Improving Energy Storage Properties of Barium Zirconate Titanate Ceramics via Defect Dipole Engineering

Zhiyi Wang; Zhengchao Qin; Si Gao; Hongjuan Zheng; Jin Luo; Yunfei Liu; Yinong Lyu

doi:10.3390/ma18122809

Improving Energy Storage Properties of Barium Zirconate Titanate Ceramics via Defect Dipole Engineering

Zhiyi Wang, Zhengchao Qin, Si Gao, Hongjuan Zheng, Jin Luo, Yunfei Liu, Yinong Lyu

College of Materials Science and Engineering

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

Abstract

Lead-free ceramic materials have been widely studied since dielectric capacitors became a key component for energy storage. In this work, we adopted defect dipole engineering and improved the energy storage performance of barium zirconate titanate (BZT) ceramics by doping them with MnO₂. With the increase in Mn content, the hysteresis loop changed from a conventional loop to a pinned hysteresis loop, resulting in a decrease in remnant polarization (P_r). When x = 0.02, the recoverable energy storage density (W_rec) reached 0.1561 J/cm² @ 40 kV/cm, a 59% increase from undoped BZT. Further, XPS and EPR analyses confirmed that many oxygen vacancies were generated. We also performed SEM and TEM characterization and observed the microstructures. These results are consistent with theories suggesting that the formation of the pinned hysteresis loop is attributable to oxygen vacancies and defect dipoles.

Original language	English
Article number	2809
Journal	Materials
Volume	18
Issue number	12
DOIs	https://doi.org/10.3390/ma18122809
State	Published - Jun 2025

Keywords

BZT
ceramics
defect dipoles
ferroelectric

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10.3390/ma18122809

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title = "Improving Energy Storage Properties of Barium Zirconate Titanate Ceramics via Defect Dipole Engineering",

abstract = "Lead-free ceramic materials have been widely studied since dielectric capacitors became a key component for energy storage. In this work, we adopted defect dipole engineering and improved the energy storage performance of barium zirconate titanate (BZT) ceramics by doping them with MnO2. With the increase in Mn content, the hysteresis loop changed from a conventional loop to a pinned hysteresis loop, resulting in a decrease in remnant polarization (Pr). When x = 0.02, the recoverable energy storage density (Wrec) reached 0.1561 J/cm2 @ 40 kV/cm, a 59% increase from undoped BZT. Further, XPS and EPR analyses confirmed that many oxygen vacancies were generated. We also performed SEM and TEM characterization and observed the microstructures. These results are consistent with theories suggesting that the formation of the pinned hysteresis loop is attributable to oxygen vacancies and defect dipoles.",

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T1 - Improving Energy Storage Properties of Barium Zirconate Titanate Ceramics via Defect Dipole Engineering

AU - Wang, Zhiyi

AU - Qin, Zhengchao

AU - Gao, Si

AU - Zheng, Hongjuan

AU - Luo, Jin

AU - Liu, Yunfei

AU - Lyu, Yinong

PY - 2025/6

Y1 - 2025/6

N2 - Lead-free ceramic materials have been widely studied since dielectric capacitors became a key component for energy storage. In this work, we adopted defect dipole engineering and improved the energy storage performance of barium zirconate titanate (BZT) ceramics by doping them with MnO2. With the increase in Mn content, the hysteresis loop changed from a conventional loop to a pinned hysteresis loop, resulting in a decrease in remnant polarization (Pr). When x = 0.02, the recoverable energy storage density (Wrec) reached 0.1561 J/cm2 @ 40 kV/cm, a 59% increase from undoped BZT. Further, XPS and EPR analyses confirmed that many oxygen vacancies were generated. We also performed SEM and TEM characterization and observed the microstructures. These results are consistent with theories suggesting that the formation of the pinned hysteresis loop is attributable to oxygen vacancies and defect dipoles.

AB - Lead-free ceramic materials have been widely studied since dielectric capacitors became a key component for energy storage. In this work, we adopted defect dipole engineering and improved the energy storage performance of barium zirconate titanate (BZT) ceramics by doping them with MnO2. With the increase in Mn content, the hysteresis loop changed from a conventional loop to a pinned hysteresis loop, resulting in a decrease in remnant polarization (Pr). When x = 0.02, the recoverable energy storage density (Wrec) reached 0.1561 J/cm2 @ 40 kV/cm, a 59% increase from undoped BZT. Further, XPS and EPR analyses confirmed that many oxygen vacancies were generated. We also performed SEM and TEM characterization and observed the microstructures. These results are consistent with theories suggesting that the formation of the pinned hysteresis loop is attributable to oxygen vacancies and defect dipoles.

KW - BZT

KW - ceramics

KW - defect dipoles

KW - ferroelectric

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VL - 18

JO - Materials

JF - Materials

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ER -

Improving Energy Storage Properties of Barium Zirconate Titanate Ceramics via Defect Dipole Engineering

Abstract

Keywords

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