Maximizing the number of coexisting phases near invariant critical points for giant electrocaloric and electromechanical responses in ferroelectrics

Z. K. Liu; Xinyu Li; Q. M. Zhang

doi:10.1063/1.4747275

Maximizing the number of coexisting phases near invariant critical points for giant electrocaloric and electromechanical responses in ferroelectrics

Z. K. Liu, Xinyu Li, Q. M. Zhang

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83 Scopus citations

Abstract

Ferroelectric materials directly convert electrical energy to mechanical or thermal work and are critical to applications such as sensors, transducers, actuators, and cooling devices. Numerous efforts have been undertaken to develop materials with high electrocaloric (EC) and electromechanical (EM) responses. Here, we present a theoretical analysis, based on thermodynamic fundamentals, for developing ferroelectric materials with high EC and EM responses, i.e., searching for and operating the material near an invariant critical point (ICP). We show that by tailoring the constraints to maximize the number of coexisting phases near ICPs, large EC and EM responses may be realized.

Original language	English (US)
Article number	082904
Journal	Applied Physics Letters
Volume	101
Issue number	8
DOIs	https://doi.org/10.1063/1.4747275
State	Published - Aug 20 2012

All Science Journal Classification (ASJC) codes

Physics and Astronomy (miscellaneous)

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10.1063/1.4747275

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title = "Maximizing the number of coexisting phases near invariant critical points for giant electrocaloric and electromechanical responses in ferroelectrics",

abstract = "Ferroelectric materials directly convert electrical energy to mechanical or thermal work and are critical to applications such as sensors, transducers, actuators, and cooling devices. Numerous efforts have been undertaken to develop materials with high electrocaloric (EC) and electromechanical (EM) responses. Here, we present a theoretical analysis, based on thermodynamic fundamentals, for developing ferroelectric materials with high EC and EM responses, i.e., searching for and operating the material near an invariant critical point (ICP). We show that by tailoring the constraints to maximize the number of coexisting phases near ICPs, large EC and EM responses may be realized.",

author = "Liu, {Z. K.} and Xinyu Li and Zhang, {Q. M.}",

note = "Funding Information: Z.K.L. is supported by National Science Foundation through Grant DMR-1006557 and Office of Naval Research under the Contract Number N0014-07-1-0638. Q.M.Z. is supported by Army Research Office under Grant W911NF-11-1-0534, and X.L. is supported by the U.S. Department of Energy Division of Materials Sciences through Grant No. DE-FG02-07ER46410. We thank to Y. Wang, Z. Kutnjak, R. Pirc, and S. G. Lu for discussions.",

year = "2012",

month = aug,

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doi = "10.1063/1.4747275",

language = "English (US)",

volume = "101",

journal = "Applied Physics Letters",

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AU - Liu, Z. K.

AU - Li, Xinyu

AU - Zhang, Q. M.

N1 - Funding Information: Z.K.L. is supported by National Science Foundation through Grant DMR-1006557 and Office of Naval Research under the Contract Number N0014-07-1-0638. Q.M.Z. is supported by Army Research Office under Grant W911NF-11-1-0534, and X.L. is supported by the U.S. Department of Energy Division of Materials Sciences through Grant No. DE-FG02-07ER46410. We thank to Y. Wang, Z. Kutnjak, R. Pirc, and S. G. Lu for discussions.

PY - 2012/8/20

Y1 - 2012/8/20

N2 - Ferroelectric materials directly convert electrical energy to mechanical or thermal work and are critical to applications such as sensors, transducers, actuators, and cooling devices. Numerous efforts have been undertaken to develop materials with high electrocaloric (EC) and electromechanical (EM) responses. Here, we present a theoretical analysis, based on thermodynamic fundamentals, for developing ferroelectric materials with high EC and EM responses, i.e., searching for and operating the material near an invariant critical point (ICP). We show that by tailoring the constraints to maximize the number of coexisting phases near ICPs, large EC and EM responses may be realized.

AB - Ferroelectric materials directly convert electrical energy to mechanical or thermal work and are critical to applications such as sensors, transducers, actuators, and cooling devices. Numerous efforts have been undertaken to develop materials with high electrocaloric (EC) and electromechanical (EM) responses. Here, we present a theoretical analysis, based on thermodynamic fundamentals, for developing ferroelectric materials with high EC and EM responses, i.e., searching for and operating the material near an invariant critical point (ICP). We show that by tailoring the constraints to maximize the number of coexisting phases near ICPs, large EC and EM responses may be realized.

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Maximizing the number of coexisting phases near invariant critical points for giant electrocaloric and electromechanical responses in ferroelectrics

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