Light-matter coupling and quantum geometry in moiré materials

Topp, G. E.; Eckhardt, C. J.; Kennes, D. M.; Sentef, M. A.; Törmä, P.

doi:10.48550/arxiv.2103.04967

Cited by 3 publications

(3 citation statements)

References 128 publications

(144 reference statements)

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“…The cavity confinement leads to similar effects, such as induced hopping as in the ultrastrong coupling regime, while the strength of effects is relatively small. The effects can be enhanced for, e.g., subwavelength cavities and metamaterials or heterostructures 83,84 . Coldatom systems represent another family of possible implementations 17,18 , which can also be studied using the same formulation discussed in Sec.…”

Section: Discussionmentioning

confidence: 99%

Effective theory of lattice electrons strongly coupled to quantum electromagnetic fields

Li,

Schamriß,

Eckstein

2021

Preprint

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Recent experiments have revealed the tantalizing possibility of fabricating lattice electronic systems strongly coupled to quantum fluctuations of electromagnetic fields, e.g., by means of geometry confinement from a cavity or artificial gauge fields in quantum simulators. In this work, we develop a high-frequency expansion to construct the effective models for lattice electrons strongly coupled to a continuum of off-resonant photon modes with arbitrary dispersion. The theory is nonperturbative in the light-matter coupling strength, and is therefore particularly suitable for the ultrastrong light-matter coupling regime. Using the effective models, we demonstrate how the dispersion and topology of the electronic energy bands can be tuned by the cavity. In particular, quasi-onedimensional physics can emerge in a two-dimensional square lattice due to a spatially anisotropic band renormalization, and a topologically nontrivial anomalous quantum Hall state can be induced in a honeycomb lattice when the cavity setup breaks time-reversal symmetry. We also demonstrate that the photon-mediated interaction induces an unconventional superconducting paired phase distinct from the pair-density-wave state discussed in models with truncated light-matter coupling. Finally, we study a realistic setup of a Fabry-Pérot cavity. Our work provides a systematic framework to explore the emergent phenomena due to strong light-matter coupling and points out new directions of engineering orders and topological states in solids.

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Section: Discussionmentioning

confidence: 99%

Effective theory of lattice electrons strongly coupled to quantum electromagnetic fields

Li,

Schamriß,

Eckstein

2021

Preprint

View full text Add to dashboard Cite

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“…8. Another motivation is that although Floquet engineering of TBG has been systematically studied [18,19,69,70], most of them have focued on light frequency driven regime or sliding TBG as a 2d Thouless pump [20,71]. The non-adiabatic structurally rotating driving TBG is still in need of investigation [72].…”

Section: Theory For Rotating Bilayer Graphene (Rbg)mentioning

confidence: 99%

An effective curved space-time geometric theory of generic twist angle graphene with application to a rotating bilayer configuration

Ma,

Datta,

Yao

2021

Preprint

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We propose a new kind of geometric effective theory based on curved space-time single valley Dirac theory with spin connection for twisted bilayer graphene under generic twist angle. This model can reproduce the nearly flat bands with particle-hole symmetry around the first magic angle. The band width is near the former results given by Bistritzer-MacDonald model or density matrix renormalization group. Even more, such geometric formalism allows one to predict the properties of rotating bilayer graphene which cannot be accessed by former theories. As an example, we investigate the Bott index of a rotating bilayer graphene. We relate this to the twodimensional Thouless pump with quantized charge pumping during one driving period which could be verified by transport measurement.

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“…Recent advances have revealed the central role played by the Fubini-Study metric [1] in various fields of quantum sciences [2], with a direct impact on quantum technologies [3,4] and many-body quantum physics [2,5]. In condensed matter, the quantum metric generally defines a notion of distance over momentum space, and it was shown to provide essential geometric contributions to various phenomena, including exotic superconductivity [6][7][8] and superfluidity [9], orbital magnetism [10,11], the stability of fractional quantum Hall states [12][13][14][15][16][17], semiclassical wavepacket dynamics [18,19], topological phase transitions [20], and light-matter coupling in flat-band systems [21]. Besides, the quantum metric plays a central role in the construction of maximally-localized Wannier functions in crystals [22,23], and it provides practical signatures for exotic momentum-space monopoles [24,25] and entanglement in topological superconductors [26,27].…”

Section: Introductionmentioning

confidence: 99%

Relating the topology of Dirac Hamiltonians to quantum geometry: When the quantum metric dictates Chern numbers and winding numbers

2022

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Quantum geometry has emerged as a central and ubiquitous concept in quantum sciences, with direct consequences on quantum metrology and many-body quantum physics. In this context, two fundamental geometric quantities are known to play complementary roles:~the Fubini-Study metric, which introduces a notion of distance between quantum states defined over a parameter space, and the Berry curvature associated with Berry-phase effects and topological band structures. In fact, recent studies have revealed direct relations between these two important quantities, suggesting that topological properties can, in special cases, be deduced from the quantum metric. In this work, we establish general and exact relations between the quantum metric and the topological invariants of generic Dirac Hamiltonians. In particular, we demonstrate that topological indices (Chern numbers or winding numbers) are bounded by the quantum volume determined by the quantum metric. Our theoretical framework, which builds on the Clifford algebra of Dirac matrices, is applicable to topological insulators and semimetals of arbitrary spatial dimensions, with or without chiral symmetry. This work clarifies the role of the Fubini-Study metric in topological states of matter, suggesting unexplored topological responses and metrological applications in a broad class of quantum-engineered systems.

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Light-matter coupling and quantum geometry in moiré materials

Cited by 3 publications

References 128 publications

Effective theory of lattice electrons strongly coupled to quantum electromagnetic fields

Effective theory of lattice electrons strongly coupled to quantum electromagnetic fields

An effective curved space-time geometric theory of generic twist angle graphene with application to a rotating bilayer configuration

Relating the topology of Dirac Hamiltonians to quantum geometry: When the quantum metric dictates Chern numbers and winding numbers

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