Ab initio study of boron-rich amorphous boron carbides
Özet
Amorphous boron carbide compositions having high B contents (BxC1−x,
0.50 ≤ x ≤ 0.95) are systematically created by way of ab initio molecular dynamics calculations, and their structural, electrical, and mechanical characteristics
are inclusively investigated. The coordination number of both B and C atoms
increases progressively with increasing B/C ratio and more close-packed materials having pentagonal pyramid motifs form. An amorphous diamond-like local
arrangement is found to be dominant up to 65% B content, and beyond this content, a mixed state of amorphous diamond– and B-like structures is perceived in
the models because sp3 hybridization around C atoms is still leading one for all
compositions. The pentagonal pyramid motifs around C atoms are anticipated
to appear beyond 65% content. The intericosahedral linear C–B–C chains do not
form in any model. All amorphous boron carbides are semiconducting materials.
The mechanical properties gradually increase with increasing B concentration,
and some amorphous compositions are proposed to be hard materials on the
basis of their Vickers hardness estimation.