Mircomechanical insights into unconstrained grain boundary sliding

Abstract

Grain boundary sliding (GBS) is a key deformation mechanism at high homologous temperatures in polycrystalline materials, however, its intrinsic behavior is often obscured by additional strain accommodation processes. In this study, dislocation-mediated unconstrained GBS was investigated using Ni bicrystal micropillars containing a single high-angle grain boundary. Micropillar compression tests were conducted over a temperature range from room temperature to 600\,C and strain rates between 5×10-4 and 10-1\,s-1. By comparing bicrystal and single-crystal responses, the intrinsic contribution of GBS was isolated. The strain-rate sensitivity remained low (SRS ≈ 0.034 0.017), comparable to room temperature values, indicating the absence of diffusion-controlled accommodation mechanisms. The activation energy for GBS was determined to be 234\,kJ\,mol-1, consistent with grain boundary diffusion-assisted glide of grain boundary dislocations. These results demonstrate that the high strain-rate sensitivity commonly associated with GBS in polycrystals originates primarily from accommodation processes rather than the intrinsic sliding mechanism.