According to conventional X-ray measurements, PbTiO$_3$ undergoes a phase transition from a tetragonal ferroelectric phase to a cubic paraelectric phase at 763 K. However, x-ray absorption fine-structure (XAFS) measurements indicate that PbTiO$_3$ is tetragonal even after the phase transition has occurred. The difference in these results concerns the length scales accessible to each measurement technique: millimeters for X-ray and Angstroms for XAFS. For both of these measurements to be consistent, PbTiO$_3$ is macroscopically cubic but still locally tetragonal above the phase transition temperature. Despite this, most models, such as the Laundau-Ginsburg-Devonshire theory, are still unable to explain this phenomenon. Moreover, these methods involve model parameters fitted to experimental or theoretical data and do not consider other tetragonal configurations, such as domain walls, to predict the phase transition. In this study, we use our novel zentropy approach to predict the phase transition, which allows us to calculate the total entropy of a system without fitted parameters, taking only inputs from density functional theory calculations through energy-volume curves and phonon calculations. Our approach also considers the tetragonal 90{\deg} and 180{\deg} domain walls and the ferroelectric ground state in predicting the phase transition. The predicted phase transition using the metaGGA $r^2\text{SCAN}$ occurs at 830 K, showing good agreement with the experimental value of 763 K. It is the subject of future work to show that the statistical average of these tetragonal configurations at the phase transition will result in the cubic phase.
Comment: 21 pages, 7 Figures, 1 Table, TMS 2024