Heterostrain Determines Flat Bands in Magic-Angle Twisted Graphene Layers

Recent experiments on magic-angle twisted bi-layer graphene have attracted an intensive attention due to exotic properties such as unconventional superconductivity and correlated insulation. These phenomena were often found at a...

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Theory of correlated insulating behaviour and spin-triplet superconductivity in twisted double bilayer graphene

Nature Communications ◽

10.1038/s41467-019-12981-1 ◽

2019 ◽

Vol 10 (1) ◽

Cited By ~ 41

Author(s):

Jong Yeon Lee ◽

Eslam Khalaf ◽

Shang Liu ◽

Xiaomeng Liu ◽

Zeyu Hao ◽

...

Keyword(s):

Displacement Field ◽

Twist Angle ◽

Vertical Displacement ◽

Bilayer Graphene ◽

Magic Angle ◽

Hartree Fock ◽

Flat Bands ◽

Half Filling ◽

Spin Triplet ◽

Experimental Findings

AbstractTwo graphene monolayers twisted by a small magic angle exhibit nearly flat bands, leading to correlated electronic states. Here we study a related but different system with reduced symmetry - twisted double bilayer graphene (TDBG), consisting of two Bernal stacked bilayer graphenes, twisted with respect to one another. Unlike the monolayer case, we show that isolated flat bands only appear on application of a vertical displacement field. We construct a phase diagram as a function of twist angle and displacement field, incorporating interactions via a Hartree-Fock approximation. At half-filling, ferromagnetic insulators are stabilized with valley Chern number $${C}_{{\rm{v}}}=\pm 2$$Cv=±2. Upon doping, ferromagnetic fluctuations are argued to lead to spin-triplet superconductivity from pairing between opposite valleys. We highlight a novel orbital effect arising from in-plane fields plays an important role in interpreting experiments. Combined with recent experimental findings, our results establish TDBG as a tunable platform to realize rare phases in conventional solids.

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Moire Is Different

Applied Physics Research ◽

10.5539/apr.v13n1p50 ◽

2021 ◽

Vol 13 (1) ◽

pp. 50

Author(s):

Wenyuan Shi

Keyword(s):

Electronic Structures ◽

Tight Binding ◽

Physical Property ◽

Large Change ◽

Bilayer Graphene ◽

Dirac Fermion ◽

Dirac Fermions ◽

Graphene Layers ◽

Flat Bands ◽

Twisted Bilayer Graphene

Graphene, as the thinnest material ever found, exhibits unconventionally relativistic behaviour of Dirac fermions. However, unusual phenomena (such as superconductivity) arise when stacking two graphene layers and twisting the bilayer graphene. The relativistic Dirac fermion in graphene has been widely studied and understood, but the large change observed in twisted bilayer graphene (TBG) is intriguing and still unclear because only van der Waals force (vdW) interlayer interaction is added from graphene to TBG and such a very weak interaction is expected to play a negligible role. To understand such dramatic variation, we studied the electronic structures of monolayer, bilayer and twisted bilayer graphene. Twisted bilayer graphene creates different moiré patterns when turned at different angles. We proposed tight-binding and effective continuum models and thereby drafted a computer code to calculate their electronic structures. Our calculated results show that the electronic structure of twisted bilayer graphene changes significantly even by a tiny twist. When bilayer graphene is twisted at special “magic angles”, flat bands appear. We examined how these flat bands are created, their properties and the relevance to some unconventional physical property such as superconductivity. We conclude that in the nanoscopic scale, similar looking atomic structures can create vastly different electronic structures. Like how P. W. Anderson stated that similar looking fields in science can have differences in his article “More is Different”, similar moiré patterns in twisted bilayer graphene can produce different electronic structures.

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Electric field–tunable superconductivity in alternating-twist magic-angle trilayer graphene

Science ◽

10.1126/science.abg0399 ◽

2021 ◽

Vol 371 (6534) ◽

pp. 1133-1138 ◽

Cited By ~ 3

Author(s):

Zeyu Hao ◽

A. M. Zimmerman ◽

Patrick Ledwith ◽

Eslam Khalaf ◽

Danial Haie Najafabadi ◽

...

Keyword(s):

Displacement Field ◽

Weak Coupling ◽

Twist Angle ◽

Magic Angle ◽

Van Hove Singularity ◽

Displacement Fields ◽

Graphene Layers ◽

Vdw Heterostructure ◽

Quantum Phenomena ◽

Trilayer Graphene

Engineering moiré superlattices by twisting layers in van der Waals (vdW) heterostructures has uncovered a wide array of quantum phenomena. We constructed a vdW heterostructure that consists of three graphene layers stacked with alternating twist angles ±θ. At the average twist angle θ ~ 1.56°, a theoretically predicted “magic angle” for the formation of flat electron bands, we observed displacement field–tunable superconductivity with a maximum critical temperature of 2.1 kelvin. By tuning the doping level and displacement field, we found that superconducting regimes occur in conjunction with flavor polarization of moiré bands and are bounded by a van Hove singularity (vHS) at high displacement fields. Our findings display inconsistencies with a weak coupling description, suggesting that the observed moiré superconductivity has an unconventional nature.

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