Nanomaterials (Aug 2022)

Bimodal-Structured 0.9KNbO<sub>3</sub>-0.1BaTiO<sub>3</sub> Solid Solutions with Highly Enhanced Electrocaloric Effect at Room Temperature

  • Hongfang Zhang,
  • Liqiang Liu,
  • Ju Gao,
  • K. W. Kwok,
  • Sheng-Guo Lu,
  • Ling-Bing Kong,
  • Biaolin Peng,
  • Fang Hou

DOI
https://doi.org/10.3390/nano12152674
Journal volume & issue
Vol. 12, no. 15
p. 2674

Abstract

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0.9KNbO3-0.1BaTiO3 ceramics, with a bimodal grain size distribution and typical tetragonal perovskite structure at room temperature, were prepared by using an induced abnormal grain growth (IAGG) method at a relatively low sintering temperature. In this bimodal grain size distribution structure, the extra-large grains (~10–50 μm) were evolved from the micron-sized filler powders, and the fine grains (~0.05–0.35 μm) were derived from the sol precursor matrix. The 0.9KNbO3-0.1BaTiO3 ceramics exhibit relaxor-like behavior with a diffused phase transition near room temperature, as confirmed by the presence of the polar nanodomain regions revealed through high resolution transmission electron microscope analyses. A large room-temperature electrocaloric effect (ECE) was observed, with an adiabatic temperature drop (ΔT) of 1.5 K, an isothermal entropy change (ΔS) of 2.48 J·kg−1·K−1, and high ECE strengths of |ΔT/ΔE| = 1.50 × 10−6 K·m·V−1 and ΔS/ΔE = 2.48 × 10−6 J·m·kg−1·K−1·V−1 (directly measured at E = 1.0 MV·m−1). These greatly enhanced ECEs demonstrate that our simple IAGG method is highly appreciated for synthesizing high-performance electrocaloric materials for efficient cooling devices.

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