Strain solitons and topological defects in bilayer graphene

Alden, Jonathan S.; Tsen, Adam W.; Huang, Pinshane Y.; Hovden, Robert; Brown, Lola; Park, Jiwoong; Muller, David A.; McEuen, Paul L.

doi:10.1073/pnas.1309394110

Cited by 478 publications

(627 citation statements)

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“…Forming a junction from layer-stacking domain walls requires patterning fewer leads, but as clearly demonstrated in the samples in Ref. 22, the three-fold symmetry of the underlying graphene lattice restricts intersections of these domain walls to be six-terminal structures. Conductance transi-tions in these six-terminal structures can be calculated and analyzed using the framework established in this paper, though the task will be algebraically more intensive.…”

Section: Discussionmentioning

confidence: 99%

“…In the presence of an interlayer electric field, when the field direction is reversed across a line [15][16][17][18][19][20][21] or when the field is uniform and the layer stacking switches from AB to BA 16,22,23 , the valley-projected Chern number changes by 2 (−2) across the domain wall in valley K (K ). As a result, both types of domain walls host two chiral edge states in each valley with chirality (direction) locked to valley index K or K , as shown in Fig.…”

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confidence: 99%

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Critical behavior of four-terminal conductance of bilayer graphene domain walls

2015

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Bilayer graphene in a perpendicular electric field can host domain walls between regions of reversed field direction or interlayer stacking. The gapless modes propagating along these domain walls, while not strictly topological, nevertheless have interesting physical properties, including valley-momentum locking. A junction where two domain walls intersect forms the analogue of a quantum point contact. We study theoretically the critical behavior of this junction near the pinchoff transition, which is controlled by two separate classes of non-trivial quantum critical points. For strong interactions, the junction can host phases of unique charge and valley conductances. For weaker interactions, the low-temperature charge conductance can undergo one of two possible quantum phase transitions, each characterized by a specific critical exponent and a collapse to a universal scaling function, which we compute.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Critical behavior of four-terminal conductance of bilayer graphene domain walls

2015

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“…For AA stacking, each carbon atoms in the second layer directly aligned on the top of another atom in the first layer, while in bilayer graphene with Bernal or AB stacking, a set of atoms in the second layer sit over the empty centers of hexagons in the first layer. As seen in the scanning transmission electron microscopy (STEM) image of AA-stacked bilayer graphene (see Figure 9(c)) [156], all atomic sites are visible in a hexagonal array and show similar brightness. Whereas in Bernal-stacked bilayer, bright spots having hexagonal symmetry and a spacing of 0.25 nm (close to ) are observed in Figure 9(d).…”

Section: The Structure Of Graphenementioning

confidence: 99%

“…Hopping integrals t and t’ correspond to the in-plane nearest-neighboring and next-nearest-neighboring hopping respectively, and parameter is associated with the main interlayer hopping in bilayer. Atomic-resolution STEM images of (c) AA- and (d) AB-stacked bilayer graphenes [156]. Hexagonal ring in the first (second) or bottom (top) layer is marked with green (orange) color.…”

Section: The Structure Of Graphenementioning

confidence: 99%

Structure of graphene and its disorders: a review

Gao

Lee

et al. 2018

Science and Technology of Advanced Materials

487

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Monolayer graphene exhibits extraordinary properties owing to the unique, regular arrangement of atoms in it. However, graphene is usually modified for specific applications, which introduces disorder. This article presents details of graphene structure, including sp2 hybridization, critical parameters of the unit cell, formation of σ and π bonds, electronic band structure, edge orientations, and the number and stacking order of graphene layers. We also discuss topics related to the creation and configuration of disorders in graphene, such as corrugations, topological defects, vacancies, adatoms and sp3-defects. The effects of these disorders on the electrical, thermal, chemical and mechanical properties of graphene are analyzed subsequently. Finally, we review previous work on the modulation of structural defects in graphene for specific applications.

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“…Excitation spectroscopy reveals the double-resonance nature of such enhancement, and identifies the two resonant states to be the A exciton transition of monolayer WSe 2 and a new hybrid state present only in WSe 2 /hBN heterostructures. The observation of an interlayer electron-phonon interaction could open up new ways to engineer electrons and phonons for device applications.Van der Waals heterostructures of atomically thin twodimensional (2D) crystals are a new class of material in which novel quantum phenomena can emerge from layer-layer interactions [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] . For example, electron-electron interactions between adjacent 2D layers can give rise to a variety of fascinating physical behaviours: the interlayer moiré potential between the graphene and hBN layers leads to mini-Dirac cones and the Hofstadter's butterfly pattern in graphene/hBN heterostructures 5-10 ; electronic couplings between MoS 2 and MoS 2 layers lead to a direct-to indirect-bandgap transition in bilayer MoS 2 (refs 11,12); and Coulomb interactions between MoSe 2 and WSe 2 layers lead to interlayer exciton states in MoSe 2 /WSe 2 heterostructures 13,14 .…”

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confidence: 99%

Interlayer electron–phonon coupling in WSe2/hBN heterostructures

et al. 2016

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Engineering layer-layer interactions provides a powerful way to realize novel and designable quantum phenomena in van der Waals heterostructures 1-16 . Interlayer electron-electron interactions, for example, have enabled fascinating physics that is di cult to achieve in a single material, such as the Hofstadter's butterfly in graphene/boron nitride (hBN) heterostructures [5][6][7][8][9][10] . In addition to electron-electron interactions, interlayer electron-phonon interactions allow for further control of the physical properties of van der Waals heterostructures. Here we report an interlayer electron-phonon interaction in WSe 2 /hBN heterostructures, where optically silent hBN phonons emerge in Raman spectra with strong intensities through resonant coupling to WSe 2 electronic transitions. Excitation spectroscopy reveals the double-resonance nature of such enhancement, and identifies the two resonant states to be the A exciton transition of monolayer WSe 2 and a new hybrid state present only in WSe 2 /hBN heterostructures. The observation of an interlayer electron-phonon interaction could open up new ways to engineer electrons and phonons for device applications.Van der Waals heterostructures of atomically thin twodimensional (2D) crystals are a new class of material in which novel quantum phenomena can emerge from layer-layer interactions [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] . For example, electron-electron interactions between adjacent 2D layers can give rise to a variety of fascinating physical behaviours: the interlayer moiré potential between the graphene and hBN layers leads to mini-Dirac cones and the Hofstadter's butterfly pattern in graphene/hBN heterostructures 5-10 ; electronic couplings between MoS 2 and MoS 2 layers lead to a direct-to indirect-bandgap transition in bilayer MoS 2 (refs 11,12); and Coulomb interactions between MoSe 2 and WSe 2 layers lead to interlayer exciton states in MoSe 2 /WSe 2 heterostructures 13,14 . Similar to electron-electron interactions, electron-phonon interactions also play a key role in a wide range of phenomena in condensed matter physics: the electron-phonon coupling sets the intrinsic limit of electron mobility 17 , dominates the ultrafast carrier dynamics 18 , leads to the Peierls instability 19 , and enables the formation of Cooper pairs 20 . Exploiting interactions between electrons in one layered material and phonons in an adjacent material could enable new ways to control electron-phonon coupling and realize novel quantum behaviour that has not previously been possible. For example, it has been recently shown that electrons in monolayer FeSe can couple strongly with phonons in the adjacent SrTiO 3 substrate, which may play an important role in the anomalously high critical temperature for superconductivity in the system 21,22 . However, the unusual interlayer electron-phonon interactions in the van der Waals heterostructures have been little explored so far, although there have been indications that interlayer interactions between graphene ...

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Strain solitons and topological defects in bilayer graphene

Cited by 478 publications

References 35 publications

Critical behavior of four-terminal conductance of bilayer graphene domain walls

Critical behavior of four-terminal conductance of bilayer graphene domain walls

Structure of graphene and its disorders: a review

Interlayer electron–phonon coupling in WSe2/hBN heterostructures

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