Phase transition and twinning in polycrystals probed by in situ high temperature 3D reciprocal space mapping

Polycrystalline materials exhibit physical properties that are driven by both the interatomic crystallographic structure as well as the nature and density of structural defects. Crystallographic evolutions driven by phase transitions and associated twinning process can be observed in situ in three-dimensional (3D) using monochromatic synchrotron radiation at very high temperatures (over 1000 & DEG;C). This paper focuses on continuous measurements of the 3D-reciprocal space maps by high-resolution x-ray diffraction as a function of temperature along a phase transition process occurring between 1200 & DEG;C and room temperature. These high precision measurements allow observing the reciprocal space node splitting and the evolution of the diffuse scattering signal around that node as a function of temperature. The capability of this experimental method is illustrated by direct in situ high temperature measurements of the 3D splitting of a reciprocal space node due to phase transition recorded on dense pure zirconia polycrystals.

Automated summary

This paper focuses on the continuous measurement of the crystallographic evolution in polycrystalline materials using high-resolution x-ray diffraction. Through observing the structure changes at high temperatures, the characteristics of reciprocal space node splitting and scattering signal evolution during phase transitions are explored.