Ab Initio Study of the Electronic, Vibrational, and Mechanical Properties of the Magnesium Diboride Monolayer

Ab Initio Study of the Electronic, Vibrational, and Mechanical Properties of the Magnesium Diboride Monolayer

Magnesium diboride gained significant interest in the materials science community after the discovery of its superconductivity, with an unusually high critical temperature of 39 K. Many aspects of the electronic properties and superconductivity of bulk MgB 2 and thin sheets of MgB 2 have been determ...

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Veröffentlicht in:Condensed matter 2019-06, Vol.4 (2), p.37
Hauptverfasser: Pešić, Jelena, Popov, Igor, Šolajić, Andrijana, Damljanović, Vladimir, Hingerl, Kurt, Belić, Milivoj, Gajić, Radoš
Format: Artikel
Sprache:eng
Schlagworte:
2D materials
Boron
density functional theory
Dynamic stability
Elastic properties
First principles
Graphene
Graphite
Magnesium
Magnesium compounds
magnesium diboride
Materials science
Mechanical properties
Monolayers
Poisson's ratio
Simulation
Software packages
Superconductivity
Temperature
Two dimensional materials
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Zusammenfassung:Magnesium diboride gained significant interest in the materials science community after the discovery of its superconductivity, with an unusually high critical temperature of 39 K. Many aspects of the electronic properties and superconductivity of bulk MgB 2 and thin sheets of MgB 2 have been determined; however, a single layer of MgB 2 has not yet been fully theoretically investigated. Here, we present a detailed study of the structural, electronic, vibrational, and elastic properties of monolayer MgB 2 , based on ab initio methods. First-principles calculations reveal the importance of reduction of dimensionality on the properties of MgB 2 and thoroughly describe the properties of this novel 2D material. The presence of a negative Poisson ratio, higher density of states at the Fermi level, and a good dynamic stability under strain make the MgB 2 monolayer a prominent material, both for fundamental research and application studies.
ISSN:2410-3896
2410-3896
DOI:10.3390/condmat4020037