Role of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate

Qi Tan; Z. Xu; Jie Fang Li; Dwight Viehland

doi:10.1063/1.119728

Role of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate

Qi Tan^*, Z. Xu, Jie Fang Li, Dwight Viehland

^*Corresponding author for this work

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

40 Scopus citations

Abstract

Studies of the influence of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate have been performed by transmission electron microscopy, high resolution electron microscopy, polarization switching measurements, and dielectric spectroscopy. Investigations focused on La³⁺ and K¹⁺ modified lead zirconate titanates. Defects which could be randomly quenched-in from temperatures significantly above that of the ferroelectric phase transformation resulted in relaxor ferroelectric behavior characterized by polar nanodomains. However, defects which remained mobile until temperatures significantly below that of the phase transformation resulted in a normal ferroelectric state which was characterized by domain pinning. Mobile impurities/vacancies are revealed to order into chain fragments or clusters which diffuse to domain boundaries resulting in a pinning of the boundaries on cooling.

Original language	English
Pages (from-to)	1062-1064
Number of pages	3
Journal	Applied Physics Letters
Volume	71
Issue number	8
DOIs	https://doi.org/10.1063/1.119728
State	Published - 25 Aug 1997
Externally published	Yes

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title = "Role of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate",

abstract = "Studies of the influence of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate have been performed by transmission electron microscopy, high resolution electron microscopy, polarization switching measurements, and dielectric spectroscopy. Investigations focused on La3+ and K1+ modified lead zirconate titanates. Defects which could be randomly quenched-in from temperatures significantly above that of the ferroelectric phase transformation resulted in relaxor ferroelectric behavior characterized by polar nanodomains. However, defects which remained mobile until temperatures significantly below that of the phase transformation resulted in a normal ferroelectric state which was characterized by domain pinning. Mobile impurities/vacancies are revealed to order into chain fragments or clusters which diffuse to domain boundaries resulting in a pinning of the boundaries on cooling.",

author = "Qi Tan and Z. Xu and Li, {Jie Fang} and Dwight Viehland",

year = "1997",

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T1 - Role of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate

AU - Tan, Qi

AU - Xu, Z.

AU - Li, Jie Fang

AU - Viehland, Dwight

PY - 1997/8/25

Y1 - 1997/8/25

N2 - Studies of the influence of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate have been performed by transmission electron microscopy, high resolution electron microscopy, polarization switching measurements, and dielectric spectroscopy. Investigations focused on La3+ and K1+ modified lead zirconate titanates. Defects which could be randomly quenched-in from temperatures significantly above that of the ferroelectric phase transformation resulted in relaxor ferroelectric behavior characterized by polar nanodomains. However, defects which remained mobile until temperatures significantly below that of the phase transformation resulted in a normal ferroelectric state which was characterized by domain pinning. Mobile impurities/vacancies are revealed to order into chain fragments or clusters which diffuse to domain boundaries resulting in a pinning of the boundaries on cooling.

AB - Studies of the influence of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate have been performed by transmission electron microscopy, high resolution electron microscopy, polarization switching measurements, and dielectric spectroscopy. Investigations focused on La3+ and K1+ modified lead zirconate titanates. Defects which could be randomly quenched-in from temperatures significantly above that of the ferroelectric phase transformation resulted in relaxor ferroelectric behavior characterized by polar nanodomains. However, defects which remained mobile until temperatures significantly below that of the phase transformation resulted in a normal ferroelectric state which was characterized by domain pinning. Mobile impurities/vacancies are revealed to order into chain fragments or clusters which diffuse to domain boundaries resulting in a pinning of the boundaries on cooling.

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DO - 10.1063/1.119728

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SP - 1062

EP - 1064

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 8

ER -

Role of defect distributions and mobility on ferroelectric phase transformations in lead zirconate titanate

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