A Simple, General Synthetic Route toward Nanoscale Transition Metal Borides

Jothi, Palani Raja; Yubuta, Kunio; Fokwa, Boniface P. T.

doi:10.1002/adma.201704181

Cited by 113 publications

(97 citation statements)

References 26 publications

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“…Recently, reactive boron halide precursors have been explored for the rapid synthesis of binary borides, including refractory HfB 2 (m.p. 3473 K) and Mo 2 B 4 ‐based hydrogen‐evolution reaction catalysts . Single‐crystal growth from reactive Li or Mg fluxes was employed, including growth under high‐pressure conditions …”

Section: Introductionmentioning

confidence: 99%

“…3473 K) [19] and Mo 2 B 4 -based hydrogenevolution reactionc atalysts. [20] Single-crystal growth from reactive Li or Mg fluxes was employed, including growth under high-pressurec onditions. [21,22] Among the ternary borides, those containinga lkali metals and 3d transition metals deserve particular attention, since only three ternary phases, all of them belongingt ot he Li-Ni-B system, [23][24][25] have been reported so far from 30 possible A-T-B ternary systems (A = alkali metal, Li, Na,K ,R b, Cs; T = 3d transition metal, V-Ni).…”

Section: Introductionmentioning

confidence: 99%

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A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

Gvozdetskyi

Hanrahan

Ribeiro

et al. 2019

Chemistry A European J

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Ternary lithium nickel borides LiNi3B1.8 and Li2.8Ni16B8 have been synthesized by using reactive LiH as a precursor. This synthetic route allows better mixing of the precursor powders, thus facilitating rapid preparation of the alkali‐metal‐containing ternary borides. This method is suitable for “fast screening” of multicomponent systems comprised of elements with drastically different reactivities. The crystal structures of the compounds LiNi3B1.8 and Li2.8Ni16B8 have been re‐investigated by a combination of single‐crystal X‐ray/synchrotron powder diffraction, solid‐state 7Li and 11B NMR spectroscopies, and scanning transmission electron microscopy. This has allowed the determination of fine structural details, including the split position of Ni sites and the ordering of B vacancies. Field‐dependent and temperature‐dependent magnetization measurements are consistent with spin‐glass behavior for both samples.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

Gvozdetskyi

Hanrahan

Ribeiro

et al. 2019

Chemistry A European J

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“…[1-10] In comparison to diamond and boron nitride (c-BN), the transition metal borides (TMBs) are attractive potential superhard materials because of the network and shorter covalent bonding such as B B covalent bond and TM B bond. [11][12][13][14][15][16][17][18][19] Diborides (TMB 2 ) and transition metal tetraborides (TMB 4 ) have been widely investigated over the last years. [20][21][22][23][24] However, the reported Vickers hardness of TMB 2 or TMB 4 is difficult to meet the requirement of superhard material.…”

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confidence: 99%

Influence of alloying elements on the mechanical and thermodynamic properties of ZrB₁₂ceramics from first‐principles calculations

Pan

Lin

2020

Int J of Quantum Chemistry

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Although ZrB 12 is a promising advanced material because of the boron cuboctahedron cages, the hardness of ZrB 12 remains controversy. Here, we apply first-principles calculations to study the influence of transition metals (4d-and 5d-) on the hardness and thermodynamic properties of ZrB 12 . The calculated hardness of ZrB 12 is 32.9 GPa, which is in good agreement with the previous theoretical result. Importantly, the calculated hardness of Re-doped ZrB 12 is up to 40.0 GPa, which is a potential superhard material. The essential reason is that the alloying element of Re enhances the localized hybridization of B B and Zr B atoms, and then forms the strong B B covalent bond and Zr B bond. The result is well demonstrated by the chemical bonding and lattice parameter. Here, our work shows that the alloying elements of Nb, Mo, and Re enhance the thermodynamic properties of ZrB 12 . The Debye temperature of Re-doped ZrB 12 is 1225.2 K, which is larger than that of the parent ZrB 12 (1213.5 K). K E Y W O R D S borides, elastic modulus, first-principles calculations, hardness, thermodynamic properties, ZrB 12 1 | INTRODUCTION Hard and superhard materials (≥40 GPa) are very important industrial materials, which are widely used in various industrial applications because of their high hardness, ultracompressibility, high melting point, and excellent thermal stability etc. [1-10] In comparison to diamond and boron nitride (c-BN), the transition metal borides (TMBs) are attractive potential superhard materials because of the network and shorter covalent bonding such as B B covalent bond and TM B bond. [11][12][13][14][15][16][17][18][19] Diborides (TMB 2 ) and transition metal tetraborides (TMB 4 ) have been widely investigated over the last years. [20][21][22][23][24] However, the reported Vickers hardness of TMB 2 or TMB 4 is difficult to meet the requirement of superhard material. [25][26][27][28][29] Naturally, the Vickers hardness of TMBs mainly relies on the shorter and network covalent bonds. In other words, the high concentration of boron plays a crucial role in Vickers hardness of TMBs. Among these TMBs, it is obvious that the transition metal dodecaborides (TMB 12 ) are potential superhard materials in comparison to TMB 2 and TMB 4 .Recently, ZrB 12 has evoked great interest because of the high concentration of boron and the network B B covalent bonds. [30] This dodecaboride is composed of the boron cuboctahedron cage (24 atoms) and 12-coordinate transition metals at the center of cubic structure. This structural feature is possible to enhance the Vickers hardness of TMBs. However, the Vickers hardness of ZrB 12 remains controversy. Korozlu et al. have found that the calculated Vickers hardness of ZrB 12 is 40.1 GPa, which is believed to a potential superhard material. [31] However, the recent works have shown that the Vickers hardness of ZrB 12 is 35.4 GPa by Chen et al. [32] and 29.3 GPa by Li et al., [33] which are different from Korozlu's result. On the other hand, even if the Vickers hardness of ZrB 12 remains...

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“…Even though the catalytic activity of these above mentioned MoB x is already considerable, the irregular shape and large size of catalyst particles indeed limits their HER performances and their activity should therefore be further optimized by downsizing. Advances in the synthesis of nanoscale or controllably doped MoB x must unlock their great potentials for future HER catalysts …”

Section: Emerging Molybdenum‐based Electrocatalystsmentioning

confidence: 99%

The Holy Grail in Platinum‐Free Electrocatalytic Hydrogen Evolution: Molybdenum‐Based Catalysts and Recent Advances

Zhuang

Huang

et al. 2019

ChemElectroChem

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Electrochemical water splitting towards hydrogen production is of significance for our sustainable development in the future. Although platinum-group catalysts possess the highest activity for hydrogen evolution reaction (HER), their scarcity renders potential applications commercially inviable and thus many efforts are constantly devoted into this arena. Over the last decade, various molybdenum-based catalysts, covering, for example, sulfides, carbides, phosphides, borides, nitrides and alloys, have been found to be very active, and are rapidly becoming popular. In this Review, we comprehensively summarize this topic of emerging Mo-based catalysts for HER by stating and discussing their catalytic mechanisms, synthesis methods, optimization tactics, and promise to outbalance platinum-based systems. We use typical examples from recent advances of various Mo-based catalysts to elaborate their merits and shortcomings for HER, as well as how to further optimize their activities, varying from surface area maximization and active site exposure to electron/atom/molecule/phase-level manipulation, and to external field-assisted activity enhancement. We also propose various challenges and perspectives for these emerging Mo-based catalysts and discuss how these challenges might be addressed.

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A Simple, General Synthetic Route toward Nanoscale Transition Metal Borides

Cited by 113 publications

References 26 publications

A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

Influence of alloying elements on the mechanical and thermodynamic properties of ZrB₁₂ceramics from first‐principles calculations

The Holy Grail in Platinum‐Free Electrocatalytic Hydrogen Evolution: Molybdenum‐Based Catalysts and Recent Advances

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A Simple, General Synthetic Route toward Nanoscale Transition Metal Borides

Cited by 113 publications

References 26 publications

A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

A Hydride Route to Ternary Alkali Metal Borides: A Case Study of Lithium Nickel Borides

Influence of alloying elements on the mechanical and thermodynamic properties of ZrB12ceramics from first‐principles calculations

The Holy Grail in Platinum‐Free Electrocatalytic Hydrogen Evolution: Molybdenum‐Based Catalysts and Recent Advances

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Influence of alloying elements on the mechanical and thermodynamic properties of ZrB₁₂ceramics from first‐principles calculations