Electronic Properties of Functionalized Diamanes for Field-Emission Displays
Permanent lenke
https://hdl.handle.net/10037/30483Dato
2023-03-16Type
Journal articleTidsskriftartikkel
Peer reviewed
Forfatter
Tantardini, Christian; Kvashnin, Alexander G.; Azizi, Maryam; Gonze, Xavier; Gatti, Carlo; Altalhi, Tariq; Yakobson, Boris I.Sammendrag
Ultrathin diamond films, or diamanes, are promising quasi-2D materials that are
characterized by high stiffness, extreme wear resistance, high thermal conductivity, and chemical
stability. Surface functionalization of multilayer graphene with different stackings of layers could
be an interesting opportunity to induce proper electronic properties into diamanes. Combination
of these electronic properties together with extraordinary mechanical ones will lead to their
applications as field-emission displays substituting original devices with light-emitting diodes or
organic light-emitting diodes. In the present study, we focus on the electronic properties of
fluorinated and hydrogenated diamanes with (111), (110), (0001), (101̅0), and (2̅110)
crystallographic orientations of surfaces of various thicknesses by using first-principles calculations
and Bader analysis of electron density. We see that fluorine induces an occupied surface electronic
state, while hydrogen modifies the occupied bulk state and also induces unoccupied surface states.
Furthermore, a lower number of layers is necessary for hydrogenated diamanes to achieve the convergence of the work function in
comparison with fluorinated diamanes, with the exception of fluorinated (110) and (2̅110) films that achieve rapid convergence and
have the same behavior as other hydrogenated surfaces. This induces a modification of the work function with an increase of the
number of layers that makes hydrogenated (2̅110) diamanes the most suitable surface for field-emission displays, better than the
fluorinated counterparts. In addition, a quasi-quantitative descriptor of surface dipole moment based on the Tantardini−Oganov
electronegativity scale is introduced as the average of bond dipole moments between the surface atoms. This new fundamental
descriptor is capable of predicting a priori the bond dipole moment and may be considered as a new useful feature for crystal
structure prediction based on artificial intelligence.
Forlag
American Chemical SocietySitering
Tantardini, Kvashnin, Azizi, Gonze, Gatti, Altalhi, Yakobson. Electronic Properties of Functionalized Diamanes for Field-Emission Displays. ACS Applied Materials & Interfaces. 2023;15(12):16317-16326Metadata
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