Non-isothermal crystallization kinetics of Fe71Nb6B23 amorphous ribbons

Man Zhu; Junjie Li; Zengyun Jian; Fang'e Chang

Non-isothermal crystallization kinetics of Fe₇₁Nb₆B₂₃ amorphous ribbons

Man Zhu, Junjie Li, Zengyun Jian, Fang'e Chang

School of Materials Sience and Engineering

Xi'an Technological University

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

The Fe₇₁Nb₆B₂₃ amorphous ribbons were prepared using melt spinning method. Differential scanning calorimeter was applied to investigate non-isothermal crystallization kinetics of the amorphous ribbons at different heating rates from 10 to 40 K/min. As the heating rate is increased, the values of T_g, T_x, and T_p are shifted toward a higher temperature region, suggesting that the amorphous ribbons have obvious crystallization kinetics. The effective activation energies including E_g, E_x and E_p were calculated with Kissinger and Ozawa equations by means of DSC traces at different step-up temperature rates. Thermodynamical mechanism of the amorphous ribbons was explained. The results reveal that the nucleation is quite more difficult than growth of the grains because E_x is larger than E_p. And the crystallization kinetics is more obvious than that of glass transition.

Original language	English
Pages (from-to)	1730-1734
Number of pages	5
Journal	Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering
Volume	41
Issue number	10
State	Published - Oct 2012

Keywords

Activation energy
Amorphous ribbons
Crystallization kinetics
Melt spinning

Cite this

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abstract = "The Fe71Nb6B23 amorphous ribbons were prepared using melt spinning method. Differential scanning calorimeter was applied to investigate non-isothermal crystallization kinetics of the amorphous ribbons at different heating rates from 10 to 40 K/min. As the heating rate is increased, the values of Tg, Tx, and Tp are shifted toward a higher temperature region, suggesting that the amorphous ribbons have obvious crystallization kinetics. The effective activation energies including Eg, Ex and Ep were calculated with Kissinger and Ozawa equations by means of DSC traces at different step-up temperature rates. Thermodynamical mechanism of the amorphous ribbons was explained. The results reveal that the nucleation is quite more difficult than growth of the grains because Ex is larger than Ep. And the crystallization kinetics is more obvious than that of glass transition.",

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T1 - Non-isothermal crystallization kinetics of Fe71Nb6B23 amorphous ribbons

AU - Zhu, Man

AU - Li, Junjie

AU - Jian, Zengyun

AU - Chang, Fang'e

PY - 2012/10

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N2 - The Fe71Nb6B23 amorphous ribbons were prepared using melt spinning method. Differential scanning calorimeter was applied to investigate non-isothermal crystallization kinetics of the amorphous ribbons at different heating rates from 10 to 40 K/min. As the heating rate is increased, the values of Tg, Tx, and Tp are shifted toward a higher temperature region, suggesting that the amorphous ribbons have obvious crystallization kinetics. The effective activation energies including Eg, Ex and Ep were calculated with Kissinger and Ozawa equations by means of DSC traces at different step-up temperature rates. Thermodynamical mechanism of the amorphous ribbons was explained. The results reveal that the nucleation is quite more difficult than growth of the grains because Ex is larger than Ep. And the crystallization kinetics is more obvious than that of glass transition.

AB - The Fe71Nb6B23 amorphous ribbons were prepared using melt spinning method. Differential scanning calorimeter was applied to investigate non-isothermal crystallization kinetics of the amorphous ribbons at different heating rates from 10 to 40 K/min. As the heating rate is increased, the values of Tg, Tx, and Tp are shifted toward a higher temperature region, suggesting that the amorphous ribbons have obvious crystallization kinetics. The effective activation energies including Eg, Ex and Ep were calculated with Kissinger and Ozawa equations by means of DSC traces at different step-up temperature rates. Thermodynamical mechanism of the amorphous ribbons was explained. The results reveal that the nucleation is quite more difficult than growth of the grains because Ex is larger than Ep. And the crystallization kinetics is more obvious than that of glass transition.

KW - Activation energy

KW - Amorphous ribbons

KW - Crystallization kinetics

KW - Melt spinning

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Non-isothermal crystallization kinetics of Fe₇₁Nb₆B₂₃ amorphous ribbons

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