The lattice strain behavior of osmium diboride—a member of a group of third-row transition metal borides associated with hard/superhard behavior—has been studied using radial diffraction in a diamond anvil cell under high pressure and non-hydrostatic stress. We interpret the average values of the measured lattice strains as a lower-bound to the lattice-plane dependent yield strengths using existing estimates for the elastic constants of OsB2, with a yield strength of 11 GPa at 27.5 GPa of hydrostatic pressure. The measured differential lattice strains show significant plane-dependent anisotropy, with the (101) lattice plane showing the largest differential strain and the (001) lattice plane showing the least strain. At the highest pressure, the a-axis develops a larger compressive strain and supports a larger differential strain than either the b or c axes. This causes an increase in the c/a ratio and a decrease in the a/b ratio especially in the maximum stress direction. The large strength anisotropy of this material points to possible ways to modulate directional mechanical properties by taking advantage of the interplay between aggregate polycrystalline texture with directional mechanical properties.
Lattice strain of osmium diboride under high pressure and nonhydrostatic stress
Abby Kavner, Michelle B. Weinberger, Anat Shahar, Robert W. Cumberland, Jonathan B. Levine, Richard B. Kaner, Sarah H. Tolbert; Lattice strain of osmium diboride under high pressure and nonhydrostatic stress. J. Appl. Phys. 1 July 2012; 112 (1): 013526. https://doi.org/10.1063/1.4730780
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