R. Qu, R. Maaß, Zengqian Liu, D. Tönnies, L. Tian, R. Ritchie, Zhefeng Zhang, C. Volkert
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引用次数: 18
Abstract
Brittle materials, such as oxide glasses, are usually very sensitive to flaws, giving rise to a macroscopic fracture strength that is much lower than that predicted by theory. The same applies to metallic glasses (MGs), with the important difference that these glasses can exhibit certain plastic strain prior to catas- trophic failure. Here we consider the strongest metallic alloy known, a ternary Co 55 Ta 10 B 35 MG. We show that this macroscopically brittle glass is flaw-insensitive at the micrometer scale. This discovery emerges when testing pre-cracked specimens with self-similar geometries, where the fracture stress does not de- crease with increasing pre-crack size. The fracture toughness of this ultra-strong glassy alloy is further shown to increase with increasing sample size. Both these findings deviate from our classical under- standing of fracture mechanics, and are attributed to a transition from toughness-controlled to strength- controlled fracture below a critical sample size.
脆性材料,如氧化玻璃,通常对缺陷非常敏感,导致其宏观断裂强度远低于理论预测。这同样适用于金属玻璃(mg),重要的区别是,这些玻璃在失营养衰竭之前可以表现出一定的塑性应变。这里我们考虑已知最强的金属合金,三元Co 55 Ta 10 B 35 MG。我们证明了这种宏观脆性玻璃在微米尺度上是缺陷不敏感的。这一发现出现在测试具有自相似几何形状的预裂试样时,其中断裂应力不会随着预裂尺寸的增加而减小。该合金的断裂韧性随试样尺寸的增大而增大。这两个发现都偏离了我们对断裂力学的经典理解,并归因于临界样本量以下从韧性控制断裂到强度控制断裂的转变。
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