Transport between twisted graphene layers

Bistritzer, Rafi; MacDonald, Allan H.

doi:10.1103/physrevb.81.245412

Cited by 183 publications

(230 citation statements)

References 36 publications

(69 reference statements)

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“…From a theoretical perspective, twisted bilayer graphene (TBG) has been examined extensively using both continuum [6][7][8][9] and ab-initio [10][11][12][13][14] approaches. These studies have shown that the individual monolayers become significantly decoupled by the rotational faults.…”

Section: Introductionmentioning

confidence: 99%

Long-range atomic ordering and variable interlayer interactions in two overlapping graphene lattices with stacking misorientations

et al. 2012

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The low energy electronic dispersion of graphene is extremely sensitive to the nearest layer interaction and thus the stacking sequence. Here, we report a method to examine the effect of stacking misorientation in bilayer graphene by transferring chemical vapor deposited (CVD) graphene onto monolithic graphene epitaxially grown on silicon carbide (SiC) (0001). The resulting hybrid bilayer graphene displays long-range Moiré diffraction patterns having various misorientations even as it exhibits electron reflectivity spectra nearly identical to epitaxial bilayer graphene grown directly on SiC. These varying twist angles affect the 2D (G')-band shape of the Raman spectrum indicating regions of both a monolayer-like single π state and Bernal-like split π states brought about by the differing interlayer interactions. This hybrid bilayer graphene fabricated via a transfer process therefore offers a means to systematically study the electronic properties of bilayer graphene films as a function of stacking misorientation angle.

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Section: Introductionmentioning

confidence: 99%

Long-range atomic ordering and variable interlayer interactions in two overlapping graphene lattices with stacking misorientations

et al. 2012

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“…It is also implicit in Eq. (12) that the top and bottom graphene lattices have a common lattice point [17]; a rigid horizontal translation between lattices adds an additional overall phase to the matrix T j [18]. We stress, however, that relative phases in T j do not alter in any significant way the physics of tunneling in Eq.…”

Section: Model Parametersmentioning

confidence: 98%

“…Indeed, incommensurability between graphene lattices already suppresses interlayer hybridization, regardless of the layer separation being a fraction of a nanometer, thus enabling the sequential tunneling regime [18]. Furthermore, the massless Dirac spectrum, and thus Eq.…”

Section: Other Graphene-based Bistable Systemsmentioning

confidence: 99%

“…rapidly on the reciprocal lattice vector G 1,2 scale [17,18]. This leads to the tunneling Hamiltonian…”

Section: Sequential Tunneling Modelmentioning

confidence: 99%

“…Here H 1,2 are the free-particle terms describing massless Dirac particles in each graphene layer, and T 12 describes the interlayer tunnel coupling [17][18][19]. The free particle terms are…”

Section: Sequential Tunneling Modelmentioning

confidence: 99%

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Resonant tunneling and intrinsic bistability in twisted graphene structures

2016

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We predict that vertical transport in heterostructures formed by twisted graphene layers can exhibit a unique bistability mechanism. Intrinsically bistable I -V characteristics arise from resonant tunneling and interlayer charge coupling, enabling multiple stable states in the sequential tunneling regime. We consider a simple trilayer architecture, with the outer layers acting as the source and drain and the middle layer floating. Under bias, the middle layer can be either resonant or nonresonant with the source and drain layers. The bistability is controlled by geometric device parameters easily tunable in experiments. The nanoscale architecture can enable uniquely fast switching times.

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Engineering the Electronic Structure of Graphene

Zhan¹,

Yan²,

Lai³

et al. 2012

Advanced Materials

147

101

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Graphene exhibits many unique electronic properties owing to its linear dispersive electronic band structure around the Dirac point, making it one of the most studied materials in the last 5-6 years. However, for many applications of graphene, further tuning its electronic band structure is necessary and has been extensively studied ever since graphene was first isolated experimentally. Here we review the major progresses made in electronic structure engineering of graphene, namely by electric and magnetic fields, chemical intercalation and adsorption, stacking geometry, edge-chirality, defects, as well as strain.

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Transport between twisted graphene layers

Cited by 183 publications

References 36 publications

Long-range atomic ordering and variable interlayer interactions in two overlapping graphene lattices with stacking misorientations

Long-range atomic ordering and variable interlayer interactions in two overlapping graphene lattices with stacking misorientations

Resonant tunneling and intrinsic bistability in twisted graphene structures

Engineering the Electronic Structure of Graphene

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