Pressure-induced gap modulation and topological transitions in twisted bilayer and twisted double bilayer graphene

Lin, Xianqing; Zhu, Haotian; Ni, Jun

doi:10.1103/physrevb.101.155405

Cited by 34 publications

(33 citation statements)

References 50 publications

(78 reference statements)

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“…( 3). It has been proven that the vertical compression has a negligible influence on the intralayer interactions, whereas significantly modify the interlayer hoppings [15,18]. Therefore, we only modify the interlayer hopping term V ppσ as [18]:…”

Section: Methodsmentioning

confidence: 99%

“…Interestingly, for twisted bilayer graphene with a moderate twist angle that shows relatively weak correlation under ambient pressure, an appropriate hydrostatic pressure induces robust insulating phases and superconductivity with higher T c than that in zero-pressure magic-angle case [13,14]. Theoretically, vertical pressure can be used to achieve the ultraflat bands in twisted bilayer graphene with arbitrary twist angle [15][16][17][18][19]. Consequently, when studying the strong correlation, we can reduce the impact of structural inhomogeneity by using a moiré pattern with a short wavelength.…”

Section: Introductionmentioning

confidence: 99%

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Magic angle and plasmon mode engineering in twisted trilayer graphene with pressure

Wu,

Kuang,

Zhan

et al. 2021

Preprint

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Recent experimental and theoretical investigations demonstrate that twisted trilayer graphene (tTLG) is a highly tunable platform to study the correlated insulating states, ferromagnetism, and superconducting properties. Here we explore the possibility of tuning electronic correlations of the tTLG via a vertical pressure. A full tight-binding model is used to accurately describe the pressuredependent interlayer interactions. Our results show that pressure can push a relatively larger twist angle (for instance, 1.89 • ) tTLG to reach the flat-band regime. Next, we obtain the relationship between the pressure-induced magic angle value and the critical pressure. These critical pressure values are almost half of that needed in the case of twisted bilayer graphene. Then, plasmonic properties are further investigated in the flat band tTLG with both zero-pressure magic angle and pressure-induced magic angle. Two plasmonic modes are detected in these two kinds of flat band samples. By comparison, one is a high energy damping-free plasmon mode that shows similar behavior, and the other is a low energy plasmon mode (flat-band plasmon) that shows obvious differences. The flat-band plasmon is contributed by both interband and intraband transitions of flat bands, and its divergence is due to the various shape of the flat bands in tTLG with zeropressure and pressure-induced magic angles. This may provide an efficient way of tuning between regimes with strong and weak electronic interactions in one sample and overcoming the technical requirement of precise control of the twist angle in the study of correlated physics.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magic angle and plasmon mode engineering in twisted trilayer graphene with pressure

Wu,

Kuang,

Zhan

et al. 2021

Preprint

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“… 38 , 39 In TBG the pressure changes the width of the low-energy bands 40 , 41 and it can drive the system through a superconducting phase transition. 5 On the basis of theoretical calculations on TDBG, the pressure is expected to have similarly drastic effects on the electronic properties; 20 , 32 thus it gives an ideal control knob for in situ band-structure and topology engineering of TDBG.…”

Section: Introductionmentioning

confidence: 99%

Tailoring the Band Structure of Twisted Double Bilayer Graphene with Pressure

et al. 2021

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Twisted two-dimensional structures open new possibilities in band structure engineering. At magic twist angles, flat bands emerge, which gave a new drive to the field of strongly correlated physics. In twisted double bilayer graphene dual gating allows changing of the Fermi level and hence the electron density and also allows tuning of the interlayer potential, giving further control over band gaps. Here, we demonstrate that by application of hydrostatic pressure, an additional control of the band structure becomes possible due to the change of tunnel couplings between the layers. We find that the flat bands and the gaps separating them can be drastically changed by pressures up to 2 GPa, in good agreement with our theoretical simulations. Furthermore, our measurements suggest that in finite magnetic field due to pressure a topologically nontrivial band gap opens at the charge neutrality point at zero displacement field.

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“…1), the interlayer coupling can be tuned, which strongly influences the electronic structure and thereby the physical properties of these heterostructures. The potential interest of tuning this parameter is demonstrated in various theoretical works [13,[36][37][38][39][40][41][42][43], however, several technological challenges are to be solved for the realization of transport measurements on nanodevices under pressure.…”

Section: Introductionmentioning

confidence: 99%

New method of transport measurements on van der Waals heterostructures under pressure

Fülöp

Márffy

Tóvári

et al. 2021

Journal of Applied Physics

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The interlayer coupling, which has a strong influence on the properties of van der Waals heterostructures, strongly depends on the interlayer distance. Although considerable theoretical interest has been demonstrated, experiments exploiting a variable interlayer coupling on nanocircuits are scarce due to the experimental difficulties. Here, we demonstrate a novel method to tune the interlayer coupling using hydrostatic pressure by incorporating van der Waals heterostructure based nanocircuits in piston-cylinder hydrostatic pressure cells with a dedicated sample holder design. This technique opens the way to conduct transport measurements on nanodevices under pressure using up to 12 contacts without constraints on the sample at fabrication level. Using transport measurements, we demonstrate that hexagonal boron nitride capping layer provides a good protection of van der Waals heterostructures from the influence of the pressure medium, and we show experimental evidence of the influence of pressure on the interlayer coupling using weak localization measurements on a TMDC/graphene heterostructure.

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Pressure-induced gap modulation and topological transitions in twisted bilayer and twisted double bilayer graphene

Cited by 34 publications

References 50 publications

Magic angle and plasmon mode engineering in twisted trilayer graphene with pressure

Magic angle and plasmon mode engineering in twisted trilayer graphene with pressure

Tailoring the Band Structure of Twisted Double Bilayer Graphene with Pressure

New method of transport measurements on van der Waals heterostructures under pressure

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