Structural Stability and Electronic Properties of Boron Phosphide Nanotubes: A Density Functional Theory Perspective

Structural Stability and Electronic Properties of Boron Phosphide Nanotubes: A Density Functional Theory Perspective

Based on the Density Functional Theory (DFT) calculations, we analyze the structural and electronic properties of boron phosphide nanotubes (BPNTs) as functions of chirality. The DFT calculations are performed using the M06-2X method in conjunction with the 6-31G(d) divided valence basis set. All na...

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Bibliographic Details
Published in:Symmetry (Basel) Vol. 14; no. 5; p. 964
Main Authors: García-Toral, Dolores, Mendoza-Báez, Raúl, Chigo-Anota, Ernesto, Flores-Riveros, Antonio, Vázquez-Báez, Víctor M., Cocoletzi, Gregorio Hernández, Rivas-Silva, Juan Francisco
Format: Journal Article
Language:English
Published: Basel MDPI AG 09-05-2022
Subjects:
Boron
boron phosphide nanotubes
Boron phosphides
Carbon
Chemical potential
Chirality
Conductors
Density functional theory
Electronic properties
Energy
Energy gap
Hydrogen bonds
Investigations
Mathematical analysis
Molecular orbitals
Nanostructure
Nanotubes
Phase transitions
Phosphorus
structural properties
Structural stability
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Summary:Based on the Density Functional Theory (DFT) calculations, we analyze the structural and electronic properties of boron phosphide nanotubes (BPNTs) as functions of chirality. The DFT calculations are performed using the M06-2X method in conjunction with the 6-31G(d) divided valence basis set. All nanostructures, (n,0) BPNT (n = 5–8, 10, 12, 14) and (n,n) BPNT (n = 3–11), were optimized minimizing the total energy, assuming a non-magnetic nature and a total charge neutrality. Results show that the BPNT diameter size increases linearly with the chiral index “n” for both chiralities. According to the global molecular descriptors, the (3,3) BPNT is the most stable structure provided that it shows the largest global hardness value. The low chirality (5,0) BPNT has a strong electrophilic character, and it is the most conductive system due to the small |HOMO-LUMO| energy gap. The chemical potential and electrophilicity index in the zigzag-type BPNTs show remarkable chirality-dependent behavior. The increase in diameter/chirality causes a gradual decrease in the |HOMO-LUMO| energy gap for the zigzag BPNTs; however, in the armchair-type BPNTs, a phase transition is generated from a semiconductor to a conductor system. Therefore, the nanostructures investigated in this work may be suggested for both electrical and biophysical applications.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym14050964