Results and discussion After cooling in liquid nitrogen, the alloy contained 85% of martensite phase. Multiple γ-α-γ transformations by rapid cooling under the direct γ-α transformation and rapid heating under the reverse α-γ transformation did not lead to significant stabilization of the reverted austenite towards next γ-α transformation. So, after ten cycles of γ-α-γ transformations, the amount of martensite phase,
when cooled in liquid nitrogen, decreased by 5% to 7%, whereas after 50 cycles, by only 8% to 10%. The slight decrease of the martensite phase after repeated temperature cycling made it possible to achieve a high degree of phase hardening rate of the reverted austenite under γ-α-γ this website transformations and generate highly dispersed disoriented 3-deazaneplanocin A fragments of γ-phase. Electron microscope research have shown [17] that, after the first γ-α-γ transformation, dislocation density in reverted austenite increases by three orders and EPZ5676 chemical structure reaches the value of 5 × 1011 cm-2, which fully
agrees with [18]. Repeated γ-α-γ transformations slightly increase dislocation density achieved after the first cycle. In reverted austenite, there appear fragments with their size decreased, depending on the increasing number of γ-α-γ transformations, i.e., with the increase of phase hardening degree (Figure 1A). Simultaneously, we observed an increase of azimuthal reflections’ blurring of austenite at an early stage of thermal cycling (3 to 5 cycles) and subsequent
reflections’ partitioning on several components already after 5 to 8 thermocycles. The azimuthal blurring indicated the formation of additional Chorioepithelioma subboundaries with subsequent fragments formation. As the result of multiplied thermocycles, the fragment size reached a nanoscale level – a significant volume fraction of the fragments had a size range of 80 to 150 nm. Grain size was determined from electron micrographs. Further fragmentation rate significantly slowed down with increased number of thermocycles, and it was impossible to achieve a significant reduction of the minimum size of the fragments. The electron diffraction pattern of reverted austenite after 50 γ-α-γ transformations shows that all reflections are divided into several components (Figure 1B). This means that during thermocycling, a number of high angle fragments’ boundaries were formed, which thus became already dispersed grains in γ-phase. It is important to note that the formation of grains with high-angle boundaries was already present in the first 3 to 10 cycles of thermocycling, and under further thermocycling, this process has not gained significant development.