Impact of long-term thermal exposure on the microstructure and creep resistance of (TiB+TiC+Y2O3)/α-Ti composite.

In this study, the influences of thermal exposure on the microstructure and creep resistance of matrix alloy and (TiB+TiC+Y 2 O 3)/α-Ti composites were systematically studied. The results indicate that long-term thermal exposure leads to β-Ti dissolution, as well as the precipitation of a large number of S1 type silicides and α 2 particles. The high temperature and internal stress by thermal exposure promote β-Ti→α-Ti phase transition. In order to reduce the total energy, nanoscale {10 1 ̅ 1} transformation twins were formed at the α/β interfaces. The introduction of precipitates and nano twins leads to a significant improvement in the creep resistance after thermal exposure. The creep life can be increased by up to 108 %, while the steady-state creep rate can be reduced by an order of magnitude. After creep, there was no significant increase in the size of precipitated silicides and α 2 particles. The rod-shaped S1 type silicide has a better pinning strengthening effect on dislocations than spherical S2 type silicide. Nano twins improve the stability of the α/β interfaces during creep. Some twins were coarsened after creep by merging mechanism. Twins and reinforcements provide nucleation sites for sub-grains during the creep process. • The characteristics of α 2 phases, silicides and nano twins after thermal exposure were investigated. • The reasons for the enhanced creep properties by thermal exposure were analyzed. • The response of silicides and nano twins to creep deformation were analyzed by TEM and HRTEM. • Dynamic recrystallization behavior based on DDRX and CDRX process were discussed. [ABSTRACT FROM AUTHOR]