AI Article Synopsis
- The study investigates how heat treatment affects the microstructure of steel, focusing on austenite nucleation and grain growth.
- It reveals that the recrystallization of the ferrite matrix during annealing enhances the conditions for austenite formation, but also slows down the overall recrystallization process around the austenite grains.
- The results show that austenite grain size increases slightly with higher annealing temperatures, but larger grains grow faster due to their relationship with the matrix, which can be influenced by specific orientation constraints.
Article Abstract
The effects of heat treatment on the microstructure evolution was studied in regards to austenite nucleation and grain growth. It was found that the austenite nucleation and matrix recrystallization kinetics of samples annealed at 675 °C for different times were revealed, implying a strong interaction between the ferrite matrix and austenite was revealed. The recrystallization of the matrix during annealing provided favorable conditions for austenite nucleation and growth, and the formation of austenite during this process reduced the matrix recrystallization kinetics, thus delaying the recrystallization process of the matrix around the austenite grains. The statistical results for the austenite grain size under different annealing temperatures indicated that the average grain size of the austenite slightly increases with increasing of the annealing temperature, but the austenite with the largest grain size grows faster at the same temperature. This difference is attributed to the strict Kurdjumov Sachs (KS) orientation relationship (OR) between the austenite grains and the matrix, because the growth of austenite with a strict KS OR with the matrix is often inhibited during annealing. In contrast, the austenite maintains a non-strict KS OR with the matrix and can grow preferentially with increasing annealing temperature and time.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7436018 | PMC |
| http://dx.doi.org/10.3390/ma13153366 | DOI Listing |
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