Mechanical properties study of VO2 micro‐beam according to metal‐insulator transition

Mechanical properties study of VO2 micro‐beam according to metal‐insulator transition

Many attempts have been made to develop applications using the metal‐insulator transition (MIT) phenomenon of VO2. However, the difference in the densities of the two phases poses serious obstacle for those applications, as it can destroy or disable during the phase transformations. For microsized o...

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Veröffentlicht in:Journal of the American Ceramic Society 2021-08, Vol.104 (8), p.4183-4189
Hauptverfasser: Kim, Youngho, Cho, Hyeon Ho, Bae, Ji Kwon, Lee, Jaeyeong, Lee, Sang Hoon, Dong, Xue, Asghar, Ghulam, Choi, Jae‐Young, Yu, Hak Ki
Format: Artikel
Sprache:eng
Schlagworte:
co‐exist phase
Finite element method
Lamella
Lamellar structure
Mechanical properties
mechanical property
phase transition
Phase transitions
ultra‐nano indentation
Vanadium oxides
vanadium/vanadium compounds
VO2 MIT
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Zusammenfassung:Many attempts have been made to develop applications using the metal‐insulator transition (MIT) phenomenon of VO2. However, the difference in the densities of the two phases poses serious obstacle for those applications, as it can destroy or disable during the phase transformations. For microsized or nanosized devices, this aspect can be critical. We attempted to measure the mechanical properties when the two phases co‐exist, as well as for an individual phase, via in‐situ control of the temperature of plate‐shaped VO2. The lamella structure is formed during MIT. At this time, the stress is applied by the gradient of density, and the residual strain can easily occur at the interface of each phase. Therefore, the co‐exist state was judged to be the most vulnerable during the MIT. The change in mechanical properties of VO2 during phase transition was also simulated by finite element method.
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.17855