Your search keyword '"twisted bilayer graphene"' showing total 5 results

1. Unusual magnetotransport in twisted bilayer graphene.

Author

Finney, Joe, Sharpe, Aaron L., Fox, Eli J., Hsueh, Connie L., Parker, Daniel E., Yankowitz, Matthew, Chen, Shaowen, Watanabe, Kenji, Takashi Taniguchi, Dean, Cory R., Vishwanath, Ashvin, Kastner, M. A., and Goldhaber-Gordon, David

Subjects

*GRAPHENE, *LANDAU levels, *BENT functions, *MAGNETORESISTANCE, *BUTTERFLIES

Abstract

We present transport measurements of bilayer graphene with a 1.38? interlayer twist. As with other devices with twist angles substantially larger than the magic angle of 1.1?, we do not observe correlated insulating states or band reorganization. However, we do observe several highly unusual behaviors in magnetotransport. For a large range of densities around half filling of the moir'e bands, magnetoresistance is large and quadratic. Over these same densities, the magnetoresistance minima corresponding to gaps between Landau levels split and bend as a function of density and field. We reproduce the same splitting and bending behavior in a simple tight-binding model of Hofstadter's butterfly on a triangular lattice with anisotropic hopping terms. These features appear to be a generic class of experimental manifestations of Hofstadter's butterfly and may provide insight into the emergent states of twisted bilayer graphene. [ABSTRACT FROM AUTHOR]

Published

2022

2. Superconductivity, correlated insulators, and Wess-Zumino-Witten terms in twisted bilayer graphene.

Author

Christos, Maine, Sachdev, Subir, and Scheurer, Mathias S.

Subjects

*GRAPHENE, *SUPERCONDUCTIVITY, *LOW temperatures, *SKYRMIONS, *FERMIONS

Abstract

Recent experiments on twisted bilayer graphene have shown a high-temperature parent state with massless Dirac fermions and broken electronic flavor symmetry; superconductivity and correlated insulators emerge from this parent state at lower temperatures. We propose that the superconducting and correlated insulating orders are connected by Wess-Zumino-Witten terms, so that defects of one order contain quanta of another order and skyrmion fluctuations of the correlated insulator are a "mechanism" for superconductivity. We present a comprehensive listing of plausible low-temperature orders and the parent flavor symmetry-breaking orders. The previously characterized topological nature of the band structure of twisted bilayer graphene plays an important role in this analysis. [ABSTRACT FROM AUTHOR]

Published

2020

3. Intrinsically undamped plasmon modes in narrow electron bands.

Author

Lewandowski, Cyprian and Levitov, Leonid

Subjects

*LANDAU damping, *SURFACE plasmons, *ELECTRONS, *COHERENCE (Optics), *BAND gaps

Abstract

Surface plasmons in 2-dimensional electron systems with narrow Bloch bands feature an interesting regime in which Landau damping (dissipation via electron-hole pair excitation) is completely quenched. This surprising behavior is made possible by strong coupling in narrow-band systems characterized by large values of the "fine structure" constant α=e²/ℏκvF. Dissipation quenching occurs when dispersing plasmon modes rise above the particle-hole continuum, extending into the forbidden energy gap that is free from particle-hole excitations. The effect is predicted to be prominent in moiré graphene, where at magic twist-angle values, flat bands feature α≫1. The extinction of Landau damping enhances spatial optical coherence. Speckle-like interference, arising in the presence of disorder scattering, can serve as a telltale signature of undamped plasmons directly accessible in near-field imaging experiments. [ABSTRACT FROM AUTHOR]

Published

2019

4. Quasicrystalline 30° twisted bilayer graphene as an incommensurate superlattice with strong interlayer coupling.

Author

Wei Yao, Eryin Wang, Changhua Bao, Yiou Zhang, Kenan Zhang, Kejie Bao, Chun Kai Chan, Chaoyu Chen, Avila, Jose, Asensio, Maria C., Junyi Zhu, and Shuyun Zhou

Subjects

*QUASICRYSTALS, *BILAYERS (Solid state physics), *GRAPHENE, *ELECTRONIC structure, *SUPERLATTICES

Abstract

The interlayer coupling can be used to engineer the electronic structure of van der Waals heterostructures (superlattices) to obtain properties that are not possible in a single material. So far research in heterostructures has been focused on commensurate superlattices with a long-ranged Moiré period. Incommensurate heterostructures with rotational symmetry but not translational symmetry (in analogy to quasicrystals) are not only rare in nature, but also the interlayer interaction has often been assumed to be negligible due to the lack of phase coherence. Here we report the successful growth of quasicrystalline 30° twisted bilayer graphene (30°-tBLG), which is stabilized by the Pt(111) substrate, and reveal its electronic structure. The 30°-tBLG is confirmed by low energy electron diffraction and the intervalley double-resonance Raman mode at 1383 cm-1. Moreover, the emergence of mirrored Dirac cones inside the Brillouin zone of each graphene layer and a gap opening at the zone boundary suggest that these two graphene layers are coupled via a generalized Umklapp scattering mechanism--that is, scattering of a Dirac cone in one graphene layer by the reciprocal lattice vector of the other graphene layer. Our work highlights the important role of interlayer coupling in incommensurate quasicrystalline superlattices, thereby extending band structure engineering to incommensurate superstructures. [ABSTRACT FROM AUTHOR]

Published

2018

5. Quasicrystalline 30° twisted bilayer graphene as an incommensurate superlattice with strong interlayer coupling.

Author

Yao W, Wang E, Bao C, Zhang Y, Zhang K, Bao K, Chan CK, Chen C, Avila J, Asensio MC, Zhu J, and Zhou S

Abstract

The interlayer coupling can be used to engineer the electronic structure of van der Waals heterostructures (superlattices) to obtain properties that are not possible in a single material. So far research in heterostructures has been focused on commensurate superlattices with a long-ranged Moiré period. Incommensurate heterostructures with rotational symmetry but not translational symmetry (in analogy to quasicrystals) are not only rare in nature, but also the interlayer interaction has often been assumed to be negligible due to the lack of phase coherence. Here we report the successful growth of quasicrystalline 30° twisted bilayer graphene (30°-tBLG), which is stabilized by the Pt(111) substrate, and reveal its electronic structure. The 30°-tBLG is confirmed by low energy electron diffraction and the intervalley double-resonance Raman mode at 1383 cm -1 Moreover, the emergence of mirrored Dirac cones inside the Brillouin zone of each graphene layer and a gap opening at the zone boundary suggest that these two graphene layers are coupled via a generalized Umklapp scattering mechanism-that is, scattering of a Dirac cone in one graphene layer by the reciprocal lattice vector of the other graphene layer. Our work highlights the important role of interlayer coupling in incommensurate quasicrystalline superlattices, thereby extending band structure engineering to incommensurate superstructures., Competing Interests: The authors declare no conflict of interest.

Published

2018