study, small cracks can be observed around the indentations employed for the 1200 °C homogenised Ti-V-Cr-Nb-Ta sample, but not for the 800 °C homogenised Ti-V-Cr5-Nb-Ta sample, Fig.…”

Section: C15 Laves Phasementioning

confidence: 49%

Controlling microstructure and mechanical properties of Ti-V-Cr-Nb-Ta refractory high entropy alloys through heat treatments

Liu

Scales

et al. 2023

Journal of Alloys and Compounds

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Section: C15 Laves Phasementioning

confidence: 49%

Controlling microstructure and mechanical properties of Ti-V-Cr-Nb-Ta refractory high entropy alloys through heat treatments

Liu

Scales

et al. 2023

Journal of Alloys and Compounds

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“…These converse effects of the Cr additions on strength/ductility were attributed by the authors to the formation of the Laves phase that is expected from the thermodynamic point of view [6,7]. Several studies have clearly proven that the Laves phase is inherently brittle at lower temperatures [8,9]. In a very recent study, Senkov et al investigated the microstructure and mechanical properties of the alloy Al-Mo 0.5 -Nb-Ta 0.5 -Ti-Zr [10].…”

Section: Introductionmentioning

confidence: 89%

Development of Oxidation Resistant Refractory High Entropy Alloys for High Temperature Applications: Recent Results and Development Strategy

Gorr

Mueller

Christ

et al. 2018

The Minerals, Metals &Amp; Materials Series

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Refractory High Entropy Alloys (HEAs) can be considered as promising materials for high temperature applications because of their high melting point and outstanding high temperature strength. The microstructure of the equimolar alloy Nb-Mo-Cr-Ti-Al consists of a disordered body centered cubic (BCC) phase and a small amount of the Laves phase, while the equimolar alloy Ta-Mo-Cr-Ti-Al exhibits the ordered B2 and several Laves phases in addition to the BCC phase. The experimental studies reveal that these alloys possess a beneficial combination of

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“…Most of the factors influencing precipitation strengthening depend on the particle size obtained during the nucleation and growth stages [90]. On the other hand, during exposure to high temperatures under constant load, high chromium ferritic steels have been found to have high intermetallic stability, unlike the rapid growth observed in 9%-12%Cr ferritic/martensitic steels.…”

Section: ¯( )mentioning

confidence: 99%

“…On the other hand, during exposure to high temperatures under constant load, high chromium ferritic steels have been found to have high intermetallic stability, unlike the rapid growth observed in 9%-12%Cr ferritic/martensitic steels. In both cases, the creep conditions tend to increase the diffusion of the elements that form Laves-phase, affecting the growth and coarsening of the particulate, decreasing the anchoring on the high-angle grain boundaries [90,91]. Initially, the fine Laves-phase adopt the shape of a needle, maintaining a semi-coherent (or coherent) interface with the matrix.…”

Section: ¯( )mentioning

confidence: 99%

Laves phase formation in Fe-based alloys from strengthening particle to self-healing agent: a review

Wackerling,

Rojas,

Oñate

et al. 2023

Mater. Res. Express

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In this study, were extensively reviewed the hardening and self-healing properties of Laves-phase in Fe-based alloys. First, the microstructural features of different polytypes of the Laves-phase, focusing on the thermodynamics and kinetics of formation in ferritic and martensitic steels were revised. C14 was identified as the dominant polytype in steels, providing strengthening by precipitation, anchoring of dislocation, and interphase boundaries, thereby increasing the creep resistance. Although the Laves phase is widely known as a reinforcement particle (or even a detrimental phase in some systems) in martensitic/ferritic and ferritic steels, recent findings have uncovered a promising property. Particles with self-healing characteristics provide creep resistance by delaying creep cavities formation. In this regard, different elements such as tungsten and molybdenum are known to provide this feature to binary and tertiary ferrous alloys due to their ability to diffuse into the creep cavities and form Laves-phase Fe(Mo,W)2. To date, self-healing by precipitation has only been reported in commercial stainless steel AISI 312, 347, and 304 modified with boron, nevertheless with a little contribution to creep rupture life. Although, commercial computational tools with thermodynamic and kinetic databases are available for researchers, to tackle the self-healing process with exactitude, genetic algorithms arise as a new tool for computational design. The two properties of Laves phase reported in the literature, precipitation hardening and self-healing agent, is a mix that can bring out a new research field. Therefore, it is not unreasonable to think of tailor-made high chromium creep-resistant steels reinforced by Laves-phase coupled with self-healing properties. However, owing to the characteristic of Laves-phase seems to be a complex challenge, mainly due to the crystallographic features of this phase in comparison with the host matrix, available computational tools, and databases.

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Laves Phase Formation and Its Effect on Mechanical Properties in P91 Steel

Cited by 17 publications

References 22 publications

Controlling microstructure and mechanical properties of Ti-V-Cr-Nb-Ta refractory high entropy alloys through heat treatments

Controlling microstructure and mechanical properties of Ti-V-Cr-Nb-Ta refractory high entropy alloys through heat treatments

Development of Oxidation Resistant Refractory High Entropy Alloys for High Temperature Applications: Recent Results and Development Strategy

Laves phase formation in Fe-based alloys from strengthening particle to self-healing agent: a review

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