Two-path transport measurements on a triple quantum dot

Rogge, M.; Haug, Rolf J.

doi:10.1103/physrevb.77.193306

Cited by 106 publications

(111 citation statements)

References 25 publications

(45 reference statements)

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“…[9][10][11] This interaction is responsible for several fascinating phenomena, e.g., Coulomb blockade, 11,12 and Kondo effect, 7,13,14 leading to characteristic behavior of the thermodynamical and transport properties, which depend drastically on the number of QDs, as well as on their topological configuration in the structure. In recent years, strong on-site interaction in double 13,[15][16][17][18][19][20][21][22][23][24] and triple [25][26][27][28][29][30][31][32] QD (DQD and TQD) structures have received a great deal of attention when in the Kondo regime. However, on-site electron-electron interaction does not exhaust all the possibilities in multiple QD structures, as electrons can, due to their proximity, interact with each other, even when located in different QDs.…”

Section: Introductionmentioning

confidence: 99%

Capacitively coupled double quantum dot system in the Kondo regime

et al. 2011

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A detailed study of the low-temperature physics of an interacting double quantum dot system in a T-shape configuration is presented. Each quantum dot is modeled by a single Anderson impurity and we include an inter-dot electron-electron interaction to account for capacitive coupling that may arise due to the proximity of the quantum dots. By employing a numerical renormalization group approach to a multi-impurity Anderson model, we study the thermodynamical and transport properties of the system in and out of the Kondo regime. We find that the two-stage-Kondo effect reported in previous works is drastically affected by the inter-dot Coulomb repulsion. In particular, we find that the Kondo temperature for the second stage of the two-stage-Kondo effect increases exponentially with the inter-dot Coulomb repulsion, providing a possible path for its experimental observation.

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Section: Introductionmentioning

confidence: 99%

Capacitively coupled double quantum dot system in the Kondo regime

et al. 2011

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“…The device is described in detail in Ref. 15. Figure 1 shows a charging diagram of the triple dot device as a function of the voltages applied to gates G3 and G1.…”

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Noninvasive detection of molecular bonds in quantum dots

Rogge

Haug

2008

Phys. Rev. B

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We performed charge detection on a lateral triple quantum dot with starlike geometry. The setup allows us to interpret the results in terms of two double dots with one common dot. One double dot features weak tunnel coupling and can be understood with atomlike electronic states, the other one is strongly coupled forming moleculelike states. In nonlinear measurements we identified patterns that can be analyzed in terms of the symmetry of tunneling rates. Those patterns strongly depend on the strength of interdot tunnel coupling and are completely different for atomiclike or moleculelike coupled quantum dots allowing the noninvasive detection of molecular bonds. DOI: 10.1103/PhysRevB.78.153310 PACS number͑s͒: 73.21.La, 73.23.Hk, 73.63.Kv Quantum dots are often called artificial atoms 1 due to their discrete electronic level spectrum. When several quantum dots are connected, they start to interact. 2 If the tunneling rate between the dots is small, the electronic wave functions are still constricted to the single-quantum dots and the interaction is dominated by electrostatics with sequential interdot tunneling. In contrast, for large tunneling rates electronic states can be found extended over several dots. These extended states introduce covalent bonding as in real molecules. 3 Whether or not the interdot tunneling rates are sufficient to form coherent moleculelike states is a crucial information in order to properly describe a quantum dot system. Especially for quantum computing purposes 4 coherent states are necessary to form and couple qubits and to implement SWAP gates for qubit manipulation. 5,6 With time resolved charge detection tunneling rates and coupling strengths can be observed directly ͑e.g. Ref. 7͒. With dc-transport experiments, however, there are only a few methods that can give hints for molecular bonds. The width of anticrossings visible in charging diagrams is a measure, 8 although anticrossings appear for capacitively coupled dots as well. In addition the curvature of the lines forming an anticrossing can be used 9 and also the visibility of lines in nonparallel quantum dots. 10 Another alternative is to study excited states. Strongly coupled quantum dots form bonding and antibonding states that are visible in nonlinear measurements. 11 We have studied the impact of the coupling strength on the mean charge of multiple quantum dot systems coupled in series. Using a quantum point contact 12 we analyzed the mean charge in stability diagrams and interpret the results in terms of resonant tunneling. We found that depending on the symmetry of tunneling rates and on the coupling strength, characteristic patterns are formed in nonlinear measurements. This allows us to noninvasively detect the symmetry of tunneling rates and the quality of the interdot coupling.The measurements were performed on a device containing three quantum dots A, B, and C ͑see inset of Fig. 1͒. The device was produced using local anodic oxidation on a GaAs/AlGaAs heterostructure. 13,14 The three dots are positioned in a starl...

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“…Up to now, only three dots in series have been demonstrated to be tunable [9,10] in the few-electron regime. A triple quantum dot geometry in a star-like configuration has been demonstrated, but the geometry did not allow tunneling between all close-by dots and the few-electron regime was not reached [11].Here we present the first step towards the transfer of a single electron spin on a closed path using a series of quantum dots in a square-like geometry. We demonstrate that we are able to set the system in the few-electron regime using charge detection techniques and therefore to remove the other electrons along the path.…”

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A few-electron quadruple quantum dot in a closed loop

Thalineau

Hermelin

Wieck

et al. 2012

Applied Physics Letters

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We report the realization of a quadruple quantum dot device in a square-like configuration where a single electron can be transferred on a closed path free of other electrons. By studying the stability diagrams of this system, we demonstrate that we are able to reach the few-electron regime and to control the electronic population of each quantum dot with gate voltages. This allows us to control the transfer of a single electron on a closed path inside the quadruple dot system. This work opens the route towards electron spin manipulation using spin-orbit interaction by moving an electron on complex paths free of electrons. PACS numbers:Controlling the path of a single electron in semiconducting nanostructures is an interesting tool in the context of spin qubits systems. In particular, it opens the route towards the transport of quantum information on a chip and represents a potential strategy to scale up the number of spin qubits in interaction [1]. In addition, in presence of spin-orbit interaction, it represents an interesting way to manipulate coherently the spin of a single electron [2][3][4]. Recently, fast and efficient single electron transport could be obtained by assisting the transport through a 1D-channel electrostatically defined with surface acoustic waves on AlGaAs heterostructures [5,6]. Nevertheless, such a technique is restricted to displacements on a straight line. To perform more complex displacements, engineering the path of the electron with series of quantum dots is a promising alternative. In this context, it has been demonstrated that topological spin manipulation can be obtained if the electron is transported adiabatically on a closed path under spin-orbit interaction [7,8].In order to preserve spin information during transport, all other electrons of the heterostructure potentially present along the electron path have to be removed. Therefore all dots have to be emptied and one needs to control them in the so called "few-electron regime". Up to now, only three dots in series have been demonstrated to be tunable [9,10] in the few-electron regime. A triple quantum dot geometry in a star-like configuration has been demonstrated, but the geometry did not allow tunneling between all close-by dots and the few-electron regime was not reached [11].Here we present the first step towards the transfer of a single electron spin on a closed path using a series of quantum dots in a square-like geometry. We demonstrate that we are able to set the system in the few-electron regime using charge detection techniques and therefore to remove the other electrons along the path. Moreover, the tunability of the four-dot system allows a single electron to be transported along a closed path isolated from the other electrons of the structure. The quantum dot system is fabricated using a GaAs/AlGaAs heterostructure grown by molecular beam epitaxy, with a two-dimensional electron gas (2DEG) 100nm below the surface (density 2 × 10 11 cm −2 and mobility 1 × 10 6 V −1 s −1 ). By applying negative voltages to the meta...

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Two-path transport measurements on a triple quantum dot

Cited by 106 publications

References 25 publications

Capacitively coupled double quantum dot system in the Kondo regime

Capacitively coupled double quantum dot system in the Kondo regime

Noninvasive detection of molecular bonds in quantum dots

A few-electron quadruple quantum dot in a closed loop

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