Stabilization of the first-order phase transition character and Enhancement of the Electrocaloric Effect by NBT substitution in BaTiO$_3$ ceramics

TL;DR

This study demonstrates that NBT substitution in BaTiO$_3$ ceramics stabilizes the first-order phase transition and significantly enhances the electrocaloric effect, achieving a $ riangle T_{eff}$ of about 1.65 K under high electric field.

Contribution

It reveals that increasing NBT content maintains the first-order phase transition and boosts electrocaloric response in BaTiO$_3$ ceramics, combining enhanced tetragonality with relaxor behavior.

Findings

Enhanced electrocaloric temperature change (~1.65 K) at x=0.20 composition.

NBT substitution stabilizes first-order phase transition in BaTiO$_3$.

Increased tetragonality correlates with larger electrocaloric response.

Abstract

The electrocaloric properties of BaTiO$_3$-based lead-free ferroelectric materials have been widely investigated. One approach to achieving a large electrocaloric response is to exploit the substantial polarization change associated with the first-order phase transition at the Curie temperature. Following this strategy, we investigated the electrocaloric response of (1$-x$)BaTiO$_3$-$x$Na$_{0.5}$Bi$_{0.5}$TiO$_3$ (BT-NBT) ceramics for x = 0.05, 0.10, 0.20, and 0.30. In this BT-rich region of the solid solution, it is established that increasing the NBT content enhances the tetragonality of BaTiO$_3$. We show that this increase in tetragonality helps maintain the first-order nature of the phase transition and enables a correspondingly large electrocaloric response, despite the simultaneous enhancement of relaxor ferroelectric character with NBT substitution. A significantly large effective electrocaloric temperature change ($\Delta T_{\mathrm{eff}}$) of ~1.65 K was obtained for the x = 0.20 composition under an applied field of 40 kV/cm using direct electrocaloric measurements, in reasonable agreement with the indirect results.