Micro-mechanical deformation behavior of heat-treated laser powder bed fusion processed Ti-6Al-4V

Industrial implementation of heat-treated Laser Powder Bed Fusion (L-PBF) processed Ti-6Al-4 V components requires a thorough understanding of the plastic deformation mechanisms to predict the part performance in safety-critical environments. Here, we study the micro-mechanical deformation behavior of a heat-treated L-PBF processed Ti-6Al-4 V by in-situ uniaxial tensile loading, during which high-resolution strain fields were monitored by Scanning Electron Microscope (SEM) based Digital Image Correlation (DIC). SEM-DIC revealed: (i) the transformed beta phase accommodates higher strain than the primary alpha phase; (ii) strain accumulation in primary alpha occurs primarily at the interface regions where the Al content is lower; and (iii) needle-shaped secondary alpha precipitate in the transformed beta creates strain localization pathways that bridge the interfacial strain bands. Based on the in-situ deformation behavior, recommendations are made on microstructure tailoring and alloy design to prevent strain localization and enhance the quasi-static mechanical properties of L-PBF processed titanium alloy components.

Automated summary

The plastic deformation mechanisms of heat-treated L-PBF processed Ti-6Al-4V components were studied by in-situ uniaxial tensile loading, revealing the accommodation of higher strain in the transformed beta phase, strain accumulation in primary alpha at interface regions with lower Al content, and strain localization pathways created by needle-shaped secondary alpha precipitates.