AI Article Synopsis
- Boron exhibits unique electron deficiency and multicenter bonding, leading to complex chemistry and various structural forms.
- The study introduces a new form called γ*-boron, which has similar energy levels to the known hardest boron, γ-B, and shows promising results in simulated X-ray diffraction patterns.
- First-principles calculations indicate that γ*-boron is 7.5% stronger in terms of shear strength than γ-B, achieving a hardness of 59 GPa, highlighting potential for new boron polymorphs with enhanced mechanical properties.
Article Abstract
The distinctive electron deficiency and unusual multicenter bonding situations of boron give rise to fascinating chemical complexity and imaginative structural polymorphism. Herein, we employ an independently developed method to construct the new twinned γ*-boron based on the well-known hardest elemental boron, γ-B. Notably, the newly propounded γ*-boron phases exhibit considerably close energy levels with γ-B under ambient conditions. The simulated X-ray diffraction patterns of stable twinned structure present excellent agreement with experimental data. First-principles calculations reveal a 7.5% increase in the ideal Vickers shear strength of γ*-boron compared to γ-B, attributed to diverse bond responses within the twinned slabs. The evaluated hardness of nanotwinned γ*-B reaches 59 GPa in consideration of the size hardening effect. Our research presents an efficient strategy for constructing new polymorphs of boron with improved mechanical properties and expands the knowledge about twinning structures of boron.
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| http://dx.doi.org/10.1021/acs.jpclett.4c00262 | DOI Listing |
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