Gaps induced by inversion symmetry breaking and second-generation Dirac cones in graphene/hexagonal boron nitride

Wang, Eryin; Lu, Xiaobo; Ding, Shijie; Yao, Wei; Yan, Mingzhe; Wan, Guoliang; Deng, Ke; Wang, Shuopei; Chen, Guorui; Ma, Liguo; Jung, Jeil; Fedorov, A. V.; Zhang, Yuanbo; Zhang, Guangyu; Zhou, Shuyun

doi:10.1038/nphys3856

Cited by 195 publications

(169 citation statements)

References 30 publications

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“…The clear electronic states and lack of band hybridization reveal a weak interlayer interaction between the two materials. Similar to work 22 on graphene/h-BN, we expect these data to represent the intrinsic electronic structure of single-layer WS 2 with negligible substrate influence.…”

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confidence: 88%

“…This should enable direct investigation of the intrinsic electronic structure and many-body effects of the adjacent TMD. Hexagonal BN is often used as a substrate for graphene heterostructures 8,20 with high device performance 21 and new exotic electronic states such as quantized Dirac cones 22 . Unfortunately, the lateral size of mechanically assembled heterostructures is usually of the order of 10 μ m, much smaller than the beam spot of typical ARPES setups (≳ 100 μ m).…”

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confidence: 99%

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Giant spin-splitting and gap renormalization driven by trions in single-layer WS2/h-BN heterostructures

et al. 2018

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In two-dimensional (2D) semiconducting transition metal dichalcogenides (TMDs), new electronic phenomena such as tunable bandgaps 1-3 and strongly bound excitons and trions emerge from strong many-body effects [4][5][6] , beyond the spin and valley degrees of freedom induced by spin-orbit coupling and by lattice symmetry 7 . Combining single-layer TMDs with other 2D materials in van der Waals heterostructures offers an intriguing means of controlling the electronic properties through these many-body effects, by means of engineered interlayer interactions [8][9][10] . Here, we use micro-focused angle-resolved photoemission spectroscopy (microARPES) and in situ surface doping to manipulate the electronic structure of single-layer WS 2 on hexagonal boron nitride (WS 2 /h-BN). Upon electron doping, we observe an unexpected giant renormalization of the spin-orbit splitting of the single-layer WS 2 valence band, from 430 meV to 660 meV, together with a bandgap reduction of at least 325 meV, attributed to the formation of trionic quasiparticles. These findings suggest that the electronic, spintronic and excitonic properties are widely tunable in 2D TMD/h-BN heterostructures, as these are intimately linked to the quasiparticle dynamics of the materials [11][12][13] . Coulomb interactions in 2D materials are several times stronger than in their 3D counterparts. In 2D TMDs, this is most directly evidenced by the presence of excitons with binding energies an order of magnitude higher than in the bulk 4 . Although the excitons in these 2D materials have been widely studied by optical techniques 13 , the impact of strong electron-electron interactions on the quasiparticle band structure remains unclear. Theory predicts that many-body effects will influence the spin-orbit splitting around the valenceband maximum (VBM) and conduction-band minimum (CBM) 14 . Although these should be observable by ARPES, a direct probe of many-body effects 15 , measurements so far have mainly focused on the layer-dependence of the single-particle spectrum and the direct bandgap transition in 2D TMD systems, including epitaxial single- . Unfortunately, the lateral size of mechanically assembled heterostructures is usually of the order of 10 μ m, much smaller than the beam spot of typical ARPES setups (≳ 100 μ m). Furthermore, sample charging on insulating bulk h-BN substrates would complicate ARPES experiments.We overcome these challenges as follows. We realize a high-quality 2D semiconductor-insulator interface by mechanically transferring a relatively large (~100 μ m) single-layer WS 2 crystal onto a thin flake of h-BN that has itself been transferred onto a degenerately doped TiO 2 substrate, as depicted in Fig. 1a. Sample charging is avoided because there is electrical contact from the continuous single-layer WS 2 flake to both the h-BN and the conductive TiO 2 . Figure 1b is an optical microscope image of the sample, including a flake of h-BN, approximately 100 μ m wide, surrounded by several transferred flakes of single-layer WS 2 on the Ti...

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confidence: 88%

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Giant spin-splitting and gap renormalization driven by trions in single-layer WS2/h-BN heterostructures

et al. 2018

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“…Collectively, these results imply that G/BN should not have a band gap. However, the experimental observation of sizeable band gaps [19,[21][22][23] has led to theories where the nonzero average mass generation introduced by the partial commensuration of the G/BN layers [24,25], and electron-electron interaction effects [26,27] play a relevant role. Other manifestations of the moiré pattern effects in G/BN include the Hofstadter butterfly [28,29], topological valley current [30,31], tunable Van Hove singularities in the low-energy regime [32], and the emergence of secondary Dirac cones (sDC) at the edge of the moiré Brilluoin Zone (mBZ) [23,29].…”

Section: Introductionmentioning

confidence: 99%

Moiré band model and band gaps of graphene on hexagonal boron nitride

et al. 2017

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Nearly aligned graphene on hexagonal boron nitride (G/BN) can be accurately modeled by a Dirac Hamiltonian perturbed by smoothly varying moiré pattern pseudospin fields. Here, we present the moiré-band model of G/BN for arbitrary small twist angles under a framework that combines symmetry considerations with input from ab-initio calculations. Our analysis of the band gaps at the primary and secondary Dirac points highlights the role of inversion symmetry breaking contributions of the moiré patterns, leading to primary Dirac point gaps when the moiré strains give rise to a finite average mass, and to secondary gaps when the moiré pseudospin components are mixed appropriately. The pseudomagnetic strain fields which can reach values of up to ∼ 40 Tesla near symmetry points in the moiré cell stem almost entirely from virtual hopping and dominate over the contributions arising from bond length distortions due to the moiré strains.

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“…The sublattice imbalance could arise for a graphene monolayer deposited on boron nitride in a commensurate fashion [11,60]. The Rashba and exchange fields naturally arise for a graphene monolayer deposited over a ferromagnetic insulator, such as YIG [61,62], EuO [63], or CrI 3 [64,65].…”

Section: B Two-dimensional Chern Insulatormentioning

confidence: 99%

“…This situation might lead to protected modes between different regions of the system, dramatically changing the low-energy properties of the whole material. This is the natural scenario in van der Waals heterostructures, where Moire patterns [9][10][11] could coexist with any topological state [12,13]. A more controlled situation is the proposals for topological superconductivity involving nanowires, where the topological state is controlled locally by electric gates [14,15].…”

Section: Introductionmentioning

confidence: 99%

Real-space mapping of topological invariants using artificial neural networks

et al. 2018

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Topological invariants allow one to characterize Hamiltonians, predicting the existence of topologically protected in-gap modes. Those invariants can be computed by tracing the evolution of the occupied wave functions under twisted boundary conditions. However, those procedures do not allow one to calculate a topological invariant by evaluating the system locally, and thus require information about the wave functions in the whole system. Here we show that artificial neural networks can be trained to identify the topological order by evaluating a local projection of the density matrix. We demonstrate this for two different models, a one-dimensional topological superconductor and a two-dimensional quantum anomalous Hall state, both with spatially modulated parameters. Our neural network correctly identifies the different topological domains in real space, predicting the location of in-gap states. By combining a neural network with a calculation of the electronic states that uses the kernel polynomial method, we show that the local evaluation of the invariant can be carried out by evaluating a local quantity, in particular for systems without translational symmetry consisting of tens of thousands of atoms. Our results show that supervised learning is an efficient methodology to characterize the local topology of a system.

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Gaps induced by inversion symmetry breaking and second-generation Dirac cones in graphene/hexagonal boron nitride

Cited by 195 publications

References 30 publications

Giant spin-splitting and gap renormalization driven by trions in single-layer WS2/h-BN heterostructures

Giant spin-splitting and gap renormalization driven by trions in single-layer WS2/h-BN heterostructures

Moiré band model and band gaps of graphene on hexagonal boron nitride

Real-space mapping of topological invariants using artificial neural networks

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