Large diameter multiwall nanotubes of MgB2: structural aspects and stability of superconducting nanotubular magnesium boride

TL;DR

This theoretical study shows that multiwall MgB2 nanotubes can be as stable as bulk MgB2, with specific structural parameters supporting their potential synthesis and superconducting properties.

Contribution

The paper demonstrates that multilayer MgB2 nanotubes derived from multilayer slabs are more stable than other forms and can reach bulk MgB2 stability, highlighting their potential as superconductors.

Findings

Multiwall MgB2 nanotubes are stable and comparable to bulk MgB2.

Critical inner diameter for stability is approximately 32.6 nm.

Electronic structures indicate superconducting properties similar to bulk MgB2.

Abstract

Based on a theoretical study, we demonstrated that magnesium boride nanotubes can reach the same stability as bulk MgB2 structure. However, most stable nanotubular forms are not structurally derived from mixed triangular-hexagonal structural motifs of a single layer sheet, which is thought to be the 2D precursor form of all boron nanotubes. MgB2 multiwall nanotubular structures that are derived from multilayer MgB2 slabs with honeycomb B-networks in hexagonal lattices are more stable. The results of an ab initio study of multilayer slabs of MgB2 show that a 25-layer slab approaches the stability of bulk MgB2. The critical parameter of the corresponding multiwall nanotubes is the inner diameter; the calculated value is ~ 32.6nm, which is independent of the number of walls. The outer diameters of 25-wall nanotubes are ~ 51 nm, and terminal Mg atoms are located on the outer surfaces of the nanotubes. The electronic band structures of MgB2-multiwall nanotubes (MgB2MWNT) correspond to the band structure character and topology of superconducting bulk MgB2. The results confirm that the quasi-1D superconductor MgB2MWNT is a stable structure and can be synthesized.