Understanding A and B-site engineered lead-free Ba(1-x)CaxZryTi(1-y)O3 piezoceramics: a perspective from DFT

Density functional theory (DFT) was used to investigate the structure and polarization of lead-free piezoelectric, Ba(1-x)CaxZryTi(1-y)O3, perovskite solid solutions, namely BaTiO3 (BT), Ba(Zr0.125Ti0.875)O-3 (BZT), (Ba0.875Ca0.125)TiO3 (BCT) and Ba0.875Ca0.125(Zr0.125Ti0.875)O-3 (BCZT). Here, we focus on understanding the effect of the simultaneous substitution of Ca and Zr in the BT lattice on structural and polarization behaviour. During the calculations a BT supercell was allowed to relax with substitution of Ca and Zr individually as well as simultaneously to obtain new atomic positions and lattice vectors. The density of states was calculated for all the compositions and the effect of Ca and Zr ions on O 2p and Ti 3d hybridization was studied along with their band gap. Berry phase calculations were performed to understand the polarization behaviour, and phonon dispersion calculations were also performed to understand the structural stability of BCZT compositions. The compositions investigated by DFT calculations were synthesised by a solid oxide route and analysed using X-ray diffraction. Structural properties were obtained using DFT analysis and Rietveld refinement of BCZT; polarization obtained using Berry phase calculations and experimentally obtained ferroelectric behaviour were compared. Further dielectric and piezoelectric properties of BCZT were studied.

Automated summary

Density functional theory (DFT) was utilized to investigate the structure and polarization behavior of lead-free piezoelectric materials, focusing on the simultaneous substitution of Ca and Zr in the BaTiO3 lattice. Calculations, synthesis, and experimental comparisons were carried out to study the properties of Ba(1-x)CaxZryTi(1-y)O3 solid solutions. The study provided insights into the effect of Ca and Zr ions on the structural and polarization properties of the compositions.