Interacting topological edge channels

Strunz, Jonas; Wiedenmann, Jonas; Fleckenstein, Christoph; Lunczer, Lukas; Beugeling, Wouter; Müller, Valentin; Shekhar, Pragya; Ziani, N. Traverso; Shamim, Saquib; Kleinlein, Johannes; Buhmann, H.; Trauzettel, Björn; Molenkamp, Laurens W.

doi:10.1038/s41567-019-0692-4

Cited by 80 publications

(78 citation statements)

References 52 publications

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“…Taking into account, the electron-electron interaction makes it also possible to construct effective two-qubit computational schemes in two coupled interferometers based on conventional materials 35,36 , on edge states of the integer quantum Hall effect 37,38 and on helical states 34 . Signatures of electron-electron interaction in HES was already observed experimentally 39,40 .…”

Section: Introductionmentioning

confidence: 56%

Coherent spin transport through helical edge states of topological insulator

2020

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We study coherent spin transport through helical edge states of topological insulator tunnel-coupled to metallic leads. We demonstrate that unpolarized incoming electron beam acquires finite polarization after transmission through such a setup provided that edges contain at least one magnetic impurity. The finite polarization appears even in the fully classical regime and is therefore robust to dephasing. There is also a quantum magnetic field-tunable contribution to the polarization, which shows sharp identical Aharonov-Bohm resonances as a function of magnetic flux—with the period hc/2e—and survives at relatively high temperature. We demonstrate that this tunneling interferometer can be described in terms of ensemble of flux-tunable qubits giving equal contributions to conductance and spin polarization. The number of active qubits participating in the charge and spin transport is given by the ratio of the temperature and the level spacing. The interferometer can effectively operate at high temperature and can be used for quantum calculations. In particular, the ensemble of qubits can be described by a single Hadamard operator. The obtained results open wide avenue for applications in the area of quantum computing.

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Section: Introductionmentioning

confidence: 56%

Coherent spin transport through helical edge states of topological insulator

2020

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“…The existence of the camel back in the band structure of these QWs has been known for many decades (14,15) and has also attracted attention recently (7,16). The large DOS at the camel back has been shown to give rise to an interaction-induced 0.5 anomaly in the HgTe-based topological quantum point contacts (17).…”

Section: Resultsmentioning

confidence: 99%

Emergent quantum Hall effects below 50 mT in a two-dimensional topological insulator

et al. 2020

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The realization of the quantum spin Hall effect in HgTe quantum wells has led to the development of topological materials, which, in combination with magnetism and superconductivity, are predicted to host chiral Majorana fermions. However, the large magnetization in conventional quantum anomalous Hall systems makes it challenging to induce superconductivity. Here, we report two different emergent quantum Hall effects in (Hg,Mn)Te quantum wells. First, a previously unidentified quantum Hall state emerges from the quantum spin Hall state at an exceptionally low magnetic field of ~50 mT. Second, tuning toward the bulk p-regime, we resolve quantum Hall plateaus at fields as low as 20 to 30 mT, where transport is dominated by a van Hove singularity in the valence band. These emergent quantum Hall phenomena rely critically on the topological band structure of HgTe, and their occurrence at very low fields makes them an ideal candidate for realizing chiral Majorana fermions.

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“…Let us now consider the case where a gate partly covers the nanowire, thereby locally changing the SIA and the RSOC of the nanowire region underneath, similarly to what occurs in constrictions in quantum spin Hall systems [79][80][81]. This situation, sketched in Fig.…”

Section: Interface Bound Statesmentioning

confidence: 99%

Confinement versus interface bound states in spin-orbit coupled nanowires

2020

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Semiconductor nanowires with strong Rashba spin-orbit coupling are currently on the spotlight of several research fields such as spintronics, topological materials and quantum computation. While most theoretical models assume an infinitely long nanowire, in actual experimental setups the nanowire has a finite length, is contacted to metallic electrodes and is partly covered by gates. By taking these effects into account through an inhomogeneous spin-orbit coupling profile, we show that in general two types of bound states arise in the nanowire, namely confinement bound states and interface bound states. The appearance of confinement bound states, related to the finite length of the nanowire, is favoured by a mismatch of the bulk band bottoms characterizing the lead and the nanowire, and occurs even in the absence of magnetic field. In contrast, an interface bound states may only appear if a magnetic field applied perpendicularly to the spin-orbit field direction overcomes a critical value, and is favoured by an alignment of the band bottoms of the two regions across the interface. We describe in details the emergence of these two types of bound states, pointing out their differences. Furthermore, we show that when a nanowire portion is covered by a gate the application of a magnetic field can change the nature of the electronic ground state from a confinement to an interface bound state, determining a redistribution of the electron charge.

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Interacting topological edge channels

Cited by 80 publications

References 52 publications

Coherent spin transport through helical edge states of topological insulator

Coherent spin transport through helical edge states of topological insulator

Emergent quantum Hall effects below 50 mT in a two-dimensional topological insulator

Confinement versus interface bound states in spin-orbit coupled nanowires

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