Kondo effect and bistability in a double quantum dot

Orellana, P. A.; Lara, Gustavo A.; Anda, E. V.

doi:10.1103/physrevb.65.155317

Cited by 31 publications

(19 citation statements)

References 25 publications

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“…7 Double QDs systems behavior is recently under careful investigation because of the variable inter-dot tunneling coupling, 8 which is the physical reason for non-linearity formation and consequently for existence of such phenomena as bifurcations, 910 and bi-stability, 11 . 12 Electron transport in QDs is strongly governed by Coulomb interaction between localized electrons, the ratios between tunneling transfer amplitudes, QDs coupling and of course by the initial conditions, 10 .…”

Section: Introductionmentioning

confidence: 99%

Two-level quantum dot susceptibility and polarization in the presence of Coulomb correlations

2016

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Susceptibility and polarization of two-level quantum dot (QD) with Coulomb correlations between localized electrons weakly connected to the reservoirs were carefully analyzed. It was revealed that both susceptibility and polarization depend strongly on high-order correlation functions of localized in QD electrons. It was demonstrated that susceptibility and polarization can be controlled by changing of applied bias voltage value, Coulomb correlations strength and Rabi frequency.

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Section: Introductionmentioning

confidence: 99%

Two-level quantum dot susceptibility and polarization in the presence of Coulomb correlations

2016

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“…Parameter of p indicates the distance between two-rings. The system assumed in equilibrium, is modeled by using a non interacting Anderson tunneling Hamiltonian [5][6] which can be written as: In this section, simulated results including the electronic conductance through quantum wire with side-coupled asymmetric QD-rings as a scatter system are presented and discussed. Figure2 shows, the dimensionless conductance (g = G/(2e2/h) = T) is plotted versus Fermi energy in units of μ ( ε / μ).…”

Section: Introductionmentioning

confidence: 99%

Transport electron through a quantum wire by side-attached asymmetric quantum-dot rings

Rostami

Zabihi

et al. 2011

SPIE Proceedings

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The electronic conductance at zero temperature through a quantum wire with side-attached asymmetric quantum ring (as a scatter system) is theoretically studied using the non-interacting Anderson tunneling Hamiltonian method. We show that the asymmetric configuration of QDscatter system strongly impresses the amplitude and spectrum of quantum wire nanostructure transmission characteristics. It is shown that whenever the balanced number of quantum dots in two rings is substituted by unbalanced scheme, the number of forbidden mini-bands in quantum wire conductance increases and QW-nanostructure electronic conductance contains rich spectral properties due to appearance of the new anti-resonance and resonance points in spectrum. Considering the suitable gap between nano-rings can strengthen the amplitude of new resonant peaks in the QW conductance spectrum. The proposed asymmetric quantum ring scatter system idea in this paper opens a new insight on designing quantum wire nano structure for given electronic conductance.

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“…This is because coupling to the continuum states shows an even-odd parity effect in the conductance when the Fermi energy is localized at the center of the energy band [3][4][5][6][7][8][9]. The systems such as uniform QD array [10], nano-wires [11] and nano-ring [12] which are side-coupled to a QW act as a scatter system for electron transmission through the QW and have a major effect on electronic conductance of nano-device. For a uniform QD-chains array with M sites, it was shown that the transmission characteristic has M anti-resonances and M-1 resonance, M mini-gaps and M-1 allowed mini-bands arise [10].…”

Section: Introductionmentioning

confidence: 99%

Quantum-wire conductance manipulating by asymmetric quantum dot-molecules

Rostami

Rasooli

Ghanbari

et al. 2010

2010 International Symposium on Optomechatronic Technologies

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The electronic conductance at zero temperature through a quantum wire with side-attached asymmetric quantum dot-molecules (as a scatter system) is theoretically studied using the non-interacting Anderson tunneling Hamiltonian method. We show that the asymmetric configuration of QD-scatter system strongly impresses the amplitude and spectrum of quantum wire nanostructure transmission characteristics. It is shown that whenever the balanced number of chains-quantum dots in one molecule is substituted by unbalanced scheme, the number of forbidden mini-bands in quantum wire conductance increases to the sum of the number of quantum dots in two chains and thus the QW-nanostructure electronic conductance contains rich spectral properties due to appearance of the new anti-resonance and resonance points in spectrum. Considering the suitable inner gap between QD-chains in one molecule or outer gap between QD-molecules, can strengthen the amplitude of new resonant peaks in QW conductance spectrum. The proposed asymmetric-QD scatter system idea in this paper opens a new insight on designing quantum wire nanostructures for given electronic conductance.

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Kondo effect and bistability in a double quantum dot

Cited by 31 publications

References 25 publications

Two-level quantum dot susceptibility and polarization in the presence of Coulomb correlations

Two-level quantum dot susceptibility and polarization in the presence of Coulomb correlations

Transport electron through a quantum wire by side-attached asymmetric quantum-dot rings

Quantum-wire conductance manipulating by asymmetric quantum dot-molecules

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