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Beilstein J. Nanotechnol. 2020, 11, 1873–1890, doi:10.3762/bjnano.11.169
Figure 1: (a, b) Ground-state maps of isolated quantum dots (U = 6 meV, δ = 1 meV·nm): (a) dot formed in a sm...
Figure 2: Maps of the total conductance values with plotted ground-state diagrams of (a) CNTQD(24,21), (b) CN...
Figure 3: (a, b) Spin polarization (SPC) and orbital polarization (OPC) maps of CNTQD(15,12). (c, d) Spin (MZ...
Figure 4: SU(3) Kondo lines of CNTQD(15,12) as functions of magnetic field and on-site energy plotted for sev...
Figure 5: (a, d) Total conductances (a) and Kondo temperature (d) of CNTQD(15,12) plotted as a function of th...
Figure 6: Thermoelectric quantities and conductance of CNTQD(15,12). (a) Linear TEP coefficient as a functio...
Figure 7: Charge and spin–orbital fluctuations of CNTQD(15,12) plotted for (a) δ = 1/4 meV·nm, (b) δ = 1/2 me...
Figure 8: Electron and hole states of (a) a carbon nanotube C(33,30) and of (b–d) a quantum dot CNTQD(33,30),...
Figure 9: Electron–hole ground-state diagrams of CNTQD(33,30) in a slanting magnetic field (θ = 89°) for diff...
Figure 10: Electron–hole ground-state diagrams of CNTQD(33,30) for (a) θ = 86° and (b) θ = 90° (U = 6 meV, δ =...
Figure 11: Partial conductances of CNTQD(33,30) in slanting magnetic fields for (a–c) θ = 89°, with curves plo...