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Cited 2 time in webofscience Cited 3 time in scopus
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Interface-Driven Phase Transition of Phase-Change Material

Authors
Choi, MinhoChoi, HeechaeAhn, JinhoKim, Yong Tae
Issue Date
Apr-2019
Publisher
AMER CHEMICAL SOC
Citation
CRYSTAL GROWTH & DESIGN, v.19, no.4, pp.2123 - 2130
Indexed
SCIE
SCOPUS
Journal Title
CRYSTAL GROWTH & DESIGN
Volume
19
Number
4
Start Page
2123
End Page
2130
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/14253
DOI
10.1021/acs.cgd.8b01690
ISSN
1528-7483
Abstract
In order to be able to control the phase transition of engineered phase-change materials, the specific understanding of phase transition processes is essential. To understand the effect of dopant on phase transition, the phase transition processes of Bi-5.5(In3SbTe2)(94.5) (Bi-IST) are quantitatively investigated with regard to the interfacial, bulk, entropy, and Gibbs free energies involved in the intermediate InSb and InTe phases and the crystallized Bi-IST. In the first step, InSb is crystallized; InTe and Bi are present in the amorphous phase. In the second step, heterogeneous nucleation of crystalline InTe occurs on the InSb. The energy barrier calculated for this nucleation of crystalline InTe is reduced by 1.5 times owing to the interfacial reaction of 5.5 atom % of Bi atoms compared to the case without Bi. In the third step, crystalline InSb and InTe are crystallized to Bi-IST since Bi atoms substitute Sb sites with a higher interfacial energy. The difference in the Gibbs free energy of the Bi-IST is -1.4 x 10(5) eV, which is lower than the -1.1 x 10(5) eV of the IST; this is because the differences in entropy with an increase in temperature and the interfacial energy are increased owing to the added Bi atoms. This lower Gibbs free energy becomes a driving force for the stable phase transition of Bi-IST at a lower transition temperature compared with that of the IST. With these phase transition processes, the contribution shares of enthalpy, entropy with temperature change, and interfacial energy are quantitatively analyzed; moreover, we recommend one of the various methods to design a novel phase-change material.
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