Novel ultra-hard hexacarbon allotropes from first principles

Matar, Samir F.; Solozhenko, Vladimir L.

doi:10.26434/chemrxiv-2022-x4p38

2022

DOI: 10.26434/chemrxiv-2022-x4p38

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Novel ultra-hard hexacarbon allotropes from first principles

Samir F. Matar

Vladimir L. Solozhenko

Abstract: Novel ultra-hard hexacarbon C6 allotropes are proposed based on crystal chemistry rationale and geometry optimization onto ground state structures. Similar to diamond, the orthorhombic, tetragonal and trigonal C6 are cohesive networks of C4 tetrahedra illustrated by charge density projections exhibiting sp3-like carbon hybridization. All three allotropes are identified as mechanically (elastic constants) and dynamically (phonons) stable. The electronic band structures are characteristic of insulators with larg… Show more

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Novel (Super)Hard SiCN from Crystal Chemistry and First Principles

Matar

Étourneau

Solozhenko

2022

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The purpose of this work is to predict the existence of novel equiatomic SiCN based on tetragonal C 6 structure ("glitter"), the elementary building unit being the 1,4 cyclohexadiene molecule comprising both tetrahedral (sp 3 ) and trigonal (sp 2 ) carbons. From crystal chemistry rationale the structural transformations of C 6 to SiC 2 and then to the ternary SiCN were fully relaxed to the ground states using first principles DFT-based calculation. Like early proposed C 6 and SiC 2 , SiCN was found bonding and structurally stable from the elastic properties on one hand and dynamically stable from the phonons, on the other hand. The Vickers hardness of SiCN is close to that of cubic silicon carbide, a conventional superabrasive, whereas hardness of tetragonal SiC 2 is slightly lower. Besides the abrasive properties, the electronic band structure indicates metal-like behavior of SiCN thus suggesting the potential for heat dissipation in operating conditions.

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Novel (Super)Hard SiCN from Crystal Chemistry and First Principles

Matar

Étourneau

Solozhenko

2022

Silicon

Self Cite

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Novel ultra-hard hexacarbon allotropes from first principles

Cited by 1 publication

References 45 publications

Novel (Super)Hard SiCN from Crystal Chemistry and First Principles

Novel (Super)Hard SiCN from Crystal Chemistry and First Principles

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