Reinvestigation of Mechanical Properties and Shear-Induced Atomic Deformation of Tetragonal Superhard Semiconducting OsB<sub>4</sub>

Yan, Haiyan; Wei, Qun; Zheng, Baobing

doi:10.1021/acs.jpcc.6b12992

Cited by 6 publications

(4 citation statements)

References 53 publications

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“…From our previous diffraction study, the stoichiometry of tungsten tetraboride from the unit cell is ∼WB 4.5 , and thus to probe the stability of theoretically predicted metal tetraboride phases, we kept the boron content fixed and substituted tungsten with other metals. − This will reveal which of the computationally predicted tetraborides are stable; plus, the presence of tungsten should help direct formation. PXRD data for the alloys of W with Ta, Nb, and V prepared with a M:B = 1:4.5 are given in Figures and S3.…”

Section: Resultsmentioning

confidence: 99%

“…Theoretical calculations have resulted in the prediction of numerous tetraborides. − This has resulted in claims of ReB 4 , OsB 4 , and TaB 4 , all isostructural with tungsten tetraboride. Unfortunately, none of these compounds have yet to be experimentally prepared, and it is possible that these compounds are not stable under equilibrium conditions.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

et al. 2017

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Tungsten tetraboride is an inexpensive, superhard material easily prepared at ambient pressure. Unfortunately, there are relatively few compounds in existence that crystallize in the same structure as tungsten tetraboride. Furthermore, the lack of data in the tetraboride phase space limits the discovery of any new superhard compounds that also possess high incompressibility and a three-dimensional boron network that withstands shear. Thus, the focus of the work here is to chemically probe the range of thermodynamically stable tetraboride compounds with respect to both the transition metal and the boron content. Tungsten tetraboride alloys with a variable concentration of boron were prepared by arc-melting and investigated for their mechanical properties and thermal stability. The purity and phase composition were confirmed by energy dispersive X-ray spectroscopy and powder X-ray diffraction. For variable boron WB, it was found that samples prepared with a metal to boron ratio of 1:11.6 to 1:9 have similar hardness values (∼40 GPa at 0.49 N loading) as well as having a similar thermal oxidation temperature of ∼455 °C. A nearly single phase compound was successfully stabilized with tantalum and prepared with a nearly stoichiometric amount of boron (4.5) as WTaB. Therefore, the cost of production of WB can be decreased while maintaining its remarkable properties. Insights from this work will help design future compounds stable in the adaptable tungsten tetraboride structure.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

et al. 2017

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“…6,10 Recently, the structural transitions sequence of osmium tetraboride (OsB 4 ) has been presented up to 300 GPa. 11,12 At 11 GPa, the P4 2 /nmc phase emerges in OsB 4 similarly resembling FeB 4 . 6 Both FeB 4 and OsB 4 undergo a metal-tosemiconductor phase transition.…”

Section: ■ Introductionmentioning

confidence: 97%

“…For instance, iron tetraboride (FeB 4 ) exhibits superhard and superconducting properties. , Its high-pressure phases (the tetragonal structures with space groups of I 4 1 / acd and P 4 2 / nmc ) are the semiconducting and hard/superhard materials. , Recently, the structural transitions sequence of osmium tetraboride (OsB 4 ) has been presented up to 300 GPa. , At 11 GPa, the P 4 2 / nmc phase emerges in OsB 4 similarly resembling FeB 4 . Both FeB 4 and OsB 4 undergo a metal-to-semiconductor phase transition.…”

Section: Introductionmentioning

confidence: 99%

Structural Phase Transitions, Electronic Properties, and Hardness of RuB₄ under High Pressure in Comparison with FeB₄ and OsB₄

et al. 2020

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We have employed an evolutionary algorithm with first-principles calculations to investigate the pressure-induced structural evolution of RuB4 up to 500 GPa. The ambient phase is predicted to be a hexagonal structure (P63/mmc). The novel phases consisting of monoclinic (C2/c) and orthorhombic (Immm) structures are proposed to be the high-pressure phases at the pressure intervals of 198–388 GPa and beyond 388 GPa, respectively. The stability of the predicted phases is confirmed by both dynamic and elastic calculations. The electronic and mechanical properties of the predicted phases are evaluated and mainly discussed compared to the isoelectronic metal tetraborides, i.e., FeB4 and OsB4. In contrast to FeB4 and OsB4, all the stable phases of RuB4 are metal or semimetal, and any semiconducting phases do not emerge in the transformation pathway of RuB4. The nature of chemical bonding investigated by ELF, MPA, and pCOHP calculations reveals that the atomic configurations and the degree of covalent bonding of the predicted phases are responsible for lower hardness compared to those of FeB4 and OsB4. The results of this work provide more understanding of the family of metal tetraboride for designing metal-boride-based hard/superhard materials.

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Exploration of stable stoichiometries, ground-state structures, and mechanical properties of the W–Si system

Yan

Wei

Zhang

et al. 2020

Ceramics International

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Reinvestigation of Mechanical Properties and Shear-Induced Atomic Deformation of Tetragonal Superhard Semiconducting OsB₄

Cited by 6 publications

References 53 publications

Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

Structural Phase Transitions, Electronic Properties, and Hardness of RuB₄ under High Pressure in Comparison with FeB₄ and OsB₄

Exploration of stable stoichiometries, ground-state structures, and mechanical properties of the W–Si system

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Reinvestigation of Mechanical Properties and Shear-Induced Atomic Deformation of Tetragonal Superhard Semiconducting OsB4

Cited by 6 publications

References 53 publications

Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

Effects of Variable Boron Concentration on the Properties of Superhard Tungsten Tetraboride

Structural Phase Transitions, Electronic Properties, and Hardness of RuB4 under High Pressure in Comparison with FeB4 and OsB4

Exploration of stable stoichiometries, ground-state structures, and mechanical properties of the W–Si system

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Product

Resources

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Reinvestigation of Mechanical Properties and Shear-Induced Atomic Deformation of Tetragonal Superhard Semiconducting OsB₄

Structural Phase Transitions, Electronic Properties, and Hardness of RuB₄ under High Pressure in Comparison with FeB₄ and OsB₄