Dynamic Hardness Evolution in Metals from Impact Induced Gradient Dislocation Density

A clear understanding of the dynamic behavior of metals is critical for developing superior structural materials as well as for improving material processing techniques such as cold spray and shot peening. Using a high-velocity (from-120 m/s to 700 m/s; strain rates >107 1/s) micro-projectile impact testing and quasistatic (strain rates: 10-2 1/s) nanoindentation, we investigate the strain-rate-dependent mechanical behavior of single-crystal aluminum substrates with (001), (011), and (111) crystal orientations. For all three crystal orientations, the dynamic hardness initially increases with increasing impact velocity and reaches a plateau regime at hardness 5 times higher than that of at quasistatic indentations. Based on coefficient of restitution and post-mortem transmission Kikuchi diffraction analyses, we show that distinct plastic deformation mechanisms with a gradient dislocation density evolution govern the dynamic behavior. We also discover a distinct deformation regime-stable plastic regime-that emerges beyond the deeply plastic regime with unique strain rate insensitive microstructure evolution and dynamic hardness. Our work additionally demonstrates an effective approach to introduce strong spatial gradients in dislocation density in metals by high-velocity projectile impacts to enhance surface mechanical properties, as it can be employed in material processing techniques such as shot peening and surface mechanical attrition treatment.

Automated summary

We investigate the strain-rate-dependent mechanical behavior of single-crystal aluminum with different crystal orientations using high-velocity micro-projectile impact testing and quasistatic nanoindentation. The dynamic hardness initially increases with impact velocity and reaches a plateau at a higher hardness than that of quasistatic indentations. Different plastic deformation mechanisms with a gradient dislocation density evolution govern the dynamic behavior. Beyond the deeply plastic regime, a stable plastic regime with unique microstructure evolution and dynamic hardness is discovered. This work demonstrates an effective approach to introduce strong spatial gradients in dislocation density in metals to enhance surface mechanical properties.