Ultrafast Dynamics of Massive Dirac Fermions in 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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Recovery of massless Dirac fermions at charge neutrality in strongly interacting twisted bilayer graphene with disorder

Physical Review B ◽

10.1103/physrevb.103.125138 ◽

2021 ◽

Vol 103 (12) ◽

Author(s):

Alex Thomson ◽

Jason Alicea

Keyword(s):

Bilayer Graphene ◽

Dirac Fermions ◽

Charge Neutrality ◽

Strongly Interacting ◽

Twisted Bilayer Graphene

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New Dirac Fermions in Periodically Modulated Bilayer Graphene

Nano Letters ◽

10.1021/nl200055s ◽

2011 ◽

Vol 11 (7) ◽

pp. 2596-2600 ◽

Cited By ~ 18

Author(s):

Liang Z. Tan ◽

Cheol-Hwan Park ◽

Steven G. Louie

Keyword(s):

Bilayer Graphene ◽

Dirac Fermions

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ELECTRON OPTICS WITH DIRAC FERMIONS: ELECTRON TRANSPORT IN MONOLAYER AND BILAYER GRAPHENE THROUGH MAGNETIC BARRIER AND THEIR SUPERLATTICES

International Journal of Modern Physics B ◽

10.1142/s0217979213410038 ◽

2013 ◽

Vol 27 (10) ◽

pp. 1341003 ◽

Cited By ~ 25

Author(s):

NEETU AGRAWAL (GARG) ◽

SANKALPA GHOSH ◽

MANISH SHARMA

Keyword(s):

Magnetic Field ◽

Electron Transport ◽

Negative Refraction ◽

Ballistic Transport ◽

Bilayer Graphene ◽

Inhomogeneous Magnetic Field ◽

Electromagnetic Potential ◽

Dirac Fermions ◽

Experimental Realization ◽

Magnetic Barrier

In this review article we discuss the recent progress in studying ballistic transport for charge carriers in graphene through highly inhomogeneous magnetic field known as magnetic barrier in combination with gate voltage induced electrostatic potential. Starting with cases for a single or double magnetic barrier we also review the progress in understanding electron transport through the superlattices created out of such electromagnetic potential barriers and discuss the possibility of experimental realization of such systems. The emphasis is particularly on the analogy of such transport with propagation of light wave through medium with alternating dielectric constant. In that direction we discuss electron analogue of optical phenomena like Fabry–Perot resonances, negative refraction, Goos–Hänchen effect, beam collimation in such systems and explain how such analogy is going to be useful for device generation. The resulting modification of band structure of Dirac fermions, the emergence of additional Dirac points was also discussed accompanied by brief section on the interconvertibility of electric and magnetic field for relativistic Dirac fermions. We also discuss the effect of such electromagnetic potential barrier on bilayer graphene (BLG) in a similar framework.

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Ultrafast reorientation of the Néel vector in antiferromagnetic Dirac semimetals

npj Computational Materials ◽

10.1038/s41524-021-00641-2 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Atsushi Ono ◽

Sumio Ishihara

Keyword(s):

Real Time ◽

Ultrafast Dynamics ◽

Dirac Fermions ◽

Spin Orbit ◽

Fundamental Physics ◽

Time Dynamics ◽

Time Symmetry ◽

Optical Effects ◽

Dirac Semimetals ◽

A Current

AbstractAntiferromagnets exhibit distinctive characteristics such as ultrafast dynamics and robustness against perturbative fields, thereby attracting considerable interest in fundamental physics and technological applications. Recently, it was revealed that the Néel vector can be switched by a current-induced staggered (Néel) spin-orbit torque in antiferromagnets with the parity-time symmetry, and furthermore, a nonsymmorphic symmetry enables the control of Dirac fermions. However, the real-time dynamics of the magnetic and electronic structures remain largely unexplored. Here, we propose a theory of the ultrafast dynamics in antiferromagnetic Dirac semimetals and show that the Néel vector is rotated in the picosecond timescale by the terahertz-pulse-induced Néel spin-orbit torque and other torques originating from magnetic anisotropies. This reorientation accompanies the modulation of the mass of Dirac fermions and can be observed in real time by the magneto-optical effects. Our results provide a theoretical basis for emerging ultrafast antiferromagnetic spintronics combined with the topological aspects of materials.

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