Light-induced anomalous Hall effect in massless Dirac fermion systems and topological insulators with dissipation

Sato, Shunsuke A.; Tang, Peizhe; Sentef, Michael A.; Giovannini, Umberto De; Hübener, Hannes; Rubio, Ángel

doi:10.1088/1367-2630/ab3acf

Cited by 50 publications

(51 citation statements)

References 54 publications

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“…Therefore, in experiments a delicate balance needs to be struck between the time necessary to establish the Floquet phase and the maximum time the material can sustain the radiation. In this context it is important to note that dissipative systems, where the energy can redistributed to a heat bath, can help to stabilize the Floquet phase [13,76,79]. In the next section, instead, we will explore the possibility to achieve establishing Floquet dressed states without the continued transfer of energy into the system.…”

Section: Experimental Observation Of Floquet Topological Phasesmentioning

confidence: 99%

Floquet analysis of excitations in materials

Giovannini

Hübener

2019

J. Phys. Mater.

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Controlled excitation of materials can transiently induce changed or novel properties with many fundamental and technological implications. Especially, the concept of Floquet engineering and the manipulation of the electronic structure via dressing with external lasers have attracted some recent interest. Here we review the progress made in defining Floquet material properties and give a special focus on their signatures in experimental observables as well as considering recent experiments realizing Floquet phases in solid state materials. We discuss how a wide range of experiments with non-equilibrium electronic structure can be viewed by employing Floquet theory as an analysis tool providing a different view of excitations in solids.

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Section: Experimental Observation Of Floquet Topological Phasesmentioning

confidence: 99%

Floquet analysis of excitations in materials

Giovannini

Hübener

2019

J. Phys. Mater.

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“…This opens up the realistic prospect of a finite-field topological transition in solid-state experiments. A future task is to study theoretically the ultrafast light-induced transport properties of TBG for realistic driving pulses especially in the mid-infrared and for smaller twisting angles near 1.7 • , including the effects of excitation and dissipation in real time, which is a much more formidable task for TBG compared to a single branch of Dirac fermions [32,33]. In particular, real-time signatures of tunneling into topological edge states might provide additional insights [70].…”

Section: Discussionmentioning

confidence: 99%

“…In solids, key progress has been made for instance in observing Floquet-Bloch states in time-resolved photoemission spectroscopy [30] or with the recently demonstrated light-induced anomalous Hall effect in graphene under circularly polarized laser driving [31][32][33]. However, the concept of Floquet engineering of a material's topological properties [34][35][36][37][38][39][40][41][42][43] has been limited to very few material systems so far.…”

Section: Introductionmentioning

confidence: 99%

Topological Floquet engineering of twisted bilayer graphene

Topp

Jotzu

McIver

et al. 2019

Phys. Rev. Research

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We investigate the topological properties of Floquet-engineered twisted bilayer graphene above the magic angle driven by circularly polarized laser pulses. Employing a full Moiré-unit-cell tightbinding Hamiltonian based on first-principles electronic structure we show that the band topology in the bilayer, at twisting angles above 1.05 • , essentially corresponds to the one of single-layer graphene. However, the ability to open topologically trivial gaps in this system by a bias voltage between the layers enables the full topological phase diagram to be explored, which is not possible in singlelayer graphene. Circularly polarized light induces a transition to a topologically nontrivial Floquet band structure with the Berry curvature of a Chern insulator. Importantly, the twisting allows for tuning electronic energy scales, which implies that the electronic bandwidth can be tailored to match realistic driving frequencies in the ultraviolet or mid-infrared photon-energy regimes. This implies that Moiré superlattices are an ideal playground for combining twistronics, Floquet engineering, and strongly interacting regimes out of thermal equilibrium.

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“…In the high-frequency regime, the laser drive is not in resonance with transitions and the heating can take exponentially long times to set in [33,93]. When the drive frequency is in resonance, one needs to take into account relaxation processes to fully describe the system, such as coupling with phonons which can act as a reservoir [94][95][96]. Interestingly, a recent study on dissipative Floquet systems has shown that for resonant and strong-enough drives, Floquet states can develop if the decoherence time is shorter than the period of the drive [97].…”

Section: B Intermediate Frequencymentioning

confidence: 99%

Floquet engineering of twisted double bilayer graphene

Rodriguez-Vega

Vogl

Fiete

2020

Phys. Rev. Research

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Motivated by the recent experimental realization of twisted double bilayer graphene (TDBG) samples, we study, both analytically and numerically, the effects of circularly polarized light propagating in free space and confined in a waveguide on the band structure and topological properties of these systems. These two complementary Floquet protocols allow us to selectively tune different parameters of the system by varying the intensity and light frequency. For the drive protocol in free space, in the high-frequency regime, we find that in TDBG with AB/BA stacking, we can selectively close the zone-center quasienergy gaps around one valley while increasing the gaps near the opposite valley by tuning the parameters of the drive. In TDBG with AB/AB stacking, a similar effect can be obtained upon the application of a perpendicular static electric field. Furthermore, we study the topological properties of the driven system in different settings, provide accurate effective Floquet Hamiltonians, and show that relatively strong drives can generate flat bands. On the other hand, longitudinal light confined in a waveguide couples to the components of the interlayer hopping that are perpendicular to the TDBG sheet, allowing for selective engineering of the bandwidth of Floquet zone-center quasienergy bands without breaking the symmetries of the static system.

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Light-induced anomalous Hall effect in massless Dirac fermion systems and topological insulators with dissipation

Cited by 50 publications

References 54 publications

Floquet analysis of excitations in materials

Floquet analysis of excitations in materials

Topological Floquet engineering of twisted bilayer graphene

Floquet engineering of twisted double bilayer graphene

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