Microstructure and texture development in single layered and heterolayered PZT thin films

Single-layered Pb(Zr_0.7Ti_0.3)O₃ and Pb(Zr_0.3Ti_0.7)O₃ thin films and heterolayered Pb(Zr_1−x Ti _x )O₃ thin films consisting of alternating Pb(Zr_0.7Ti_0.3)O₃ and Pb(Zr_0.3Ti_0.7)O₃ layers were studied for their microstructure and texture development. The texture in the single-layered PZT films is affected by the Zr/Ti ratio as they have different crystallization behavior depending on the Zr/Ti ratio. With increasing film thickness, the average grain size of Pb(Zr_1−x Ti _x )O₃ increases. An unusually large grain size of 1–3 μm together with a strong (001)/(100) preferred orientation were observed for the heterolayered PZ₇₀T₃₀, whereby Pb(Zr_0.7Ti_0.3)O₃ was used as the seeding layer, for film as thin as 150 nm. The film microstructure is refined drastically when the stacking sequence is changed, i.e., when Pb(Zr_0.3Ti_0.7)O₃ is employed as the seeding layer. Thermal treatment of the PZ₇₀T₃₀ seeding layer also plays an important function in the microstructure development of the heterolayered PZ₇₀T₃₀ film. The formation of the large-grained film is correlated to the lowered nucleation energy of crystallizing Pb(Zr_0.7Ti_0.3)O₃ by the top Pb(Zr_0.3Ti_0.7)O₃. The Pb(Zr_0.3Ti_0.7)O₃ layer facilitated the nucleation and crystallization of the Pb(Zr_0.7Ti_0.3)O₃ amorphous seeding layer, whereby the overall microstructure of the heterolayered thin film was dictated by the Pb(Zr_0.7Ti_0.3)O₃ seeding layer leading to the growth of larger PZT grains.