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Innovative Design of BNKT-<i>x</i>SLZT Ceramics: Maximizing the Polarization Difference for Enhanced Energy Storage

Kaili Shang, Wenjing Shi, Yule Yang, Yunyao Huang, V. Ya. Shur, В. М. Лалетин, Leiyang Zhang, Ruiyi Jing, Li Jin

2024ACS Applied Materials & Interfaces12 citationsDOI

Abstract

Lead-free relaxor ferroelectric ceramics with outstanding energy-storage (ES) density ( W rec ) and high ES efficiency ( η ) are crucial for advanced pulse-power capacitors. This study introduces a strategic approach to maximizing the polarization difference (Δ P ) by inducing a transition from the ferroelectric phase to the ergodic relaxor (ER) phase. By employing this strategy, a series of ceramics, (1 – x )(Bi 0.5 Na 0.4 K 0.1 )TiO 3 - x (Sr 0.85 La 0.1 )(Zr 0.5 Ti 0.5 )O 3 (BNKT- x SLZT), with varying SLZT content ( x = 0.05, 0.10, 0.15, and 0.20), were designed. The addition of SLZT enhances cationic disorder, induces vacancies at A sites, and disrupts long-range ferroelectric order, facilitating the formation of polar nanoregions and enhancing relaxor ferroelectric behavior. Furthermore, a viscous polymer process (VPP) technology is employed to optimize the ceramics’ structure, aiming to increase the breakdown strength ( E b ) and enhance Δ P . Ultimately, enhanced ES performance is demonstrated in BNKT-0.15SLZT VPP, achieving a remarkable W rec of 6.85 J/cm 3 and η of 84% under 470 kV/cm. This composition demonstrates excellent stability with minimal variations in W rec (3.0%) and η (4.4%) over the temperature range of 20–110 °C. Additionally, BNKT-0.15SLZT VPP exhibits exceptional pulse charge–discharge properties, featuring a high discharge density of 3.72 J/cm 3, a large power density of 164.2 MW/cm 3, and a short discharge time ( t 0.9 ) of 193 ns under 300 kV/cm. The study validates the practicality of BNKT-0.15SLZT VPP for pulse capacitors and underscores the potential to enhance ES performance through A-site donor doping and VPP technology. This work provides a comprehensive understanding of the interplay among composition, structure, and ES properties in lead-free relaxor dielectric ceramics, laying the groundwork for innovative advancements in the field.

Topics & Concepts

Materials scienceCapacitorFerroelectricityPolarization (electrochemistry)Pulsed powerCeramicEnergy storageDielectricOptoelectronicsNanotechnologyComposite materialVoltagePower (physics)Electrical engineeringThermodynamicsPhysical chemistryChemistryPhysicsEngineeringFerroelectric and Piezoelectric MaterialsDielectric materials and actuatorsMicrowave Dielectric Ceramics Synthesis