Unusual hardening in Ti/Al2O3 nanocomposites produced by high-pressure torsion followed by annealing

Nanocomposites of Ti–18 vol.% Al2O3 were fully consolidated by applying severe plastic deformation to powder mixtures using high-pressure torsion (HPT). The HPT-processed composites exhibited an unusual increase in the hardness from 350 Hv to 650 Hv when they were annealed at 973 K for 1 h. Microstructural observations including elemental mappings were conducted using scanning electron microscopy with an electron probe X-ray micro-analyzer and scanning transmission electron microscopy with an energy dispersive X-ray spectrometer. It was shown that the Al2O3 particles are fragmented and the grain size of the Ti matrix is reduced to the nanometer level (<100 nm) after processing with HPT. Following the annealing, the fragmented Al2O3 particles with particle sizes less than ∼400 nm are reduced to Al in the Ti matrix and the average grain size of Ti is coarsened to ∼500 nm in conflicting with the hardness increase. The hardness increase after annealing is attributed to the dissolution of Al and O atoms in the Ti-matrix and the formation of reaction product, Ti3Al intermetallic, at the interface and improvement of mechanical connectivity. Enrichment of Al along grain boundaries confirmed that Al atoms diffuse fast through the grain boundaries and move towards the grain interior from the grain boundaries.

► Nanocomposites of Ti–18 vol.% Al2O3 are consolidated by high-pressure torsion (HPT). ► Nanocomposite exhibits an unusual increase in the hardness from 350 Hv to 650 Hv by annealing. ► The Al2O3 particles are dissolved in Ti and the Ti grain size is increased to ∼500 nm after annealing. ► Dissolved Al atoms diffuse in the Ti matrix mainly through the grain boundaries. ► Solution hardening and formation of Ti3Al at the interface result in hardness increase after annealing.