Lattice strain development in an alpha titanium alloy studied using synchrotron and neutron diffraction

Neutron and high-energy X-ray diffraction methods have been used to investigate deformation mechanisms (slip and twinning activities) during uniaxial tensile tests of Grade 1 commercially pure titanium (Ti-alpha). These two diffraction techniques have provided valuable and complementary information. The predictions made by an Elasto-Plastic Self-Consistent (EPSC) model, taking into account grain reorientation and stress relaxation induced by twinning activity, have been compared with the experimental data. Results clearly demonstrate that there is a good agreement between simulations and diffraction measurements. The EPSC model enables accurate predictions of: (i) the lattice strains developed in variously oriented {hk.l} grain families within the bulk material, (ii) the grain reorientation induced by twinning activity and (iii) the macroscopic stress-strain response. Two different textured products were studied in order to evaluate the influence of texture on the mesoscopic and macroscopic responses of Ti-alpha alloy.

Automated summary

Neutron and high-energy X-ray diffraction methods were used to investigate deformation mechanisms during uniaxial tensile tests of Grade 1 commercially pure titanium. Results showed good agreement between simulations and experimental data, and the EPSC model accurately predicted lattice strains, grain reorientation, and macroscopic stress-strain response. Study on two different textured products evaluated the influence of texture on mesoscopic and macroscopic responses of Ti-alpha alloy.