Electrostatic superlattices on scaled graphene lattices

Chen, Szu Chao; Kraft, Rainer; Danneau, R.; Richter, Klaus; Liu, Ming‐Hao

doi:10.1038/s42005-020-0335-1

Cited by 21 publications

(9 citation statements)

References 52 publications

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“…A special case of encapsulated graphene heterostructures is graphene superlattices, where crystallographic axes of graphene and hBN are intentionally aligned. A small (1.8%) mismatch between graphene and hBN crystal lattices results in a periodic moiré potential acting on charge carriers in graphene and leading to the formation of electronic minibands [1][2][3][8][9][10][11][12][13][14][15][16][17] .…”

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confidence: 99%

Long-range ballistic transport of Brown-Zak fermions in graphene superlattices

et al. 2020

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In quantizing magnetic fields, graphene superlattices exhibit a complex fractal spectrum often referred to as the Hofstadter butterfly. It can be viewed as a collection of Landau levels that arise from quantization of Brown-Zak minibands recurring at rational (p/q) fractions of the magnetic flux quantum per superlattice unit cell. Here we show that, in graphene-on-boron-nitride superlattices, Brown-Zak fermions can exhibit mobilities above 106 cm2 V−1 s−1 and the mean free path exceeding several micrometers. The exceptional quality of our devices allows us to show that Brown-Zak minibands are 4q times degenerate and all the degeneracies (spin, valley and mini-valley) can be lifted by exchange interactions below 1 K. We also found negative bend resistance at 1/q fractions for electrical probes placed as far as several micrometers apart. The latter observation highlights the fact that Brown-Zak fermions are Bloch quasiparticles propagating in high fields along straight trajectories, just like electrons in zero field.

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confidence: 99%

Long-range ballistic transport of Brown-Zak fermions in graphene superlattices

et al. 2020

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“…However, the effective continuum model cannot be used to simulate the transport for realistic experimental conditions, while results for the tight-binding models with empirical parameters must be carefully scrutinized to ascertain their reliability. For a large device transport simulation Chen et al [31] applied a scaled graphene lattice with a triangular periodic scalar moiré potential, and successfully reproduced the main features of the secondary Dirac point. However, as we show below, this sim-ple moiré potential does not lead to particle-hole asymmetry.…”

Section: The Modelmentioning

confidence: 99%

“…To emphasize the importance of full relaxation, we plot in Fig. 1(d) the band structure of graphene with a scalar moiré potential [31]: the band degeneracy at high symmetry points is lifted and one finds secondary Dirac points at ±0.225eV. However, in this case the DOS around the two secondary Dirac points are equal and obey particle-hole symmetry (Fig.…”

Section: The Modelmentioning

confidence: 99%

Moiré effects in graphene--hBN heterostructures

Du,

Xu,

Lin

et al. 2020

Preprint

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Encapsulating graphene in hexagonal Boron Nitride has several advantages: the highest mobilities reported to date are achieved in this way, and precise nanostructuring of graphene becomes feasible through the protective hBN layers. Nevertheless, subtle effects may arise due to the differing lattice constants of graphene and hBN, and due to the twist angle between the graphene and hBN lattices. Here, we use a recently developed model which allows us to perform band structure and magnetotransport calculations of such structures, and show that with a proper account of the moiré physics an excellent agreement with experiments can be achieved, even for complicated structures such as disordered graphene, or antidot lattices on a monolayer hBN with a relative twist angle. Calculations of this kind are essential to a quantitative modeling of twistronic devices.

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“…For instance, graphene nanoribbons with different edge orientations exhibit edge-dependent electronic and optical properties 11 – 14 . Here, it is also important to mention that there are recent breakthroughs in the fabrication of the so-called gated (electrostatic) graphene superlattices (GGSLs) 15 , 16 . One of the most attractive aspects of this type of superlattice is the tunability that can be achieved through electrostatic gating in contrast to moiré graphene superlattices.…”

Section: Introductionmentioning

confidence: 99%

Biperiodic superlattices and transparent states in graphene

Alvarado-Goytia

Rodríguez-González

Martı́nez-Orozco

et al. 2022

Sci Rep

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The transmission and transport properties of biperiodic graphene superlattices are studied theoretically. Special attention is paid to the so-called transparent states of biperiodic superlattices. A Dirac-like Hamiltonian is used to describe the charge carriers in graphene. The transfer matrix method and the Landauer–Büttiker formalism are implemented to obtain the transmittance and conductance, respectively. Similar results to those reported for Schrödinger electrons are obtained. However, in the case of Dirac electrons the splitted bands and the transparent states associated to the biperiodicity depend strongly on the angle of incidence as well as the character of the charge carriers. In fact, the dynamic of the splitted bands and transparent states is inverted for holes. The origin of transparent states is unveiled by obtaining an analytic expression for the transmittance. It is found that resonant transmission through single and double barriers gives rise to transparent states. Regarding the transport properties, it is possible to identify the fundamental changes caused by the biperiodicity. In particular, it is found a splitting, shifting, and diminishment of the conductance peaks with respect to the case of regular periodicity. This opens the door to corroborate experimentally the fundamental characteristics of biperiodic gated graphene superlattices through transport measurements.

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Electrostatic superlattices on scaled graphene lattices

Cited by 21 publications

References 52 publications

Long-range ballistic transport of Brown-Zak fermions in graphene superlattices

Long-range ballistic transport of Brown-Zak fermions in graphene superlattices

Moiré effects in graphene--hBN heterostructures

Biperiodic superlattices and transparent states in graphene

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