Layer-defect toughened hierarchically structured diamond composites
XL Ma and LP Shi and L Yang and J Yi and B Wang and MW Li and B Zheng and CY Hou and L Ye and YS Zhong and XD He, ENGINEERING FRACTURE MECHANICS, 279, 109052 (2023).
DOI: 10.1016/j.engfracmech.2023.109052
Recently synthesized diamond composites containing interfaced polytypes, nanograins, and nanotwins show exceptional fracture toughness. Layer defects with enlarged interlayer distances and substantial sp2 bonding are commonly observed in such diamond composites. By using mo-lecular dynamics simulations, we demonstrate that twin boundaries and phase boundaries have limited effect on toughening of the diamond composite. A diamond toughening mechanism that inhibits crack propagation and reduces crack tip stress intensity by introducing layer defects is demonstrated. Stress concentration around the crack tip can cleave nonpenetrating layer defects into partially deflected cracks, which dissipate fracture energy and stress concentration over a larger space region compared with a defect-free model, increasing fracture toughness. The toughening mechanism offers fundamental insight into understanding the fracture toughness of hierarchically structured diamond and is verified via comparison to previously published experimental results. The tradeoff between hardness and toughness in diamond composites may eventually be overcome by introducing these uniformly distributed layer defects.
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