Role of polar nanoregions with weak random fields in Pb-based perovskite ferroelectrics

Helal, M. A.; Aftabuzzaman, M.; Tsukada, Shinya; Kojima, Seiji

doi:10.1038/srep44448

Cited by 31 publications

(21 citation statements)

References 55 publications

(96 reference statements)

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“…This type of relaxors includes PMN, PZN, PbSc 1/2 Nb 1/2 O 3 (PSN), PbSc 1/2 Ta 1/2 O 3 (PST), Na 1/2 Bi 1/2 TiO 3 (NBT), etc., which generally contain two heterovalance cations on the A‐site or B‐site of the perovskite structure. In these relaxors, the A‐site or B‐site cations are not totally ordered, instead, both nanoscale ordering and disordered regions may be present . For some systems, the volume fraction of the ordered regions can be tuned by thermal annealing.…”

Section: State‐of‐the‐art Relaxor Ferroelectric Materials and Their Amentioning

confidence: 99%

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Zhang

Damjanović

et al. 2018

Adv Funct Materials

305

228

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Long-range ordering of dipoles is a key microscopic signature of ferroelectrics. These ordered dipoles form ferroelectric domains, which can be reoriented by electric fields. Relaxor ferroelectrics are a type of ferroelectric where the longrange ordering of dipoles is disrupted by cation disorder, exhibiting complex polar states with a significant amount of local structural heterogeneity at the nanoscale. They are the materials of choice for numerous devices such as capacitors, nonlinear optical devices, and piezoelectric transducers, owing to their extraordinary dielectric, electro-optic, and electromechanical properties. However, despite their extensive applications in these devices, the origins of their unique properties are yet to be fully understood, hindering the design and exploration of new relaxor ferroelectric-based materials. Herein, the complex polar states and applications of relaxor ferroelectrics are first introduced. Attention is then focused on their electromechanical properties, where the relationship between local structural heterogeneity and the extraordinary electromechanical properties is discussed. Based on the understanding of relaxor ferroelectrics, potential strategies to exploit the local structural heterogeneity to design ferroelectrics for drastically enhancing their electromechanical performances are also discussed. It is expected that this article will stimulate future studies on the important roles of local structural heterogeneity in improving the properties of various functional materials. FerroelectricsThe ORCID identification number(s) for the author(s) of this article can be found under https://doi.

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Section: State‐of‐the‐art Relaxor Ferroelectric Materials and Their Amentioning

confidence: 99%

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Zhang

Damjanović

et al. 2018

Adv Funct Materials

305

228

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“…PNRs are formed due to the reorientation of off‐center Nb ions described by these three characteristic temperatures, from lowest to highest: the Curie temperature,

T_{normalc}

; intermediate temperature,

T^{*}

; and Burns temperature,

T_{normalB}

, respectively. [ 32–35 ] As we increase the temperature from

T_{normalc}

T_{normalc} + 58 ° C

( T >

T^{*}

), these microscopically small static FE regions within its macroscopic PE state start to shrink in size, correlation, and lifetime. Ta ions move toward their high symmetry site and Nb ions get de‐restricted of specific reorientation directions upon approaching

T_{normalB}

.…”

Section: Resultsmentioning

confidence: 99%

Domain Engineering Enabled Giant Linear Electro‐Optic Effect and High Transparency in Ferroelectric KTa_1−xNb_xO₃ Single Crystals

Shang

Liu

Chen

et al. 2022

Physica Rapid Research Ltrs

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A giant linear electro‐optic (EO) effect and high transparency in ferroelectric potassium tantalate niobate [( K T normala 1 − x N normalb x normalO 3 ), KTN] crystal is achieved via a thermally controlled domain engineering method. It involves a two‐step thermal annealing process: 1) a rapid cooling process that forms polar nano‐regions (PNRs), i.e., a cooling rate of 1 . 67 ° C normals − 1 from T normalc + 58 ° C to T normalc + 8 ° C where T normalc is the Curie temperature; and 2) a slow cooling process that facilitates abnormal domain growth (AGG) i.e., a cooling rate of 0 . 0115 ° C s − 1 from T normalc + 8 ° C to T normalc − 15 ° C . Since PNR can have a faceted boundary and high anisotropy, it can promote AGG within single crystals to realize solid‐state domain conversion macroscopically from a multi‐domain to single‐domain crystal within a slow cooling process. The resultant KTN crystal offers high transparency that is equivalent to its paraelectric phase; and a linear EO coefficient ( γ 51 ) as large as γ 51 ≈ 51200 p m normalV − 1 , which is five times the value of conventional KTN crystals with similar composition. This giant linear EO coefficient represents a major technical advance in EO materials and significantly reduces the driving voltage, power, and footprint of many types of EO devices.

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“…The increase in homogeneity of grain sizes corresponds to the increase in intergranular porosity and resulted in the decrease in relative density. The density of the unmodified ceramics, obtained by the Archimedes displacement method with distilled water, was 7.07 g/cm 3 , whereas the density of the ceramics modified with 5 at.% of calcium was 6.94 g/cm 3 . The changes of the morphology and grain size may not solely be an effect of doping, but also the difference in the sintering temperature (the pure BBN ceramics were sintered at 1100°C, whereas the calcium modified ones at 1150°C).…”

Section: Structural Characterizationmentioning

confidence: 94%

“…Over the past few decades a number of theoretical models have been developed to try to describe their properties. Their basic assumption is existence of polar nanoregions (PNRs), which provide unique physical properties [1][2][3]. Although the presence of PNRs in ferroelectric relaxors is noticed without a doubt, the mechanism and reasons for their formation have been the subject of discussion for several decades.…”

Section: Introductionmentioning

confidence: 99%

Influence of calcium doping on microstructure, dielectric and electric properties of BaBi2Nb2O9 ceramics

Szalbot

Adamczyk

Wodecka-Duś

et al. 2018

PAC

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Barium bismuth niobiate (BaBi 2 Nb 2 O 9) ceramics modified by calcium were prepared by solid state synthesis and two-step sintering process. An impact of calcium substitution on the A site of perovskite block is presented. The investigations are focused on dielectric as well as electric aspects of the modification. The presented results reveal that the concentration of a space charge is not preserved, what is surprising due to the homovalent nature of the dopant and no reason for creating additional lattice defects and charges connected. However, not only the valence of ions, but also the calcium-oxygen and barium-oxygen bond strength should be taken into consideration. Since the calcium-oxygen bond is probably weaker the loss of the bismuth oxide is expected to increase with an increase in the calcium content. Such a scenario results in appearance of a large number of negative charge carriers connected with unsaturated oxygen ions.

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Role of polar nanoregions with weak random fields in Pb-based perovskite ferroelectrics

Cited by 31 publications

References 55 publications

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Domain Engineering Enabled Giant Linear Electro‐Optic Effect and High Transparency in Ferroelectric KTa_1−xNb_xO₃ Single Crystals

Influence of calcium doping on microstructure, dielectric and electric properties of BaBi2Nb2O9 ceramics

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Role of polar nanoregions with weak random fields in Pb-based perovskite ferroelectrics

Cited by 31 publications

References 55 publications

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Local Structural Heterogeneity and Electromechanical Responses of Ferroelectrics: Learning from Relaxor Ferroelectrics

Domain Engineering Enabled Giant Linear Electro‐Optic Effect and High Transparency in Ferroelectric KTa1−xNbxO3 Single Crystals

Influence of calcium doping on microstructure, dielectric and electric properties of BaBi2Nb2O9 ceramics

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Domain Engineering Enabled Giant Linear Electro‐Optic Effect and High Transparency in Ferroelectric KTa_1−xNb_xO₃ Single Crystals