Transport in coupled quantum dots: Kondo effect versus antiferromagnetic correlation

Büsser, C. A.; Anda, E. V.; Lima, Ana Raquel Carmo de; Davidovich, Maria A.; Chiappe, G.

doi:10.1103/physrevb.62.9907

Cited by 97 publications

(119 citation statements)

References 39 publications

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“…There have been a number of theoretical works on DQD systems in this context. For example, it was pointed out that the DQD system shows the dramatic suppression of the Kondo-assisted transport due to the interference when the DQD is arranged in the parallel geometry [15,16,17,18,19,20,21,22], whereas such interference effects do not appear in the serial DQD [16,23,24,25,26,27,28,29,30]. More recently, slightly different DQD systems with the parallel geometry, where the two dots are connected via the exchange coupling [19] or the tunneling [20,21], have been studied.…”

Section: Introductionmentioning

confidence: 99%

Interference effects on Kondo-assisted transport through double quantum dots

2005

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We systematically investigate electron transport through double quantum dots with particular emphasis on interference induced via multiple paths of electron propagation. By means of the slave-boson mean-field approximation, we calculate the conductance, the local density of states, the transmission probability in the Kondo regime at zero temperature. It is clarified how the Kondoassisted transport changes its properties when the system is continuously changed among the serial, parallel and T-shaped double dots. The obtained results for the conductance are explained in terms of the Kondo resonances influenced by interference effects. We also discuss the impacts due to the spin-polarization of ferromagnetic leads.

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Section: Introductionmentioning

confidence: 99%

Interference effects on Kondo-assisted transport through double quantum dots

2005

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“…The Kondo effect for even number electrons on a single multilevel dot and possible phase transitions between singlet and triplet states have been considered for both "vertical" [5] and "lateral" [6,7,8,9] configurations. For the coupled DQD with degenerate energy levels, the Kondo behavior and the ISS interplay and strongly compete, as seen in the bulk two-impurity Kondo problem,[10] and a question arises whether there exists a spin entangled state composed of the coherent Kondo resonances.[11] Previous experimental and theoretical studies have mainly focused on the serial-coupled DQD [12,13,14,15,16,17,18,19], except for Ref. 9, 19.…”

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confidence: 99%

“…[11] Previous experimental and theoretical studies have mainly focused on the serial-coupled DQD [12,13,14,15,16,17,18,19], except for Ref. 9, 19.…”

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confidence: 99%

“…For the coupled DQD with degenerate energy levels, the Kondo behavior and the ISS interplay and strongly compete, as seen in the bulk two-impurity Kondo problem, [10] and a question arises whether there exists a spin entangled state composed of the coherent Kondo resonances. [11] Previous experimental and theoretical studies have mainly focused on the serial-coupled DQD [12,13,14,15,16,17,18,19], except for Ref. 9,19.…”

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confidence: 99%

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Swapping Kondo resonances in coupled double quantum dots

et al. 2005

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Strong electron and spin correlations are studied in parallel-coupled double quantum dots with interdot spin superexchange J. In the Kondo regime with degenerate dot energy levels, a coherent transport occurs at zero temperature, where two entangled (bonding and antibonding) resonances are formed near the Fermi energy. When increasing J or the dot-lead parallel-coupling asymmetry ratio Γ2/Γ1, a swap between two entangled resonances occurs and the line shapes of the linear conductance are interchanged. The zero-bias differential conductance shows a peak at the critical values. Such a peculiar effect with the virtue of many-body coherence may be useful in future quantum computing.A large number of proposals have been made to materialize quantum bits (qubits) and quantum computing. Among these proposals, coupled quantum dot (QD) systems are particularly attractive.[1] The spin degree of freedom of the localized electrons on the dots is considered as a qubit due to the comparatively long coherence time. A key challenge is the construction of coupled double QD (DQD) to perform a swap operation, i.e. exchanging the electron spin states on the two dots. When the square root of a swap operation is combined with other isolated qubit rotations, a quantum controlled-NOT gate can be built and any quantum algorithms can be implemented.[2] In the coupled DQD, two local electrons form a singlet state. It has been proposed that the swap operation can be realized by tuning the time-dependent interdot spin superexchange (ISS) J(t) from positive to negative, flopping the singlet and triplet states. [1,3] In this Letter, we propose a simple and reliable mechanism to perform such a swap process in a parallel-coupled DQD at low temperatures. It has been well-established that under the Coulomb blockade with odd number electrons on a single QD, a quantum coherent many-body (Kondo) resonance is formed near the Fermi energy in the dot density of states (DOS) [4]. The Kondo effect for even number electrons on a single multilevel dot and possible phase transitions between singlet and triplet states have been considered for both "vertical" [5] and "lateral" [6,7,8,9] configurations. For the coupled DQD with degenerate energy levels, the Kondo behavior and the ISS interplay and strongly compete, as seen in the bulk two-impurity Kondo problem,[10] and a question arises whether there exists a spin entangled state composed of the coherent Kondo resonances.[11] Previous experimental and theoretical studies have mainly focused on the serial-coupled DQD [12,13,14,15,16,17,18,19], except for Ref. 9, 19. However, it has been recently realized that the serial geometry is unsuitable for studying this competition experimentally and a direct evidence for observing spin entanglement between the dot local electrons could be sought in the parallel coupled configuration. [20] It has thus motivated us to investigate whether and how this competition manifests itself in the coherent transport through DQD in the parallel configuration.For a degenerate DQD with ...

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“…3,4 From the theoretical point of view, numerical renormalization group (NRG) 7 calculations on the two-impurity Anderson model (TIAM) focused on the properties of its non-Fermi Liquid QCP 8 and pointed out that the interimpurity hopping suppresses the critical transition 9,10 . Several theoretical methods were used to analyze the TIAM, as the slave-boson formalism [11][12][13][14][15][16][17] , the NRG 8,18 , the Embedded Cluster Approximation (ECA) 19 , and the noncrossing approximation 20 . The results obtained confirmed the replacement of the critical transition by a crossover as a consequence of the broken evenodd parity symmetry.…”

Section: Introductionmentioning

confidence: 99%

Transport properties of a two-impurity system: A theoretical approach

et al. 2013

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A system of two interacting Cobalt atoms, at varying distances, has been studied in a recent Scanning Tunneling Microscope experiment by J. Bork et al., Nature Physics 7, 901 (2011). We propose a microscopic model that explains, for all the experimentally analyzed interatomic distances, the physics observed in these experiments. Our proposal is based on the two-impurity Anderson model, with the inclusion of a two-path geometry for charge transport. This many-body system is treated in the finite-U Slave Boson Mean Field Approximation and the Logarithmic-Discretization Embedded-Cluster Approximation. We physically characterize the different charge transport regimes of this system at various interatomic distances and show that, as in the experiments, the features observed in the transport properties depend on the presence of two impurities but also on the existence of two conducting channels for electron transport. We interpret the splitting observed in the conductance as the result of the hybridization of the two Kondo resonances associated to each impurity.

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Transport in coupled quantum dots: Kondo effect versus antiferromagnetic correlation

Cited by 97 publications

References 39 publications

Interference effects on Kondo-assisted transport through double quantum dots

Interference effects on Kondo-assisted transport through double quantum dots

Swapping Kondo resonances in coupled double quantum dots

Transport properties of a two-impurity system: A theoretical approach

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