Phase transition, microstructure and electrical properties of K1‐xNaxNbO3‐based ceramic sintered in reducing atmosphere

Abstract

AbstractLead‐free 0.955K1‐xNaxNbO3‐0.045Bi0.5Na0.5ZrO3+0.4% mol MnO ceramics (Abbreviated as K1‐xNxN‐0.045BNZ+0.4Mn) were prepared by a conventional solid‐state sintering method in a reducing atmosphere (oxygen partial pressure : 1 × 10−11 MPa). All K1‐xNxN‐0.045BNZ+0.4Mn samples show a pure perovskite structure with a polymorphic phase boundary (PPB) composed of rhombohedral (R) and tetragonal (T) phases. A high Na/K ratio and a low Na/K ratio can both induce an increase in the rhombohedral phase. The reverse piezoelectric coefficient and its temperature stability in K1‐xNxN‐0.045BNZ+0.4Mn ceramics can be improved by controlling the Na/K ratio. The increase in the Na/K ratio from x = 0.46 to x = 0.56 can decrease the A‐site cation vacancies. The activation energy of the grain is higher than that of the grain boundary due to the accumulation of oxygen vacancies at the grain boundary. K1‐xNxN‐0.045BNZ+0.4Mn ceramics with excellent piezoelectric properties (quasi‐static piezoelectric coefficient d33 = 326 pC/N, and = 472 pm/V at Emax = 25 kV/cm) were obtained at x = 0.52.