The effect of temperature and microstructure on dynamic deformation of iron, tantalum, and titanium

Laser-driven shock loading was performed on thin samples of iron, tantalum, and titanium at strain-rates up to 10⁷ s^–1, and over a range of temperatures extending from 120 through 800 K, to investigate the influence of temperature on the early stages of yielding and plastic flow in materials of distinct crystal structure and initial defect density. The onset of yielding was identified using time-resolved velocimetry of the target rear surface to reveal the peak elastic state in the precursor wave front. Measurements on as-received iron reveal a trend of decreasing peak elastic stress (σE) with increasing temperature and electron microscopy of the recovered material revealed evidence of mobile dislocations coalescing into subgrains. This is in contrast to the results for the annealed iron where theσEremains constant with increasing temperature and recovered samples showed indications of deformation twinning. For tantalum, the yield strength remains constant for the most part, but has a jump in yield strength at 815 K, indicative of a possible twinning to slip transition with increasing temperature. For titanium, the yield strength was generally constant with temperature. Here, these results provide insight into studying deformation mechanisms, such as slip and twinning, in high rate loading of materials.