Combined Minivalley and Layer Control in Twisted Double Bilayer Graphene

Vries, Folkert K. de; Zhu, Jihang; Portolés, Elías; Zheng, Giulia; Masseroni, Michele; Kurzmann, Annika; Taniguchi, Takashi; Watanabe, Kenji; MacDonald, Allan H.; Ensslin, Klaus; Ihn, Thomas; Rickhaus, Peter

doi:10.1103/physrevlett.125.176801

Cited by 20 publications

(21 citation statements)

References 25 publications

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“…In such weakly dispersing bands, the kinetic energy is reduced, allowing the electron–electron interactions to favor correlated states. Evidence of correlated behavior has been observed, for example, as the appearance of resistive states at the fractional filling of bands in tBLG with an interlayer twist of ∼1.1°, , ABC-trilayer graphene/hBN moiré, , twisted bibilayer, − monolayer–bilayer graphene, − and twisted WSe 2 . One recently observed consequence of these correlations is ferromagnetism in tBLG in a narrow range of carrier densities around 3/4 filling of the flat conduction band, , where full filling corresponds to four electrons per moiré unit cell accounting for spin and valley degeneracies .…”

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confidence: 98%

Evidence of Orbital Ferromagnetism in Twisted Bilayer Graphene Aligned to Hexagonal Boron Nitride

et al. 2021

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We have previously reported ferromagnetism evinced by a large hysteretic anomalous Hall effect in twisted bilayer graphene (tBLG). Subsequent measurements of a quantized Hall resistance and small longitudinal resistance confirmed that this magnetic state is a Chern insulator. Here, we report that when tilting the sample in an external magnetic field, the ferromagnetism is highly anisotropic. Because spin−orbit coupling is weak in graphene, such anisotropy is unlikely to come from spin but rather favors theories in which the ferromagnetism is orbital. We know of no other case in which ferromagnetism has a purely orbital origin. For an applied in-plane field larger than 5 T, the out-of-plane magnetization is destroyed, suggesting a transition to a new phase.

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confidence: 98%

Evidence of Orbital Ferromagnetism in Twisted Bilayer Graphene Aligned to Hexagonal Boron Nitride

et al. 2021

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“…While this phenomenon has been seen in experiments on tBG [62], experimental investigation of the resistivity anisotropy in tDBG remain to be performed, to the best of our knowledge. As opposed to STM setups, transport measurements [99][100][101] can usually be performed in the presence of top and back gates, which allow one to control both the displacement field and the electronic density independently [10][11][12][13]. This provides more flexibility in stabilizing and tuning nematic order.…”

Section: Signatures In Transport Measurementsmentioning

confidence: 99%

“…Focusing on the case of moiré nematicity, as supported by the STM data, we microscopically compute the coupling constant for tDBG and show that the director can rotate over a substantial range of about 10 • for experimentally accessible values of the displacement field. We further discuss the predicted experimental manifestations of the nematic director's rotation in STM [63,88,89] and transport [99][100][101] measurements, disentangling it from effects caused by the changes in the band structure prompted by a changing displacement field. These results demonstrate the unique capabilities of moiré systems for electrostatic control of electronic nematicity.…”

Section: Introductionmentioning

confidence: 98%

Electric-field-tunable electronic nematic order in twisted double-bilayer graphene

Samajdar,

Scheurer,

Turkel

et al. 2021

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Graphene-based moiré systems have attracted considerable interest in recent years as they display a remarkable variety of correlated phenomena. Besides insulating and superconducting phases in the vicinity of integer fillings of the moiré unit cell, there is growing evidence for electronic nematic order both in twisted bilayer graphene and twisted double-bilayer graphene (tDBG), as signaled by the spontaneous breaking of the threefold rotational symmetry of the moiré superlattices. Here, we combine symmetry-based analysis with a microscopic continuum model to investigate the structure of the nematic phase of tDBG and its experimental manifestations. First, we perform a detailed comparison between the theoretically calculated local density of states and recent scanning tunneling microscopy data [arXiv:2009.11645] to resolve the internal structure of the nematic order parameter in terms of the layer, sublattice, spin, and valley degrees of freedom. We find strong evidence that the dominant contribution to the nematic order parameter comes from states at the moiré scale rather than at the microscopic scale of the individual graphene layers, which demonstrates the key role played by the moiré degrees of freedom and confirms the correlated nature of the nematic phase in tDBG. Secondly, our analysis reveals an unprecedented tunability of the orientation of the nematic director in tDBG by an externally applied electric field, allowing the director to rotate away from high-symmetry crystalline directions. We compute the expected fingerprints of this rotation in both STM and transport experiments, providing feasible ways to probe it. Rooted in the strong sensitivity of the flat bands of tDBG to the displacement field, this effect opens an interesting route to the electrostatic control of electronic nematicity in moiré systems.

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“…A notable feature of SA-TBG is that, by employing a single-or dual-gated device architecture, one can selectively populate the minivalleys by appropriately tuning the top and bottom gate voltages 16,17 (V tg and V bg respectively). This combination defines the relative displacement field between graphene layers, D = (C bg V bg − C tg V tg )/2, and total carrier density, n = (C bg V bg + C tg V tg )/e.…”

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“…Intuitively, as the minivalleys are predominantly formed from the energy bands of different graphene sheets, an applied electric field dopes the lay- ers unequally resulting in such an imbalance. [16][17][18] In the presence of a perpendicular magnetic field, B, the gateinduced imbalance also determines the relative offset of the Landau levels (LLs) hosted by each minivalley, 19,20 a property that brings us a reliable method to explore the effects of interminivalley electron scattering in SA-TBG, as we now proceed to show.…”

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Strong interminivalley scattering in twisted bilayer graphene revealed by high-temperature magnetooscillations

Phinney,

Bandurin,

Collignon

et al. 2021

Preprint

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Twisted bilayer graphene (TBG) provides an example of a system in which the interplay of interlayer interactions and superlattice structure impacts electron transport in a variety of non-trivial ways and gives rise to a plethora of interesting effects. Understanding the mechanisms of electron scattering in TBG has, however, proven challenging, raising many questions about the origins of resistivity in this system. Here we show that TBG exhibits high-temperature magnetooscillations originating from the scattering of charge carriers between TBG minivalleys. The amplitude of these oscillations reveals that interminivalley scattering is strong, and its characteristic time scale is comparable to that of its intraminivalley counterpart. Furthermore, by exploring the temperature dependence of these oscillations, we estimate the electron-electron collision rate in TBG and find that it exceeds that of monolayer graphene. Our study demonstrates the consequences of the relatively small size of the superlattice Brillouin zone and Fermi velocity reduction on lateral transport in TBG.

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Combined Minivalley and Layer Control in Twisted Double Bilayer Graphene

Cited by 20 publications

References 25 publications

Evidence of Orbital Ferromagnetism in Twisted Bilayer Graphene Aligned to Hexagonal Boron Nitride

Evidence of Orbital Ferromagnetism in Twisted Bilayer Graphene Aligned to Hexagonal Boron Nitride

Electric-field-tunable electronic nematic order in twisted double-bilayer graphene

Strong interminivalley scattering in twisted bilayer graphene revealed by high-temperature magnetooscillations

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