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| Autores principales: | , , |
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| Formato: | Preprint |
| Publicado: |
2024
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| Materias: | |
| Acceso en línea: | https://arxiv.org/abs/2410.18139 |
| Etiquetas: |
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- The strength, $σ_{\rm y}$, of a polycrystal decreases with mean grain diameter $D$ at $D\gtrsim50$ atoms (i.e. Hall-Petch behaviour) and increases at $D\lesssim50$ (i.e. inverse Hall-Petch behaviour). Our simulations generalise $σ_{\rm y}(D)$ to $σ_{\rm y}(D,l)$, where $l$ is the mean thickness of grain boundaries. For various particle compositions, the maximum strength is reached at $(D,l)\simeq(50, 6)$ particles for single-component face-centred-cubic solids and at $(D,l)\simeq(50, 2)$ for bidispersed or body-centred-cubic solids because of the different activation stresses of dislocation motions. The results explain recent alloy experiments and provide a way to exceed the maximum strength of polycrystals. Ductility and elastic moduli are also measured in the broad $(D,l)$ space. The regimes without a strength-ductility trade-off, the maximum ductility and ductile--brittle transitions are identified. These results obtained in $(D,l)$ space are important in solid mechanics and can guide the fabrication of crystalline-amorphous composites with outstanding mechanical properties.