Helical quantum Hall phase in graphene on SrTiO
            <sub>3</sub>

Veyrat, Louis; Déprez, Corentin; Coissard, Alexis; Li, Xiaoxi; Gay, Frédéric; Watanabe, Kenji; Taniguchi, Takashi; Han, Zheng; Piot, B. A.; Sellier, H.; Sacépé, Benjamin

doi:10.1126/science.aax8201

Cited by 81 publications

(91 citation statements)

References 51 publications

(110 reference statements)

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“…For a better comparison with the previously discovered helical QH phase in graphene 20 , 21 , we zoom in the R xx and R yx data in the Chern insulator regime, as displayed in Fig. 4a .…”

Section: Resultsmentioning

confidence: 99%

“…It is likely that the QAH plateau will not survive forever because extreme conditions may induce other topological phases, as exemplified by the fractional QH effect 19 . Recently, it was demonstrated that helical phases analogous to the QSH phase exist in charge-neutral graphene 20 , 21 and non-symmorphic KHgSb crystal 22 in strong magnetic fields, which are characterized by quantized longitudinal resistance ( R xx ) and zero Hall resistance ( R yx ) plateau in certain magnetic fields and gate voltage ( V g ) ranges. Inspired by these discoveries, it is imperative to find out the fate of the Chern insulator phase in MnBi 2 Te 4 in strong magnetic fields, as has been discussed theoretically for magnetic TIs 23 , 24 .…”

Section: Introductionmentioning

confidence: 99%

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Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

et al. 2021

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The intrinsic antiferromagnetic topological insulator MnBi2Te4 provides an ideal platform for exploring exotic topological quantum phenomena. Recently, the Chern insulator and axion insulator phases have been realized in few-layer MnBi2Te4 devices at low magnetic field regime. However, the fate of MnBi2Te4 in high magnetic field has never been explored in experiment. In this work, we report transport studies of exfoliated MnBi2Te4 flakes in pulsed magnetic fields up to 61.5 T. In the high-field limit, the Chern insulator phase with Chern number C = −1 evolves into a robust zero Hall resistance plateau state. Nonlocal transport measurements and theoretical calculations demonstrate that the charge transport in the zero Hall plateau state is conducted by two counter-propagating edge states that arise from the combined effects of Landau levels and large Zeeman effect in strong magnetic fields. Our result demonstrates the intricate interplay among intrinsic magnetic order, external magnetic field, and nontrivial band topology in MnBi2Te4.

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“…For a better comparison with the previously discovered helical QH phase in graphene 20 , 21 , we zoom in the R xx and R yx data in the Chern insulator regime, as displayed in Fig. 4a .…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

et al. 2021

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“…4A and 4B of Ref. [7]) actually suggest that the most accurate quantization happens at T = 90K, rather than at T = 5K. That, along with the negative (albeit fairly small) temperature coefficient of the resistance dR/dT may warrant further studies.…”

mentioning

confidence: 90%

“…In the experiment [7], the graphene sheet was separated by mere 2 − 5nm of a HBN spacer from SrTiO 3 substrate. The latter has a huge ∼ 10 4 and may provide the dielectric screening for the electron-electron interaction in graphene.…”

mentioning

confidence: 99%

Observation of Helical Edge Transport in a Screened Graphene

2019

Journal Club for Condensed Matter Physics

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The strength of electron-electron interaction in a conductor is conventionally characterized by parameter r s = e 2 /( v F ). This dimensionless parameter is the ratio of the Coulomb interaction energy between two electrons separated by a typical distance, i.e., by the Fermi wavelength, to the Fermi energy in a gas of free fermions (v F is the Fermi velocity and is the background dielectric constant of the medium). Starting from a Fermi gas with a non-degenerate ground state, the system would continuously "morph" into a Fermi liquid upon increase of the interaction from r s = 0 to some moderate value. The Fermi liquid description works perfectly well, say, for alkali metals having r s ∼ 1, with the ground state and quasiparticle excitations being direct descendants of those for the free fermions.Situation changes drastically if the free-fermion ground state is degenerate: introduction of interactions then may result in emergence of new electron phases. The free-fermion spectrum may be "flattened" by applying even a small out-of-plane magnetic field to a twodimensional gas of free fermions. Landau quantization gives rise to discrete single-particle energy levels which are flat in the bulk and bend at the boundaries, creating states propagating along the boundary. Electron-electron interaction in a partially-occupied Landau level may result in a variety of phases, including the well-studied phases of the fractional quantum Hall effect.The plot thickens if the free fermions are "living" in a graphene lattice and, in addition, their Fermi level is tuned to the charge neutrality point. Application of a small out-ofplane magnetic field creates a flat level half-filled with electrons carrying the spin and valley labels. In the absence of Zeeman splitting, a slight shift of Fermi level up in energy would create a particle-like state propagating along the edge, while a down-shift would lead to a state propagating in the opposite direction. Ignoring Zeeman energy and interactions, electron states at the charge-neutrality point carry a four-fold degeneracy, on top of the degeneracy associated with the Landau level. How interaction would affect such highlydegenerate system? 1

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“…More importantly, the inability to stabilize patterned graphene edges [4][5][6] derailed the ambitious graphene nanoelectronics effort replacing it with much more modest goals. 16,17 Evidence of the protected graphene edge state [7][8][9][12][13][14] (not to be confused with quantum Hall edge states 14,[18][19][20][21][22][23][24] ) was first found in 40 nm wide self-assembled graphene ribbons that form 25 on the high temperature annealed sidewalls of steps etched on the polar faces of electronics grade hexagonal SiC. 26,27 Electron microscopy revealed that the sidewall ribbons terminated in the SiC, thereby stabilizing and passivating the edges.…”

mentioning

confidence: 99%

Dissipationless zero energy epigraphene edge state for nanoelectronics

Prudkovskiy¹,

Zhang

et al. 2021

Preprint

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The graphene edge state is essential for graphene electronics and fundamental in graphene theory, however it is not observed in deposited graphene. Here we report the discovery of the epigraphene edge state (EGES) in conventionally patterned epigraphene using plasma-based lithography that stabilizes and passivates the edges probably by fusing the graphene edges to the non-polar silicon carbide substrate, as expected. Transport involves a single, essentially dissipationless conductance channel at zero energy up to room temperature. The Fermi level is pinned at zero energy. The EGES does not generate a Hall voltage and the usual quantum Hall effect is observed only after subtraction of the EGES current. EGES transport is highly protected and apparently mediated by an unconventional zero-energy fermion that is half electron and half hole. Interconnected networks involving only the EGES can be patterned, opening the door to a new graphene nanoelectronics paradigm that is relevant for quantum computing.

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Helical quantum Hall phase in graphene on SrTiO ₃

Cited by 81 publications

References 51 publications

Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

Observation of Helical Edge Transport in a Screened Graphene

Dissipationless zero energy epigraphene edge state for nanoelectronics

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Helical quantum Hall phase in graphene on SrTiO 3

Cited by 81 publications

References 51 publications

Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

Magnetic-field-induced robust zero Hall plateau state in MnBi2Te4 Chern insulator

Observation of Helical Edge Transport in a Screened Graphene

Dissipationless zero energy epigraphene edge state for nanoelectronics

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Product

Resources

About

Helical quantum Hall phase in graphene on SrTiO ₃