Strain and curvature induced evolution of electronic band structures in twisted graphene bilayer

Yan, Wei; He, Wen-Yu; Chu, Zhaodong; Liu, Mengxi; Meng, Lan; Dou, Rui-Fen; Zhang, Yanfeng; Liu, Zhongfan; Nie, Jia-Cai; He, Lin

doi:10.1038/ncomms3159

Cited by 176 publications

(152 citation statements)

References 58 publications

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“…In particular, Landau level quantization was observed in a sequence of dI/dV spectra measured in a line across a graphene nanobubble on Pt(111), as shown in Figure 9(c), which arises from giant strain-induced pseudo-magnetic elds in excess of 300 Tesla in highly strained graphene nanobubbles formed on Pt(111) [107]. Similar phenomena were recently reported by Yan et al who observed the Landau level quantization of the strained graphene bilayer in a large pseudomagnetic eld of~100 Tesla [109].…”

Section: Weakly Interacting Graphene/metal Systemssupporting

confidence: 66%

Probing Electronic Properties of Graphene on the Atomic Scale by Scanning Tunneling Microscopy and Spectroscopy

Gao¹

2014

Graphene and 2D Materials

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Atomic scale investigations of the electronic properties of graphene are playing a crucial role in understanding and tuning the exotic properties of this material for its potential device applications. Scanning tunneling microscopy (STM) and spectroscopy (STS) are unique techniques for atomic scale investigations and have been extensively used in graphene research. In this article, we review recent progresses in STM and STS studies of the electronic properties of suspended graphene as well as graphene supported by di erent substrates including graphite, metals, silicon carbide, silicon dioxide and boron nitride.

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Section: Weakly Interacting Graphene/metal Systemssupporting

confidence: 66%

Probing Electronic Properties of Graphene on the Atomic Scale by Scanning Tunneling Microscopy and Spectroscopy

Gao¹

2014

Graphene and 2D Materials

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“…For example, effective gauge fields are introduced when lattice deformation of graphene takes place. Like the effective magnetic field, the produced effective gauge fields influence the Dirac fermions [180]. The Fermi level in undoped graphene lies at the Dirac point where the minimum conductivity values are achieved [181].…”

Section: Electrical Propertiesmentioning

confidence: 99%

Modeling and Simulation of Graphene Based Polymer Nanocomposites: Advances in the Last Decade

Atif¹,

Inam²

2016

Graphene

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Modeling and simulation allow methodical variation of material properties beyond the capacity of experimental methods. The polymers are one of the most commonly used matrices of choice for composites and have found applications in numerous fields. The stiff and fragile structure of monolithic polymers leads to the innate cracks to cause fracture and therefore the engineering applications of monolithic polymers, requiring robust damage tolerance and high fracture toughness, are not ubiquitous. In addition, when "many-parts" cling together to form polymers, a labyrinth of molecules results, which does not offer to electrons and phonons a smooth and continuous passageway. Therefore, the monolithic polymers are bad conductors of heat and electricity. However, it is well established that when polymers are embedded with suitable entities especially nano-fillers, such as metallic oxides, clays, carbon nanotubes, and other carbonaceous materials, their performance is propitiously improved. Among various additives, graphene has recently been employed as nano-filler to enhance mechanical, thermal, electrical, and functional properties of polymers. In this review, advances in the modeling and simulation of grapheme based polymer nanocomposites will be discussed in terms of graphene structure, topographical features, interfacial interactions, dispersion state, aspect ratio, weight fraction, and trade-off between variables and overall performance.

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“…In Bernal stacking, the charge carriers of the graphene bilayer have a parabolic energy spectrum and exhibit chirality that resembles those associated with spin 1. However, a twist between the two layers splits the parabolic band touching into two Dirac cones [13][14][15][16][19][20][21][22][23][24] and changes the chirality of the low-energy quasiparticles to those of spin 1/2 [18,25]. This provides a facile route to tune the electronic properties of graphene bilayer.…”

Section: Introductionmentioning

confidence: 99%

Strain and curvature induced evolution of electronic band structures in twisted graphene bilayer

Cited by 176 publications

References 58 publications

Probing Electronic Properties of Graphene on the Atomic Scale by Scanning Tunneling Microscopy and Spectroscopy

Probing Electronic Properties of Graphene on the Atomic Scale by Scanning Tunneling Microscopy and Spectroscopy

Modeling and Simulation of Graphene Based Polymer Nanocomposites: Advances in the Last Decade

In-plane chiral tunneling and out-of-plane valley-polarized quantum tunneling in twisted graphene trilayer

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