Tomonaga–Luttinger liquid in the edge channels of a quantum spin Hall insulator

Stühler, R.; Reis, Felix; Müller, Tobias; Helbig, Tobias; Schwemmer, Tilman; Thomale, Ronny; Schäfer, J.; Claessen, R.

doi:10.1038/s41567-019-0697-z

Cited by 108 publications

(151 citation statements)

References 31 publications

(49 reference statements)

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“…systems, including metallic carbon nanotubes [15][16][17] , nanowires 18 , and edge states in 2D systems, have been reported as LLs and show good agreement with theory 19,20 . Although isolated polymer chains have quasi-1D structures, their films are usually in condensed 2D or 3D forms, and these undoubtedly raised questions on whether the conducting polymer could be treated as collections of pure 1D LL systems without considering their detailed condensed forms on the molecular scale.…”

Section: Introductionsupporting

confidence: 60%

A tied Fermi liquid to Luttinger liquid model for the explanation of nonlinear transport in conducting polymers

Wang

Niu

Shao

et al. 2020

Preprint

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Organic conjugated polymers demonstrate great potential in the transistor, solar cell and light-emitting diodes. The performances of those devices are fundamentally governed by charge transport within the active materials. However, the morphology-property relationships and the underpinning charge transport mechanism in polymers remain unclear. Particularly, whether the nonlinear charge transport in doped conducting polymers, i.e., anomalous non-Ohmic behaviors at low temperature, is appropriately formulated within non-Fermi liquid picture is not clear. In this work, via varying crystalline degrees of samples, we carried out systematic investigations on the charge transport nonlinearity in conducting polymers. Possible charge carriers’ dimensionality was discussed with experiments when varying the molecular chain’s crystalline orders. A heterogeneous-resistive-network (HRN) model was proposed based on the tied link between Fermi liquids (FL) and Luttinger liquids (LL), related to the high-ordered crystalline zones and weak-coupled amorphous regions, respectively. This mesoscopic HRN model is experimentally supported by precise electrical and microstructural characterizations, together with theoretic evaluations. Significantly, such model well describes the nonlinear transport behaviors in conducting polymers universally and provides new insights into the microstructure-correlated charge transport in organic conducting/semiconducting systems.

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Section: Introductionsupporting

confidence: 60%

A tied Fermi liquid to Luttinger liquid model for the explanation of nonlinear transport in conducting polymers

Wang

Niu

Shao

et al. 2020

Preprint

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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: 62%

“…For the first time, quantum spin Hall effect was observed in structures based on HgTe/CdTe 53 and InAs/GaSb 54 , which had a rather narrow bulk gap, <100 K. Substantially large values were observed recently in WTe 2 , where gap of the order of 500 K was observed 55 , and in bismuthene grown on a SiC (0001) substrate, where a bulk gap of about 0.8 eV was demonstrated 56,57 (see also recent discussion in ref. 39 ). Thus, recent experimental studies unambiguously indicate the possibility of transport through HES at room temperature, when the condition Δ b ≫ T ≫ Δ, needed for applicability of our theory, can be easily satisfied.…”

Section: Modelmentioning

confidence: 99%

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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“…Interestingly, the Luttinger liquid also applies to bosonic [21], and spin one-dimensional systems [22,23], thus providing a very powerful tool. The experimental consequences of the Luttinger liquid behavior of fermionic systems can be found in very different contexts, ranging from Bechgaard salts [24,25], to quantum wires [26][27][28][29], quantum Hall edges [30][31][32], quantum spin Hall edges [33,34], and carbon nanotubes [35], even in the presence of mechanical vibrations [36,37]. Interestingly, strongly out of equilibrium scenarios can also be inspected within this framework [38][39][40][41][42][43][44][45][46][47][48][49].…”

Section: Introductionmentioning

confidence: 99%

A Short Review on One Dimensional Wigner Crystallization

Ziani¹,

Cavaliere²,

Becerra³

et al. 2020

Preprint

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The simplest possible structural transition that an electronic system can undergo is Wigner crystallization. The aim of this short review is to discuss the main aspects of three recent experimets on the one dimensional Wigner molecule, starting from scratch. To achieve this task, the Luttinger liquid theory of weakly and strongly interacting fermions will be shortly addressed, together with the basic properties of carbon nanotubes that are require. Then, the most relevant properties of Wigner molecules will be addressed, and finally the experiments will be described.

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Tomonaga–Luttinger liquid in the edge channels of a quantum spin Hall insulator

Cited by 108 publications

References 31 publications

A tied Fermi liquid to Luttinger liquid model for the explanation of nonlinear transport in conducting polymers

A tied Fermi liquid to Luttinger liquid model for the explanation of nonlinear transport in conducting polymers

Coherent spin transport through helical edge states of topological insulator

A Short Review on One Dimensional Wigner Crystallization

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