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Elucidating Stress–Strain Relations of ZrB<sub>12</sub> from First-Principles Studies

Cheng Lü, Weiguang Gong, Quan Li, Changfeng Chen

2020The Journal of Physical Chemistry Letters125 citationsDOI

Abstract

Transition-metal boron-rich compounds exhibit favorable synthesis conditions and mechanical properties that hold great promise for wide-ranging applications. However, the complex bonding networks of these compounds produce diverse structural and mechanical behaviors that require in-depth studies. A notable case is ZrB12, which has been reported to possess high Vickers hardness comparable to those of ReB2 and WB4. Surprisingly, first-principles calculations of stress–strain relations reveal unexpected low indentation strengths of ZrB12 well below those of ReB2 and WB4. Such contrasting results are reconciled by noting that the additional presence of a boron-rich phase of ZrB50 in the experimental synthesis process likely plays a key role in the extrinsic strengthening. These findings uncover mechanisms for the higher measured strength of ZrB12 and offer insights for elucidating extrinsic hardening phenomena that may exist in other transition-metal compounds.

Topics & Concepts

Materials scienceStrain (injury)Stress (linguistics)Stress–strain curveComposite materialStructural engineeringEngineeringDeformation (meteorology)PhilosophyMedicineLinguisticsInternal medicineBoron and Carbon Nanomaterials ResearchMXene and MAX Phase MaterialsNuclear Materials and Properties
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