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Beilstein J. Nanotechnol. 2017, 8, 172–182, doi:10.3762/bjnano.8.18
Figure 1: Geometry, LDA band-structure and DOS of the different (zigzag and armchair) GNR arrays reported in ...
Figure 2: Loss properties of intrinsic graphene (a), i.e., an example of infinite-width GNR, and the undoped ...
Figure 3: Macroscopic permittivity (, Equation 6) and EL function (ELOSS, Equation 8) at room temperature for the GNR arrays of Figure 1 ...
Figure 4: EL function of Equation 8 at room temperature for the GNR-arrays considered in the main text, e.g., 10ZGNR (a...
Figure 5: EL function of three positively doped 5AGNRs (ΔEF = 0.2 eV) separated by an in-plane vacuum distanc...
Figure 6: EL function of three negatively doped 5AGNR (ΔEF = −0.2 eV), characterized by a C–C bond length acc...
Beilstein J. Nanotechnol. 2015, 6, 755–766, doi:10.3762/bjnano.6.78
Figure 1: Valence levels and (broadened) DOS for the neutral (C60) and ionized () fullerene molecules, as com...
Figure 2: Lowest and highest occupied valence states for the neutral fullerene molecule (C60) and correspondi...
Figure 3: Energy levels and (broadened) density of states for a trapped gas of spin 1/2 fermions having a num...
Figure 4: Lowest and highest occupied one-particle wave functions and levels for a harmonically trapped gas o...
Figure 5: Zero-temperature work-distribution components (Equation 7) for a C60 molecule undergoing core ionization, and...
Figure 6: Low-temperature work distributions for: (left) a C60 molecule undergoing core-ionization; (center,r...