TY  - EJOU
AU  - Hu, Chen-Xi 
AU  - Jiang, Wu-Gui 
AU  - Wang, Jin 
AU  - He, Tian-Yu 

TI  - Mechanisms of Pore-Grain Boundary Interactions Influencing Nanoindentation Behavior in Pure Nickel: A Molecular Dynamics Study
T2  - Computers, Materials \& Continua

PY  - 2026
VL  - 86
IS  - 1
SN  - 1546-2226

AB  - THE mechanical response and deformation mechanisms of pure nickel under nanoindentation were systematically investigated using molecular dynamics (MD) simulations, with a particular focus on the novel interplay between crystallographic orientation, grain boundary (GB) proximity, and pore characteristics (size/location). This study compares single-crystal nickel models along [100], [110], and [111] orientations with equiaxed polycrystalline models containing 0, 1, and 2.5 nm pores in surface and subsurface configurations. Our results reveal that crystallographic anisotropy manifests as a 24.4% higher elastic modulus and 22.2% greater hardness in [111]-oriented single crystals compared to [100]. Pore-GB synergistic effects are found to dominate the deformation behavior: 2.5 nm subsurface pores reduce hardness by 25.2% through stress concentration and dislocation annihilation at GBs, whereas surface pores enable mechanical recovery via accelerated dislocation generation post-collapse. Additionally, size-dependent deformation regimes were identified, with 1 nm pores inducing negligible perturbation due to rapid atomic rearrangement, in contrast with persistent softening in 2.5 nm pores. These findings establish atomic-scale design principles for defect engineering in nickel-based aerospace components, demonstrating how crystallographic orientation, pore configuration, and GB interactions collectively govern nanoindentation behavior.
KW  - Pure nickel; nanoindentation; molecular dynamics; pore; grain boundary

DO  - 10.32604/cmc.2025.068655