Ab initio study of structural and electronic properties of zigzag graphene nanoribbons on hexagonal boron nitride

“…The obtained results correlate well with known data. 9,14,31 For the highlighted 8-ZGNR/h-BN(0001) heterostructure fragment shown in the Fig. 1(d), the obtained total energy values are E tot = −1130.6441 Ry/cell.…”

“…14 Studies on magnetic characteristics in 8-ZGNR/h-BN(0001) heterostructures have revealed that edge C atoms exhibit the highest local magnetic moments (LMM) among C atoms. 4,14 For the ZGNRs on metal substrates (such as Au, Pt, Ni, Cu, Al, Ag, Pd), MMs in ZGNR on s-dominated metal surfaces can be reordered using E ext 22 because of the prevalence of electrostatic interaction between ZGNR and s-dominated surfaces. For ZGNRs on p-and d-dominated metal surfaces, tuning with E ext is less efficient 22 because of strong interaction between carbon π -orbitals and metal substrate during chemical adsorption.…”

“…1 ZGNR band structure with AF ordering (AF-ZGNRs) corresponds to the semiconductor type. 3,[13][14][15] Selection of h-BN as substrate is determined by its ability to ensure high carrier mobility (125 000 cm 2 V −1 s −1 , at room temperature) in graphene. 16 High carrier mobility is attributed to the smooth surface, low density of charged impurities, lack of dangling bonds, and relative inertness of h-BN.…”

Tuning the band structure, magnetic and transport properties of the zigzag graphene nanoribbons/hexagonal boron nitride heterostructures by transverse electric field

“…The obtained results correlate well with known data. 9,14,31 For the highlighted 8-ZGNR/h-BN(0001) heterostructure fragment shown in the Fig. 1(d), the obtained total energy values are E tot = −1130.6441 Ry/cell.…”

“…14 Studies on magnetic characteristics in 8-ZGNR/h-BN(0001) heterostructures have revealed that edge C atoms exhibit the highest local magnetic moments (LMM) among C atoms. 4,14 For the ZGNRs on metal substrates (such as Au, Pt, Ni, Cu, Al, Ag, Pd), MMs in ZGNR on s-dominated metal surfaces can be reordered using E ext 22 because of the prevalence of electrostatic interaction between ZGNR and s-dominated surfaces. For ZGNRs on p-and d-dominated metal surfaces, tuning with E ext is less efficient 22 because of strong interaction between carbon π -orbitals and metal substrate during chemical adsorption.…”

“…1 ZGNR band structure with AF ordering (AF-ZGNRs) corresponds to the semiconductor type. 3,[13][14][15] Selection of h-BN as substrate is determined by its ability to ensure high carrier mobility (125 000 cm 2 V −1 s −1 , at room temperature) in graphene. 16 High carrier mobility is attributed to the smooth surface, low density of charged impurities, lack of dangling bonds, and relative inertness of h-BN.…”

Tuning the band structure, magnetic and transport properties of the zigzag graphene nanoribbons/hexagonal boron nitride heterostructures by transverse electric field

“…This is different from the tetragonal sp 3 -configuration typical of the 3D w-AlN structure 38 . 11,35,40 For the highlighted 4-ZGNR/AlNNS fragment shown in Fig. The bond between the Al and N atoms is formed by the combination of the p z orbitals in Al and N with charge transferring from Al to N due to the different electronegativity of Al and N atoms.…”

“…

Effect of an external electric field on the electronic and magnetic properties of the heterostructure of the zigzag graphene nanoribbons (ZGNRs) placed on aluminium nitride nanosheet (AlNNS) is studied by the the density functional theory (DFT). 1,11,26,27 Magnetism characteristics in such systems as the 8-ZGNR/h-BN revealed that the edge C atoms in ZGNR have highest local magnetic moments (LMMs) in comparison to other C atoms. We can control the band gap of the 4-ZGNR/AlNNS by using an external electric field.

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Effect of electric field on the electronic and magnetic properties of a graphene nanoribbon/aluminium nitride bilayer system

Modulation the Band Structure and Physical Properties of the Graphene Materials with Electric Field and Semiconductor Substrate