Light-matter coupling and quantum geometry in moiré materials

Topp, Gabriel E.; Eckhardt, Christian; Kennes, Dante M.; Sentef, Michael A.; Törmä, Païvi

doi:10.1103/physrevb.104.064306

Cited by 40 publications

(19 citation statements)

References 159 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For instance, Berry curvature governs the anomalous transport of an electron wave packet [3], while its integral over the Brillouin zone (BZ) gives the Chern number, which, among other topological invariants, is central in explaining the quantum Hall effect and topological insulators [4][5][6][7][8][9]. The importance of the quantum metric for phenomena such as superconductivity [10][11][12][13], orbital magnetic susceptibility [14,15], and light-matter coupling [16] has been understood only recently, and the interest in the quantum metric is rapidly growing [17][18][19][20]. Quantum geometric concepts have also been proposed for bosonic systems composed of light, bosonic atoms, or collective excitations [21][22][23][24][25][26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Excitations of a Bose-Einstein condensate and the quantum geometry of a flat band

2021

Self Cite

View full text Add to dashboard Cite

The quantum geometry of Bloch states fundamentally affects a wide range of physical phenomena. The quantum Hall effect, for example, is governed by the Chern number, and flat-band superconductivity by the distance between the Bloch states: the quantum metric. While understanding quantum geometry phenomena in the context of fermions is well established, less is known about the role of quantum geometry in bosonic systems where particles can undergo Bose-Einstein condensation (BEC). In conventional single-band or continuum systems, excitations of a weakly interacting BEC are determined by the condensate density and the interparticle interaction energy. In contrast to this, we discover here fundamental connections between the properties of a weakly interacting BEC and the underlying quantum geometry of a multiband lattice system. We show that, in the flat-band limit, the defining physical quantities of BEC, namely, the speed of sound and the quantum depletion, are dictated solely by the quantum geometry. We find that the speed of sound becomes proportional to the quantum metric of the condensed state. Furthermore, the quantum distance between the Bloch functions forces the quantum depletion and the quantum fluctuations of the density-density correlation to obtain finite values for infinitesimally small interactions. This is in striking contrast to dispersive bands where these quantities vanish with the interaction strength. Additionally, we show how in the flat-band limit the supercurrent is carried by the quantum fluctuations and is determined by the Berry connections of the Bloch states. Our results reveal how nontrivial quantum geometry allows reaching strong quantum correlation regime of condensed bosons even with weak interactions. This is highly relevant, for example, for polariton and photon BECs where interparticle interactions are inherently small. Our predictions can be experimentally tested with flat-band lattices already implemented in ultracold gases and various photonic platforms.

show abstract

Section: Introductionmentioning

confidence: 99%

Excitations of a Bose-Einstein condensate and the quantum geometry of a flat band

2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…The quantum metric is a fundamental quantity describing distances between the eigenstates of a system, and hence appears in many observables of interacting systems. For instance, light-matter interactions in TBG reflect the underlying quantum geometry as well [148,149]. Recently, quantum geometry was predicted to stabilize Bose-Einstein condensates in flat bands [150], relevant for bosonic condensates in ultracold gas and polariton systems, or even for 2D moiré materials at the bosonic end of the BCS-BEC crossover [98].…”

Section: Discussionmentioning

confidence: 99%

Superfluidity and Quantum Geometry in Twisted Multilayer Systems

Törmä¹,

Peotta²,

Bernevig³

2021

Preprint

View full text Add to dashboard Cite

Designer 2D materials where the constituent layers are not aligned may result in band structures with dispersionless, "flat" bands. Twisted bilayer graphene has been found to show correlated phases as well as superconductivity related to such flat bands. In parallel, theory work has discovered that superconductivity and superfluidity is determined by the quantum geometry and topology of the band structure. These recent key developments are merging to a flourishing research topic: understanding the possible connection and ramifications of quantum geometry on the induced superconductivity and superfluidity in moiré multilayer and other flat band systems. This article presents an introduction to how quantum geometry governs superfluidity in platforms including, and beyond, graphene. We explain how a new type of topology discovered in TBG could affect superconductivity, pinpoint the geometric contribution in its Beretzinskii-Kosterlitz-Thouless (BKT) critical temperature, and mention moiré materials beyond TBG. Ultracold gases are introduced as a complementary platform for quantum geometric effects and a comparison is made to moiré materials. An outlook sketches the prospects of twisted multilayer systems in providing the route to room temperature superconductivity.

show abstract

“…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 lightmatter 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

View full text Add to dashboard Cite

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.

show abstract

Light-matter coupling and quantum geometry in moiré materials

Cited by 40 publications

References 159 publications

Excitations of a Bose-Einstein condensate and the quantum geometry of a flat band

Excitations of a Bose-Einstein condensate and the quantum geometry of a flat band

Superfluidity and Quantum Geometry in Twisted Multilayer Systems

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

Contact Info

Product

Resources

About