2019
DOI: 10.1016/j.tca.2019.03.016
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Effect of Co substitution for Fe on the non-isothermal crystallization kinetics of Fe80P13C7 bulk metallic glasses

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Cited by 21 publications
(13 citation statements)
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“…Currently, researchers are focused on investigating crystallizations of metallic glasses [ 27 , 28 , 29 , 30 ]. To date, there have not been any precise investigations of the crystallization kinetics of Mg–Zn–Ca metallic glasses.…”
Section: Introductionmentioning
confidence: 99%
“…Currently, researchers are focused on investigating crystallizations of metallic glasses [ 27 , 28 , 29 , 30 ]. To date, there have not been any precise investigations of the crystallization kinetics of Mg–Zn–Ca metallic glasses.…”
Section: Introductionmentioning
confidence: 99%
“…However, it is unavoidable that MGs will change into the corresponding crystalline counterparts for their metastable nature and this can be enhanced with increasing temperatures, which exhibits noticeable effects on their structures and properties 15–19 . Therefore, it is essential to investigate the crystallization behaviors and crystallization kinetics of MGs at various heating conditions, which is significant for tuning the structures and properties of MGs 15–40 . Among them, the nonisothermal crystallization behaviors and crystallization kinetics for MGs with various compositions, that is, multicomponent Zr‐Cu‐Fe‐Al MG, 15 Fe‐Co‐Cr‐Ni‐Zr MG, 16 Zr‐(CuAg)‐Al MG, 17 Fe‐Ni‐P‐B MG, 18 Zr‐Co‐Al‐Cu MG, 24 Fe‐Ni‐Mo‐P‐C‐B‐Cu MG, 25 Ti‐Zr‐Ni‐Cu‐Be MG, 26 Co‐Fe‐Ta‐B MG, 29 Ni‐Nb‐Ti‐Zr‐Co‐Ta MG, 31 Fe‐Cr‐P‐C‐B MG, 32 and Fe‐Co‐Cr‐Mo‐Y‐C‐B MG 33 ; ternary U‐Co‐Al MG, 19 La‐Al‐Co MG, 27 Zr‐Al‐Fe MG, 30 Zr‐Co‐Al MGs, 24,35 Fe‐P‐C MG, 36 Fe‐B‐C MG, 37 La‐Al‐Ni MG, 38 and Pd‐Ni‐P MG 39 ; and binary Cu‐Zr MG, 40 have been extensively researched by Kissinger, Ozawa, Kissinger‐Akahira‐Sunose (KAS), Ozawa‐Flynn‐Wall (OFW), and Vogel‐Fulcher‐Tammann (VFT) approaches using differential scanning calorimeter (DSC).…”
Section: Introductionmentioning
confidence: 99%
“…[15][16][17][18][19] Therefore, it is essential to investigate the crystallization behaviors and crystallization kinetics of MGs at various heating conditions, which is significant for tuning the structures and properties of MGs. Among them, the nonisothermal crystallization behaviors and crystallization kinetics for MGs with various compositions, that is, multicomponent Zr-Cu-Fe-Al MG, 15 Fe-Co-Cr-Ni-Zr MG, 16 Zr-(CuAg)-Al MG, 17 Fe-Ni-P-B MG, 18 Zr-Co-Al-Cu MG, 24 Fe-Ni-Mo-P-C-B-Cu MG, 25 Ti-Zr-Ni-Cu-Be MG, 26 Co-Fe-Ta-B MG, 29 Ni-Nb-Ti-Zr-Co-Ta MG, 31 Fe-Cr-P-C-B MG, 32 and Fe-Co-Cr-Mo-Y-C-B MG 33 ; ternary U-Co-Al MG, 19 La-Al-Co MG, 27 Zr-Al-Fe MG, 30 Zr-Co-Al MGs, 24,35 Fe-P-C MG, 36 Fe-B-C MG, 37 La-Al-Ni MG, 38 and Pd-Ni-P MG 39 ; and binary Cu-Zr MG, 40 have been extensively researched by Kissinger, Ozawa, Kissinger-Akahira-Sunose (KAS), Ozawa-Flynn-Wall (OFW), and Vogel-Fulcher-Tammann (VFT) approaches using differential scanning calorimeter (DSC). Under nonisothermal crystallization conditions, MGs were continuously heated up to complete crystallization by different heating rates.…”
mentioning
confidence: 99%
“…It is universally known that MGs will instinctively change to a relative state such as the crystalline counterparts for their metastable nature, and this process can be stimulated at elevated temperatures, which exhibits remarkable effects on the structures and properties of MGs 6–11 . Accordingly, persistent efforts are required for knowing the crystallization kinetics of MGs under diverse conditions, which is of considerable benefit to the glass‐forming ability (GFA), structures, and properties of the MGs and developing more amorphous‐crystalline composites with desirable structures and properties 6–18 . Meanwhile, it is also suggested that the crystallization kinetics of MG systems is generally composition dependent, which will vary with the change in the composition of MGs 7–10,12,14,15,18 .…”
Section: Introductionmentioning
confidence: 99%
“…Generally, the crystallization behaviors and crystallization kinetics under different conditions for diverse compositions, that is, binary Zr‐Ni MG, 19 Cu‐Zr MGs, 20,21 and Ni‐Nb MGs 22,23 ; ternary Dy‐Co‐Al MG, 24 U‐Co‐Al MG, 25 La‐Al‐Co MG, 26 Zr‐Al‐Fe MG, 15 Zr‐Co‐Al MGs, 8,27 Fe‐P‐C MG, 18 Fe‐B‐C MG, 28 La‐Al‐Ni MG, 4 and Pd‐Ni‐P MG, 29 ; quaternary Zr‐Cu‐Fe‐Al MG, 30 Zr‐(CuAg)‐Al MG, 7 Fe‐Ni‐P‐B MG, 31 Zr‐Co‐Al‐Cu MG, 27 and Co‐Fe‐Ta‐B MG 13 ; and multicomponent Fe‐Co‐Cr‐Ni‐Zr MG, 6 Fe‐Ni‐Mo‐P‐C‐B‐Cu MG, 32 Ti‐Zr‐Ni‐Cu‐Be MG, 33 Ni‐Nb‐Ti‐Zr‐Co‐Ta MG, 34 Fe‐Cr‐P‐C‐B MG, 17 and Fe‐Co‐Cr‐Mo‐Y‐C‐B MG 35 have been comprehensively investigated. Among these reported investigations, the crystallization kinetics of MGs at the isothermal annealing conditions have been primarily studied 12–17 .…”
Section: Introductionmentioning
confidence: 99%