Large and electric field tunable superelasticity in BaTiO3 crystals predicted by an incremental domain switching criterion

Y. W. Li; X. B. Ren; F. X. Li; H. S. Luo; D. N. Fang

doi:10.1063/1.4795330

Large and electric field tunable superelasticity in BaTiO3 crystals predicted by an incremental domain switching criterion

Y. W. Li, X. B. Ren, F. X. Li^*, H. S. Luo, D. N. Fang

^*Corresponding author for this work

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

19 Citations (Scopus)

Abstract

Superelasticity is very common in shape memory alloys but is rather difficult to realize in ferroelectric ceramics and had never appeared in normal ferroelectric single crystals. Here we show that guided by a proposed incremental 90°domain switching criterion, large and electric-field-tunable superelastic strains up to 0.85 has been realized in a specially poled BaTiO3 crystal cube via compression loading/unloading with a positive dc bias electric field along the poling direction. Moreover, the tunable superelasticity has a large damping factor of up to 0.76, which is very promising in intelligent damping devices.

Original language	English
Article number	092905
Journal	Applied Physics Letters
Volume	102
Issue number	9
DOIs	https://doi.org/10.1063/1.4795330
Publication status	Published - 4 Mar 2013
Externally published	Yes

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title = "Large and electric field tunable superelasticity in BaTiO3 crystals predicted by an incremental domain switching criterion",

abstract = "Superelasticity is very common in shape memory alloys but is rather difficult to realize in ferroelectric ceramics and had never appeared in normal ferroelectric single crystals. Here we show that guided by a proposed incremental 90°domain switching criterion, large and electric-field-tunable superelastic strains up to 0.85 has been realized in a specially poled BaTiO3 crystal cube via compression loading/unloading with a positive dc bias electric field along the poling direction. Moreover, the tunable superelasticity has a large damping factor of up to 0.76, which is very promising in intelligent damping devices.",

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AU - Li, Y. W.

AU - Ren, X. B.

AU - Li, F. X.

AU - Luo, H. S.

AU - Fang, D. N.

PY - 2013/3/4

Y1 - 2013/3/4

N2 - Superelasticity is very common in shape memory alloys but is rather difficult to realize in ferroelectric ceramics and had never appeared in normal ferroelectric single crystals. Here we show that guided by a proposed incremental 90°domain switching criterion, large and electric-field-tunable superelastic strains up to 0.85 has been realized in a specially poled BaTiO3 crystal cube via compression loading/unloading with a positive dc bias electric field along the poling direction. Moreover, the tunable superelasticity has a large damping factor of up to 0.76, which is very promising in intelligent damping devices.

AB - Superelasticity is very common in shape memory alloys but is rather difficult to realize in ferroelectric ceramics and had never appeared in normal ferroelectric single crystals. Here we show that guided by a proposed incremental 90°domain switching criterion, large and electric-field-tunable superelastic strains up to 0.85 has been realized in a specially poled BaTiO3 crystal cube via compression loading/unloading with a positive dc bias electric field along the poling direction. Moreover, the tunable superelasticity has a large damping factor of up to 0.76, which is very promising in intelligent damping devices.

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Large and electric field tunable superelasticity in BaTiO3 crystals predicted by an incremental domain switching criterion

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