Entanglement switching via the Kondo effect in triple quantum dots

Tooski, S. B.; Bułka, Bogdan R.; Žitko, Rok; Ramšak, A.

doi:10.1140/epjb/e2014-41025-6

Cited by 18 publications

(17 citation statements)

References 57 publications

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“…g , which results in the maximum of the spinup/spin-down conductance in the vicinity of V g = ∓V (3) g . Consequently, the total conductance g(V g ) = g ↑ (V g ) + …”

Section: B Up-down Asymmetrymentioning

confidence: 99%

“…Nanostructures based on quantum dots attract growing interest due to an opportunity of tuning of their transport and magnetic properties [1][2][3][4][5][6][7], which makes them promising candidates for quantum spintronics and quantum information processing applications [8][9][10][11][12][13][14][15]. At appropriate conditions, these systems consist of discrete energy levels of quantum dots, which are hybridized with the leads, having continuous energy bands.…”

Section: Introductionmentioning

confidence: 99%

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Functional renormalization group study of parallel double quantum dots: Effects of asymmetric dot-lead couplings

Проценко

Катанин

2017

Phys. Rev. B

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We explore the effects of asymmetry of hopping parameters between double parallel quantum dots and the leads on the conductance and a possibility of local magnetic moment formation in this system using functional renormalization group approach with the counterterm. We demonstrate a possibility of a quantum phase transition to a local moment regime (so called singular Fermi liquid (SFL) state) for various types of hopping asymmetries and discuss respective gate voltage dependences of the conductance. It is shown, that depending on the type of the asymmetry, the system can demonstrate either a first order quantum phase transition to SFL state, accompanied by a discontinuous change of the conductance, similarly to the symmetric case, or the second order quantum phase transition, in which the conductance is continuous and exhibits Fano-type asymmetric resonance near the transition point. A semi-analytical explanation of these different types of conductance behavior is presented.

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“…g , which results in the maximum of the spinup/spin-down conductance in the vicinity of V g = ∓V (3) g . Consequently, the total conductance g(V g ) = g ↑ (V g ) + …”

Section: B Up-down Asymmetrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Functional renormalization group study of parallel double quantum dots: Effects of asymmetric dot-lead couplings

Проценко

Катанин

2017

Phys. Rev. B

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“…This quantum transition was investigated in several theoretical studies as a unique feature of the Kondo effect for a triangular loop of three magnetic impurities. 44,47,48) In the present study, we have focused on the KIEP in the equilateral TTQD, and the result also holds for the lower-symmetry case t bc > t c .…”

Section: Summary and Concluding Remarksmentioning

confidence: 72%

Antisymmetric Spin–Orbit Coupling Effect on Kondo-Induced Electric Polarization in a Triangular Triple Quantum Dot

2017

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We study the local antisymmetric spin-orbit (ASO) coupling effect on spin, orbital, and charge degrees of freedom for the Kondo effect in a triangular triple quantum dot (TTQD). Here, one of the three QDs is coupled to a metallic lead through electron tunneling, and a local electric polarization is induced by the Kondo effect. The ASO interaction is introduced in the other two coupled QDs on the opposite side of the lead. Generally, the ASO coupling effect is very weak and not easily detectable, but it essentially causes spin and charge reconfigurations in the TTQD through the Kondo effect. Using an extended Anderson model for the TTQD Kondo system, we elucidate that the ASO coupling gives rise to a considerable reduction of the emergent electric polarization, as a consequence of the parity mixing of molecular orbitals in the triangular loop as well as the spin-up and spin-down coupling of local electrons. The latter leads to a local diamagnetic susceptibility owing to the ASO coupled spins. We also show that the Kondo-induced electric polarization can be controlled by the ASO coupling as well as by the magnetic flux penetrating through the TTQD.

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“…In attempt to propose such correlation functions, one need to point out the relevance of quantum fluctuations between electronic doubly-occupied sites and unoccupied sites and between singly occupied sites with spin up and spin down in lattice models, as suggested before by numerous authors [15][16][17][18][19]. The concept quantum entanglement [20,21], together with entanglement measures such as the concurrence [22], was adopted to quantify the above-mentioned fluctuations in various systems [23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41], including basic spin models [23][24][25]42], fermionic systems [26][27][28][29][30][31], or systems with spin and orbital degrees of freedom [32][33][34][35]. For an open fermionic system (namely: acorrelated quantum dot attached to the leads) we found that the concurrence, defined separately for charge and spin degrees of freedom, allowed one to distinguish between different quantum transport regimes of the system [36].…”

Section: Introductionmentioning

confidence: 99%

Pairwise entanglement and the Mott transition for correlated electrons in nanochains

Rycerz

2017

New J. Phys.

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Pairwise entanglement, calculated separately for charge and spin degrees of freedom, is proposed as a ground-state signature of the Mott transition in correlated nanoscopic systems. Utilizing the exact diagonalization-ab initio, for chains containing N 16  hydrogenic-like atoms (at the half filling),we find that the vanishing of the nearest-neighbor charge concurrence indicates the crossover from apartly-localized quantum liquid to the Mott insulator. Spin concurrence remains nonzero at the insulating phase, showing that the decopling of spin and charge degrees of freedom may manifest itself by wavefunctions entangled in spin, but separable in charge coordinates. At the quarter filling, the analysis for N 20  shows that spin concurrence vanishes immediately when the charge-energy gap obtained from the scaling with N 1 0  vanishes, constituting afinite-system version of the Mott transition. Analytic derivations of the formulas expressing either charge or spin concurrence in terms of ground-state correlation functions are also provided.

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Entanglement switching via the Kondo effect in triple quantum dots

Cited by 18 publications

References 57 publications

Functional renormalization group study of parallel double quantum dots: Effects of asymmetric dot-lead couplings

Functional renormalization group study of parallel double quantum dots: Effects of asymmetric dot-lead couplings

Antisymmetric Spin–Orbit Coupling Effect on Kondo-Induced Electric Polarization in a Triangular Triple Quantum Dot

Pairwise entanglement and the Mott transition for correlated electrons in nanochains

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