Compression behavior of TiB2-particulate-reinforced composites of Al22Fe3Ti8

Abstract

The compression behavior of both the monolithic L1₂ compound Al₂₂Fe₃Ti₈ and discontinuous composites obtained by incorporating ∼1 μm TiB₂ particles was studied for various volume percent reinforcements as a function of temperature and at high temperatures as a function of strain rate. In this study, by varying the Fe and Ti contents, the nature and volume fraction of the minor phases coexisting with the dominant L1₂ phase were changed and were examined with and without TiB₂ reinforcement. At high strain rates (10⁻⁴ s⁻¹), the TiB₂ reinforcements significantly enhance ambient and warm-temperature strength, although a crossover is observed at ∼1000 K, above which the monolithic material is stronger than the composite. At slow strain rates (10⁻⁷ s⁻¹), representative of creep conditions, however, the TiB₂-containing composites retain their superiority at least up to 1200 K. Power law fits of compressive flow stress at 1% strain versus strain rate yielded a stress exponent of ∼3.0 with an activation energy of 310 kJ/mol for the monolithic material. For the particulate composites (20 vol. % TiB₂), the corresponding values were ∼5.0 and 465 kJ/mol, suggesting a change in the dominant deformation mechanism.