Abstract
The study investigated the nanofabrication behavior of TiAl alloys with a duplex structure of γ/α 2. The process included downward pressure followed by reciprocating friction with diamond grinding balls and was simulated using molecular dynamics (MD). It was found that a certain number of dislocations in the workpiece was low, and the resilience was high during the initial pressing stage. The dislocations increased, the resilience decreased, and the plastic deformation capacity was enhanced under continuous pressing. The α 2 phase did not deform significantly during the compression process. The presence of the α 2 phase increases the overall hardness of the material, and elastic-plastic deformation occurs mainly where the γ phase is present; the endowment layer dislocations generated during the intrinsic stacking fault rebound via the phase boundary to form V-shaped dislocations. During the reciprocating friction of the workpiece, forward friction produces V-shaped dislocations, and reverse friction makes the dislocations disappear. This process results in the forward average friction force being more significant than the reverse average. γ/α 2 phase boundary has an impeding effect on the downward proliferation of defects, and the phase boundary makes the temperature transfer appear discontinuous. During friction, the specific number of vacancy atoms in the γ-phase increases, and the transition between FCC and HCP occurs.
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