The Effect of Electrical Boundary Conditions on the Thermal Properties of Ferroelectric Piezoelectric Ceramics

TL;DR

This study investigates how electrical boundary conditions and poling affect the thermal conductivity of PZT ferroelectric ceramics, revealing that short circuit conditions enhance thermal conductivity and highlighting the relationship with electrothermal coupling.

Contribution

It provides new insights into the influence of electrical boundary conditions on thermal properties of ferroelectric ceramics, linking thermal conductivity to electrothermal coupling factors.

Findings

Short circuit thermal conductivity is higher than open circuit.

Unpoled PZT has the lowest thermal conductivity.

Thermal conductivity relates to electrothermal coupling and phonon scattering.

Abstract

The thermal conductivity of polycrystalline bulk PZT (lead-zirconate-titanate) has been investigated according to electrical boundary conditions and poling. The thermal conductivity of poled PZT was measured in the poling direction for open circuit and short circuit conditions. The short circuit thermal conductivity had the largest thermal conductivity. The relationship between these two thermal properties, the electrothermal coupling factor $k_{33}^{\kappa}$, was found to be similar to the electromechanical coupling factor $k_{33}$ relating elastic compliance under short circuit and open circuit conditions. The thermal conductivity of the unpoled sample was found to have the lowest thermal conductivity. The significance of the thermal conductivity with regards to phonon mode scattering and elastic compliance was discussed.