Spatially resolved electronic structure of twisted graphene

Yao, Qiuyan; Bremen, Rik van; Slotman, Guus J.; Zhang, Lijie; Haartsen, Sebastiaan; Sotthewes, Kai; Bampoulis, Pantelis; Boeij, P.L. de; Houselt, Arie van; Yuan, Shengjun; Zandvliet, Henricus J.W.

doi:10.1103/physrevb.95.245116

Cited by 6 publications

(10 citation statements)

References 38 publications

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“…shown in the STM image (Fig. 3(c)), in consistent with that observed in TBG in previous works 1,16,21,22 . This result indicates the presence of the moiré potential in the TTG due to the twist-induced moiré pattern, which is similar as that observed in the TBG.…”

supporting

confidence: 92%

“…3(d)) reveals the same period and circular symmetry of the moiré pattern but exhibits the inverted contrast comparing with that shown in the STM image ( Fig. 3(c)), in consistent with that observed in TBG in previous works 1,16,21,22 . This result indicates the presence of the moiré potential in the TTG due to the twist-induced moiré pattern, which is similar as that observed in the Figure S10) 38 .…”

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confidence: 90%

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Scanning tunneling microscopy and spectroscopy of twisted trilayer graphene

Zuo

Qiao

et al. 2018

Phys. Rev. B

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Twist, as a simple and unique degree of freedom, could lead to enormous novel quantum phenomena in bilayer graphene. A small rotation angle introduces lowenergy van Hove singularities (VHSs) approaching the Fermi level, which result in unusual correlated states in the bilayer graphene. It is reasonable to expect that the twist could also affect the electronic properties of few-layer graphene dramatically. However, such an issue has remained experimentally elusive. Here, by using scanning tunneling microscopy/spectroscopy (STM/STS), we systematically studied a twisted trilayer graphene (TTG) with two different small twist angles between adjacent layers. Two sets of VHSs originating from the two twist angles were observed in the TTG, indicating that the TTG could be simply regarded as a combination of two different twisted bilayer graphene. By using high-resolution STS, we observed split of the VHSs and directly imaged spatial symmetry breaking of electronic states around the VHSs. These results suggest that electron-electron interactions play an important role in affecting the electronic properties of graphene systems with low-energy VHSs.

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confidence: 92%

supporting

confidence: 90%

Scanning tunneling microscopy and spectroscopy of twisted trilayer graphene

Zuo

Qiao

et al. 2018

Phys. Rev. B

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“…Whereas an engineering of a network of helical states with tunable geometry is a challenging problem, the triangular one has been recently observed [20] with help of scanning tunneling spectroscopy (STM) in misoriented graphene bilayers [21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40]. In the presence of a twist local stacking arrangement changes slowly in space in a periodic moiré pattern in which regions with approximate AB and BA stacking are separated by domain walls with helical states .…”

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confidence: 99%

Helical network model for twisted bilayer graphene

2018

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In the presence of a finite interlayer displacement field bilayer graphene has an energy gap that is dependent on stacking and largest for the stable AB and BA stacking arrangements. When the relative orientations between layers are twisted through a small angle to form a moiré pattern, the local stacking arrangement changes slowly. We show that for non-zero displacement fields the low-energy physics of twisted bilayers is captured by a phenomenological helical network model that describes electrons localized on domain walls separating regions with approximate AB and BA stacking. The network band structure is gapless and has of a series of two-dimensional bands with Dirac band-touching points and a density-of-states that is periodic in energy with one zero and one divergence per period. arXiv:1803.06404v1 [cond-mat.mes-hall]

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“…The peaks, which are referred to as Van Hove singularities (VHs), arise due to the hybridization of the Dirac cones of the top and bottom graphene layer. 22 Using the continuum approximation for a bilayer graphene with a small twist angle, the energy gap of the two Van Hove singularities is given by DE VHs ¼ 2 hv F Ksinðh=2Þ À 2t ? , where v F is the Fermi velocity of the twisted graphene bilayer andt ?…”

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confidence: 99%