Subnanometre-wide electron channels protected by topology

Pauly, Christian; Rasche, Bertold; Koepernik, Klaus; Liebmann, Marcus; Pratzer, M.; Richter, Manuel; Kellner, Jens; Eschbach, Markus; Kaufmann, Bernhard; Pluciński, Ł.; Schneider, Claus M.; Ruck, Michael; Brink, Jeroen van den; Morgenstern, Markus

doi:10.1038/nphys3264

Cited by 127 publications

(173 citation statements)

References 34 publications

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“…They have been used to categorize the quantum Hall effect [6,7] as well as to predict a non-magnetic quantized transversal conductance in superfluids [8]. More recently, they led to the experimental discovery of two-dimensional (2D) topological insulators (TIs) [9][10][11], strong and weak three-dimensional (3D) TIs [12][13][14][15][16][17], topological crystalline insulators [18,19] and the anomalous quantum Hall effect [20,21]. The strong 3DTIs are so far the most versatile class in terms of different realizations in materials [3-5, 22, 23].…”

Section: Introductionmentioning

confidence: 99%

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

et al. 2015

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Using low temperature scanning tunneling spectroscopy, we probe the Landau levels of the topologically protected state of Sb2Te3(0001) after in-situ cleavage of a single crystal. Landau levels are visible for magnetic fields B ≥ 2 T at energies, which confirm the Dirac type dispersion including the zeroth Landau level. We find different Dirac velocities for the lower and the upper part of the Dirac cone in reasonable agreement with previous density functional theory data. The Dirac point deduced from the zeroth Landau level shifts by about 40 meV between different areas of the sample indicating long range potential fluctuations. The local potentials are correlated to different local defect densities varying slightly stronger than expected from a statistical distribution. Moreover, the width of the Landau level peaks is analyzed. It is found to increase, mostly linearly, with the energy distance to the Fermi level. Consequently, we attribute the peak width to a dominating scattering of the hot quasiparticles by electron-electron interaction.

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Section: Introductionmentioning

confidence: 99%

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

et al. 2015

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“…15 Subsequently, this hypothesis was strengthened by scanning tunneling microscopy (STM) experiments. 16 By STM topography, the investigated [001] surface was found to exhibit areas with both types of layers. Clear signatures of one-dimensional (1D) states were observed in the band gap only at step edges of cationic surface layers.…”

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confidence: 99%

“…However, the related surface-layer gap was found 0.25 eV below the Fermi level (E F ). 16 The [(Bi 4 Rh) 3 A confirmation of the weak 3D TI state of Bi 14 Rh 3 I 9 would require to observe the QSH effect on the mentioned 1D edge states. 22 However, related transport experiments make only sense if the observed intrinsic doping is compensated by reasonable means and, thus, the topological gap with the edge states is shifted to the Fermi level.…”

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confidence: 99%

Chemical Gating of a Weak Topological Insulator: Bi₁₄Rh₃I₉

Ghimire

Richter

2017

Nano Lett.

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The compound Bi 14 Rh 3 I 9 has recently been suggested as a weak 3D topological insulator (TI) on the basis of angle-resolved photoemission and scanning-tunneling experiments in combination with density-functional (DF) electronic structure calculations. These methods unanimously support the topological character of the headline compound, but a compelling confirmation could only be obtained by dedicated transport experiments. The latter, however, are biased by an intrinsic n-doping of the material's surface due to its polarity. Electronic reconstruction of the polar surface shifts the topological gap below the Fermi energy, which would also prevent any future device application. Here, we report the results of DF slab calculations for chemically gated and counter-doped surfaces of Bi 14 Rh 3 I 9 . We demonstrate that both methods can be used to compensate the surface polarity without closing the electronic gap. A confirmation of the weak 3D TI state of Bi 14 Rh 3 I 9 would require to observe the QSH effect on the mentioned 1D edge states. 22 However, related transport experiments make only sense if the observed intrinsic doping is compensated by reasonable means and, thus, the topological gap with the edge states is shifted to the Fermi level.There are several possible ways to compensate the surface polarity: (i) physical gating by preparation of a dielectric gate structure and applying the electric field effect; (ii) chemical gating by deposition of an oxidizing agent; or (iii) counter-doping of the surface layer.Here, we report results of investigations into the two latter possibilities by means of DF 3 calculations. In particular, we study the effects of Iodine deposition as a sparse overlayer and of counter-doping by exchanging surface-layer Bi atoms by Sn. The results are expected to provide suggestions for the preparation of forthcoming transport experiments, which are required to confirm the topological state of Bi 14 Rh 3 I 9 or similar systems. We are not aware of any observation of the QSH effect on another suggested weak 3D TI material. All DF calculations were done with the full-potential local-orbital (FPLO) code 23 using the local density approximation (LDA) in the PW92 parametrization. 24 The self-consistent calculations were carried out with spin-orbit coupling (SOC) included. This effort is necessary because the involved elements have a sizable SOC strength which is responsible for opening the band gap. The following basis states are treated as valence states: Bi: 5s, 5p, 5d, 6s, 7s, 6p, 7p, 6d; Rh: 4s, 4p, 5s, 6s, 4d, 5d, 5p; I: 4s, 4p, 4d, 5s, 6s, 5p, 6p, 5d.In order to simulate the [001] surface of a bulk sample, we considered a series of slabs with different thickness (1.25 to 3.75 nm), varying from one to three structural layers. The considered layer stacks have the same lateral cell dimensions as the experimental bulk structure, 15 and equivalent atomic positions. Thus, the elementary cell of a slab with one, two, and three structural layers contains two, four, and six chemical uni...

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“…16 Yet, in spite of the number of realizations of 3D topological insulators, 17 there have not been many proposals for realizing a WTI in stoichiometric compounds. 18 WTI may be realized in superlattice systems.…”

Section: Introductionmentioning

confidence: 99%

Manipulating quantum channels in weak topological insulator nanoarchitectures

et al. 2015

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In strong topological insulators protected surface states are always manifest, while in weak topological insulators (WTI) the corresponding metallic surface states are either manifest or hidden, depending on the orientation of the surface. One can design a nanostep on the surface of WTI such that a protected helical channel appears along it. In a more generic WTI nanostructure, multiple sets of such quasi-1D channels emerge and are coupled to each other. We study the response of the electronic spectrum associated with such quasi-1D surface modes against a magnetic flux piercing the system in the presence of disorder, and find a non-trivial, connected spectral flow as a clear signature indicating the immunity of the surface modes to disorder. We propose that the WTI nanoarchitecture is a promising platform for realizing topologically protected nanocircuits immune to disorder.

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Subnanometre-wide electron channels protected by topology

Cited by 127 publications

References 34 publications

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

Chemical Gating of a Weak Topological Insulator: Bi₁₄Rh₃I₉

Manipulating quantum channels in weak topological insulator nanoarchitectures

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Subnanometre-wide electron channels protected by topology

Cited by 127 publications

References 34 publications

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

Spatially resolved Landau level spectroscopy of the topological Dirac cone of bulk-typeSb2Te3(0001): Potential fluctuations and quasiparticle lifetime

Chemical Gating of a Weak Topological Insulator: Bi14Rh3I9

Manipulating quantum channels in weak topological insulator nanoarchitectures

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Product

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Chemical Gating of a Weak Topological Insulator: Bi₁₄Rh₃I₉