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Beilstein J. Nanotechnol. 2016, 7, 439–464, doi:10.3762/bjnano.7.39
Figure 1: Scheme of the device studied in this work. The left lead (LL) and the right lead (RL) are kept at d...
Figure 2: Analysis of the validity of the adiabatic approximation. Electronic spectral function as a function...
Figure 3: Analysis of the validity of the adiabatic approximation. Panel (a): Dimensionless position distribu...
Figure 4: Phase diagrams expressing the validity of the adiabatic approximation. Panel (a): Phase diagram at ...
Figure 5: Electronic transport properties within the range of validity of the adiabatic approximation. Curren...
Figure 6: Phonon thermal conductance in the linear response regime, in the range of validity of the adiabatic...
Figure 7: Thermal transport properties in the linear response regime, in the range of validity of the adiabat...
Figure 8: Thermal transport properties in the linear response regime, within the range of validity of the adi...
Figure 9: Sketch of the device investigated in section 6. A carbon nanotube is suspended between two metal le...
Figure 10: Electronic transport properties in the presence of an external periodic time-dependent perturbation...
Figure 11: Interplay between the resonator frequency and the charge density. Panel (a): Resonator frequency at...
Figure 12: Single-parameter charge-pumping mechanism, and oscillator frequency as a function of the gate volta...
Figure 13: Single-parameter charge pumped at zero bias. Panel (a): Charge Q (in units of e) as a function of t...
Figure 14: Electronic charge pumped in a two-parameter pumping device in the presence of an adiabatic vibratio...