| Autor: |
Ryou H; American Society for Engineering Education Postdoctoral Research Fellow sited at the U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Drazin JW; American Society for Engineering Education Postdoctoral Research Fellow sited at the U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Wahl KJ; Chemistry Division , U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Qadri SB; Material Science & Technology Division , U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Gorzkowski EP; Material Science & Technology Division , U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Feigelson BN; Electronics Science & Technology Division , U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States., Wollmershauser JA; Material Science & Technology Division , U.S. Naval Research Laboratory , Washington , D.C. 20375 , United States. |
| Abstrakt: |
Reducing the grain size of metals and ceramics can significantly increase strength and hardness, a phenomenon described by the Hall-Petch relationship. The many studies on the Hall-Petch relationship in metals reveal that when the grain size is reduced to tens of nanometers, this relationship breaks down. However, experimental data for nanocrystalline ceramics are scarce, and the existence of a breakdown is controversial. Here we show the Hall-Petch breakdown in nanocrystalline ceramics by performing indentation studies on fully dense nanocrystalline ceramics fabricated with grain sizes ranging from 3.6 to 37.5 nm. A maximum hardness occurs at a grain size of 18.4 nm, and a negative (or inverse) Hall-Petch relationship reduces the hardness as the grain size is decreased to around 5 nm. At the smallest grain sizes, the hardness plateaus and becomes insensitive to grain size change. Strain rate studies show that the primary mechanism behind the breakdown, negative, and plateau behavior is not diffusion-based. We find that a decrease in density and an increase in dissipative energy below the breakdown correlate with increasing grain boundary volume fraction as the grain size is reduced. The behavior below the breakdown is consistent with structural changes, such as increasing triple-junction volume fraction. Grain- and indent-size-dependent fracture behavior further supports local structural changes that corroborate current theories of nanocrack formation at triple junctions. The synergistic grain size dependencies of hardness, elasticity, energy dissipation, and nanostructure of nanocrystalline ceramics point to an opportunity to use the grain size to tune the strength and dissipative properties. |
