Abstract
Molecular dynamics (MD) simulations are employed to probe the crystallization and precipitation behaviors in FeCu alloys. The alloys will undergo liquid phase separation at high temperature, after which α-Fe nucleates preferentially, then metastable Cu solid solutions in BCC lattice (ε` phase) nucleate and transform into FCC structure (ε-Cu) via martensite phase transformation immediately. Reversible order-disorder transformation behavior is observed during time-consuming crystallization process of ε-Cu. Interestingly, the ε`-Cu with only approximately three atomic layers in thickness exists stably near BCC/FCC α/ε interface at room temperature, following the Kurdjumov–Sachs (K–S) orientation relationship. The lower nucleation energy and interface energy are the reasons for the existence of abnormal ε`-Cu at the interface. It is also found that the composition and cooling rate play key roles on the final phase structure. The alloys can be fully crystallized upon cooling down at a rate of 0.1 K/ps.
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