Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance

Yingwei Li; Kangjie Chu; Chang Liu; Peng Jiang; Ke Qu; Peng Gao; Jie Wang; Fuzeng Ren; Qingping Sun; Longqing Chen; Jiangyu Li

doi:10.1073/pnas.2025255118

Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance

Yingwei Li, Kangjie Chu, Chang Liu, Peng Jiang, Ke Qu, Peng Gao, Jie Wang, Fuzeng Ren, Qingping Sun, Longqing Chen, Jiangyu Li

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

16 Scopus citations

Abstract

Superelastic materials capable of recovering large nonlinear strains are ideal for a variety of applications in morphing structures, reconfigurable systems, and robots. However, making oxide materials superelastic has been a long-standing challenge due to their intrinsic brittleness. Here, we fabricate ferroelectric BaTiO₃ (BTO) micropillars that not only are superelastic but also possess excellent fatigue resistance, lasting over 1 million cycles without accumulating residual strains or noticeable variation in stress–strain curves. Phase field simulations reveal that the large recoverable strains of BTO micropillars arise from surface tension–modulated 90° domain switching and thus are size dependent, while the small energy barrier and ultralow energy dissipation are responsible for their unprecedented cyclic stability among superelastic materials. This work demonstrates a general strategy to realize superelastic and fatigue-resistant domain switching in ferroelectric oxides for many potential applications.

Original language	English (US)
Article number	e2025255118
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	118
Issue number	24
DOIs	https://doi.org/10.1073/pnas.2025255118
State	Published - Jun 15 2021

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Li, Y., Chu, K., Liu, C., Jiang, P., Qu, K., Gao, P., Wang, J., Ren, F., Sun, Q., Chen, L., & Li, J. (2021). Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance. Proceedings of the National Academy of Sciences of the United States of America, 118(24), Article e2025255118. https://doi.org/10.1073/pnas.2025255118

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title = "Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance",

abstract = "Superelastic materials capable of recovering large nonlinear strains are ideal for a variety of applications in morphing structures, reconfigurable systems, and robots. However, making oxide materials superelastic has been a long-standing challenge due to their intrinsic brittleness. Here, we fabricate ferroelectric BaTiO3 (BTO) micropillars that not only are superelastic but also possess excellent fatigue resistance, lasting over 1 million cycles without accumulating residual strains or noticeable variation in stress–strain curves. Phase field simulations reveal that the large recoverable strains of BTO micropillars arise from surface tension–modulated 90° domain switching and thus are size dependent, while the small energy barrier and ultralow energy dissipation are responsible for their unprecedented cyclic stability among superelastic materials. This work demonstrates a general strategy to realize superelastic and fatigue-resistant domain switching in ferroelectric oxides for many potential applications.",

author = "Yingwei Li and Kangjie Chu and Chang Liu and Peng Jiang and Ke Qu and Peng Gao and Jie Wang and Fuzeng Ren and Qingping Sun and Longqing Chen and Jiangyu Li",

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Li, Y, Chu, K, Liu, C, Jiang, P, Qu, K, Gao, P, Wang, J, Ren, F, Sun, Q, Chen, L & Li, J 2021, 'Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance', Proceedings of the National Academy of Sciences of the United States of America, vol. 118, no. 24, e2025255118. https://doi.org/10.1073/pnas.2025255118

Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance. / Li, Yingwei; Chu, Kangjie; Liu, Chang et al.
In: Proceedings of the National Academy of Sciences of the United States of America, Vol. 118, No. 24, e2025255118, 15.06.2021.

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

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T1 - Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance

AU - Li, Yingwei

AU - Chu, Kangjie

AU - Liu, Chang

AU - Jiang, Peng

AU - Qu, Ke

AU - Gao, Peng

AU - Wang, Jie

AU - Ren, Fuzeng

AU - Sun, Qingping

AU - Chen, Longqing

AU - Li, Jiangyu

PY - 2021/6/15

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N2 - Superelastic materials capable of recovering large nonlinear strains are ideal for a variety of applications in morphing structures, reconfigurable systems, and robots. However, making oxide materials superelastic has been a long-standing challenge due to their intrinsic brittleness. Here, we fabricate ferroelectric BaTiO3 (BTO) micropillars that not only are superelastic but also possess excellent fatigue resistance, lasting over 1 million cycles without accumulating residual strains or noticeable variation in stress–strain curves. Phase field simulations reveal that the large recoverable strains of BTO micropillars arise from surface tension–modulated 90° domain switching and thus are size dependent, while the small energy barrier and ultralow energy dissipation are responsible for their unprecedented cyclic stability among superelastic materials. This work demonstrates a general strategy to realize superelastic and fatigue-resistant domain switching in ferroelectric oxides for many potential applications.

AB - Superelastic materials capable of recovering large nonlinear strains are ideal for a variety of applications in morphing structures, reconfigurable systems, and robots. However, making oxide materials superelastic has been a long-standing challenge due to their intrinsic brittleness. Here, we fabricate ferroelectric BaTiO3 (BTO) micropillars that not only are superelastic but also possess excellent fatigue resistance, lasting over 1 million cycles without accumulating residual strains or noticeable variation in stress–strain curves. Phase field simulations reveal that the large recoverable strains of BTO micropillars arise from surface tension–modulated 90° domain switching and thus are size dependent, while the small energy barrier and ultralow energy dissipation are responsible for their unprecedented cyclic stability among superelastic materials. This work demonstrates a general strategy to realize superelastic and fatigue-resistant domain switching in ferroelectric oxides for many potential applications.

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Superelastic oxide micropillars enabled by surface tension–modulated 90° domain switching with excellent fatigue resistance

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