Enhanced Energy Density in Core–Shell Ferroelectric Ceramics: Modeling and Practical Conclusions

Wu, Longwen; Wang, Xiaohui; Li, Longtu

doi:10.1111/jace.14063

Cited by 31 publications

(21 citation statements)

References 51 publications

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“…Core-shell structures in FE ceramics are reported to alleviate inhomogeneity of local electric fields and weakens dielectric nonlinearity, resulting in slimmer hysteresis loops. 37 Although the work presented does not conclusively prove the arguments presented by the authors of ref.…”

Section: Field-induced Polarization (P-e) Bipolar Strain (S-e) and Ucontrasting

confidence: 70%

High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

Wang

Fan

et al. 2018

ACS Appl. Energy Mater.

254

100

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High recoverable energy density (Wrec ~ 2.1 J/cm 3) was obtained in (0.7-x)BiFeO3-0.3BaTiO3-xBi(Zn2/3Nb1/3)O3 + 0.1wt% Mn2O3 (BF-BT-xBZN, x = 0.05) lead-free ceramics at < 200 kV/cm. Fast discharge speeds (< 0.5 s), low leakage (~ 10-7 A/cm 2) and small temperature variation in Wrec (~ 25% from 23 to 150 °C) confirmed the potential for these BiFeO3 based compositions for use in high energy density capacitors. A core-shell microstructure composed of a BiFeO3-rich core and BaTiO3-rich shell was observed by scanning and transmission electron microscopy which may contribute to the high value of energy density. In addition, for x = 0.005, a large electromechanical strain was observed with Spos = 0.463% and effective d33 * ~ 424 pm/V, suggesting that this family of ceramics may also have potential for high strain actuators.

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Section: Field-induced Polarization (P-e) Bipolar Strain (S-e) and Ucontrasting

confidence: 70%

High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

Wang

Fan

et al. 2018

ACS Appl. Energy Mater.

254

100

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“…On the other hand, due to the hysteretic dielectric feature of the ferroelectric ceramic grains, as shown in the upper part of Figure B, the polarization response during charge and discharge processes are separately considered. A classical hyperbolic tangent function is employed during the initial charge upswing, which is written as

P = P_{normals} \tanh [\frac{ε_{0} ()(, ε_{g} ()(, 0) - 1) E}{P_{normals}}],

where P is the polarization under the applied field of E and P s , ɛ 0 , and

{normalε}_{normalg} (0)

are the saturation polarization, vacuum permittivity, and the zero‐electric‐field permittivity of ceramic grain, respectively. When combined with the standard constitutive definition D = ɛ 0 E + P , here D represents the electric displacement, and the dielectric permittivity of ceramic grain

()(, {normalε}_{c}^{'})

during the initial upswing can be derived by

{normalε}_{c}^{'} = 1 + \frac{P_{s}}{{normalε}_{0} E} \tanh [\frac{ε_{0} ()(, ε_{g} ()(, 0) - 1) E}{P_{normals}}] .

…”

Section: Modelingmentioning

confidence: 99%

“…Therefore, a finite element method simulation is adopted in Figure 2B, the polarization response during charge and discharge processes are separately considered. A classical hyperbolic tangent function is employed during the initial charge upswing, [36][37][38] which is written as…”

Section: Modified Hyperbolic Tangent Model On the Electric Hysteresismentioning

confidence: 99%

Grain‐size–dependent dielectric properties in nanograin ferroelectrics

et al. 2018

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A series of ferroelectric ceramic models with grain and grain‐boundary structures of different sizes are established via Voronoi tessellations. A phase‐field model is introduced to study the dielectric breakdown strength of these ferroelectric ceramics. Afterward, the relation between the electric displacement and electric field and the hysteresis loop are calculated using a finite element method based on a classical and modified hyperbolic tangent model. The results indicate that as the grain size decreases, the dielectric strength is enhanced, but the dielectric permittivity is reduced. The discharge energy density and energy storage efficiency of these ferroelectric ceramics extracted from the as‐calculated hysteresis both increase along with a decrease in their grain size at their breakdown points. However, under the same applied electric field, the ferroelectric ceramic with a smaller grain size possesses a lower discharge energy density but a higher energy storage efficiency. The results suggest that ferroelectric ceramics with smaller grain sizes possess advantages for applications in energy storage devices.

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“…Further analyses on the activation energy of oxygen vacancy diffusion under P-E hysteresis loop measurement are necessary to clarify this consideration. As the polarization is linked to the energy storage density, [56][57][58][59] Fig. 7(i) gives the value of P max ÀP r and the energy storage density aer aging 785 h of all the samples.…”

Section: Xrd Patterns Resultsmentioning

confidence: 99%

Large activation energy in aged Mn-doped Sr_0.4Ba_0.6Nb₂O₆ ferroelectric ceramics

et al. 2017

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Enhanced Energy Density in Core–Shell Ferroelectric Ceramics: Modeling and Practical Conclusions

Cited by 31 publications

References 51 publications

High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

Grain‐size–dependent dielectric properties in nanograin ferroelectrics

Large activation energy in aged Mn-doped Sr_0.4Ba_0.6Nb₂O₆ ferroelectric ceramics

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Enhanced Energy Density in Core–Shell Ferroelectric Ceramics: Modeling and Practical Conclusions

Cited by 31 publications

References 51 publications

High Energy Storage Density and Large Strain in Bi(Zn2/3Nb1/3)O3-Doped BiFeO3–BaTiO3 Ceramics

High Energy Storage Density and Large Strain in Bi(Zn2/3Nb1/3)O3-Doped BiFeO3–BaTiO3 Ceramics

Grain‐size–dependent dielectric properties in nanograin ferroelectrics

Large activation energy in aged Mn-doped Sr0.4Ba0.6Nb2O6 ferroelectric ceramics

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High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

High Energy Storage Density and Large Strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃–BaTiO₃ Ceramics

Large activation energy in aged Mn-doped Sr_0.4Ba_0.6Nb₂O₆ ferroelectric ceramics