Abstract:
The Pb-free complex perovskite Ca(Fe1/2Nb1/2)O3 is a promising material for technological applications, featuring a nearly temperature-independent large dielectric constant over a broad range of temperatures and frequencies. This study explores the structure and low temperature dynamics of this system using multiple experimental techniques. X-ray diffraction analysis confirms the formation of a single-phase sample with an orthorhombic crystal structure in the Pbnm space group, which remains stable down to 12 K. DC susceptibility measurements reveal a bifurcation between zero-field-cooled warming and field-cooled warming curves at the irreversibility temperature (Tirr ≈ 27 K), with a peak at the freezing temperature (Tf ≈ 25 K), indicating glassy dynamics. Specific heat analysis reveals that below Tf, paramagnons co-exist with the glassy phase, whereas above Tf, the system follows the paramagnon model. This study provides new insights into the low-temperature dynamics of Pb-free complex perovskites of the form A(Fe1/2B1/2)O3, where A = Ca, Sr, or Ba, and B = Nb, Ta, or Sb.