Issue 4, 2024

High-pressure studies of size dependent yield strength in rhenium diboride nanocrystals

Abstract

The superhard ReB2 system is the hardest pure phase diboride synthesized to date. Previously, we have demonstrated the synthesis of nano-ReB2 and the use of this nanostructured material for texture analysis using high-pressure radial diffraction. Here, we investigate the size dependence of hardness in the nano-ReB2 system using nanocrystalline ReB2 with a range of grain sizes (20–60 nm). Using high-pressure X-ray diffraction, we characterize the mechanical properties of these materials, including bulk modulus, lattice strain, yield strength, and texture. In agreement with the Hall–Petch effect, the yield strength increases with decreasing size, with the 20 nm ReB2 exhibiting a significantly higher yield strength than any of the larger grained materials or bulk ReB2. Texture analysis on the high pressure diffraction data shows a maximum along the [0001] direction, which indicates that plastic deformation is primarily controlled by the basal slip system. At the highest pressure (55 GPa), the 20 nm ReB2 shows suppression of other slip systems observed in larger ReB2 samples, in agreement with its high yield strength. This behavior, likely arises from an increased grain boundary concentration in the smaller nanoparticles. Overall, these results highlight that even superhard materials can be made more mechanically robust using nanoscale grain size effects.

Graphical abstract: High-pressure studies of size dependent yield strength in rhenium diboride nanocrystals

Supplementary files

Article information

Article type
Communication
Submitted
02 Nov 2023
Accepted
19 Feb 2024
First published
20 Feb 2024

Nanoscale Horiz., 2024,9, 646-655

High-pressure studies of size dependent yield strength in rhenium diboride nanocrystals

S. Hu, S. G. Hamilton, C. L. Turner, D. D. Robertson, J. Yan, A. Kavner, R. B. Kaner and S. H. Tolbert, Nanoscale Horiz., 2024, 9, 646 DOI: 10.1039/D3NH00489A

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