Understanding order in compositionally graded ferroelectrics: Flexoelectricity, gradient, and depolarization field effects

J. Zhang, R. Xu, A. R. Damodaran, Z.-H. Chen, and L. W. Martin

Phys. Rev. B 89, 224101 – Published 13 June 2014

Abstract

A nonlinear thermodynamic formalism based on Ginzburg-Landau-Devonshire theory is developed to describe the total free energy density in (001)-oriented, compositionally graded, and monodomain ferroelectric films including the relative contributions and importance of flexoelectric, gradient, and depolarization energy terms. The effects of these energies on the evolution of the spontaneous polarization, dielectric permittivity, and the pyroelectric coefficient as a function of position throughout the film thickness, temperature, and epitaxial strain state are explored. In general, the presence of a compositional gradient and the three energy terms tend to stabilize a polar, ferroelectric state even in compositions that should be paraelectric in the bulk. Flexoelectric effects produce large built-in fields which diminish the temperature dependence of the polarization and susceptibilities. Gradient energy terms, here used to describe short-scale correlation between dipoles, have minimal impact on the polarization and susceptibilities. Finally, depolarization energy significantly impacts the temperature and strain dependence, as well as the magnitude, of the susceptibilities. This approach provides guidance on how to more accurately model compositionally graded films and presents experimental approaches that could enable differentiation and determination of the constitutive coefficients of interest.

Received 6 April 2014
Revised 23 May 2014

DOI:https://doi.org/10.1103/PhysRevB.89.224101

Authors & Affiliations

J. Zhang¹, R. Xu¹, A. R. Damodaran¹, Z.-H. Chen¹, and L. W. Martin^1,2,*

¹Department of Materials Science and Engineering and Materials Research Laboratory, University of Illinois, Urbana-Champaign, Urbana, Illinois 61801, USA
²Department of Materials Science and Engineering, University of California, Berkeley, Berkeley, California 94720, USA

^*lwmartin@berkeley.edu

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Vol. 89, Iss. 22 — 1 June 2014

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Images

Figure 1
(a) Spontaneous polarization as a function of position throughout the thickness for 150-nm-thick films of ${BaTiO}_{3}$ (green), ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ (blue), and compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ (orange) under conditions where there are zero flexoelectric, gradient, and depolarization energies. Spontaneous polarization as a function of position throughout the thickness for a 150 nm compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film under conditions where there is (b) nonzero flexoelectric energy, (c) nonzero gradient energy, and (d) nonzero depolarization energy.
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Figure 2
(a) Average polarization as a function of temperature for 150-nm-thick films of ${BaTiO}_{3}$ (green), ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ (blue), and compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ (orange) under conditions where there are zero flexoelectric, gradient, and depolarization energies. Average polarization as a function of temperature for a 150 nm compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film under conditions where there is (b) nonzero flexoelectric energy, (c) nonzero gradient energy, and (d) nonzero depolarization energy.
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Figure 3
Average polarization as a function of temperature for a 150-nm-thick compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film under the influence of all three energies of interest with varying (a) flexoelectric, (b) gradient, and (c) depolarization energies.
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Figure 4
Dielectric permittivity as a function of temperature for a 150 nm compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film under the influence of all three energies of interest with varying (a) flexoelectric, (b) gradient, and (c) depolarization energies. Effective pyroelectric coefficient as a function of temperature for a 150 nm compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film under the influence of all three energies of interest with varying (d) flexoelectric, (e) gradient, and (f) depolarization energies. Black data in graphs show a comparison with a coherently strained, homogeneous film of ${BaTiO}_{3}$ .
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Figure 5
(a) Average polarization, (b) dielectric permittivity, and (c) effective pyroelectric coefficient as a function of epitaxial lattice mismatch for a 150 nm compositionally graded ${BaTiO}_{3}$ - ${Ba}_{0.6} {Sr}_{0.4} {TiO}_{3}$ film where $f_{12}$ = $- 10^{- 10} m^{3}$ /C, $g_{33}$ = $10^{- 10} m^{3}$ V/C, and $ɛ_{d}$ is allowed to vary from 1 to 300. A number of commercially available substrates spanning the range of lattice mismatches studied here are provided for context.
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