Classification of flat bands according to the band-crossing singularity of Bloch wave functions

Rhim, Jun‐Won; Yang, Bohm‐Jung

doi:10.1103/physrevb.99.045107

Cited by 156 publications

(179 citation statements)

References 75 publications

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“…The missing states are the so‐called noncontractible loop states (NLSs) winding around the entire (infinite) lattices, a manifestation of real‐space topology. [ 37,38 ] NLSs are a new type of flatband eigenstates which cannot be obtained by linear superposition of the conventional CLSs, and they cannot be continuously deformed into the CLSs in a torus geometry representing the periodical boundary conditions. Recently, it was theoretically found that the NLSs are inherent to the singular flatband, where an immovable singularity exists in the band‐crossing of the Bloch wavefunctions.…”

Section: Figurementioning

confidence: 99%

“…Recently, it was theoretically found that the NLSs are inherent to the singular flatband, where an immovable singularity exists in the band‐crossing of the Bloch wavefunctions. [ 38 ] Since an infinite lattice or a torus structure (mimicking the periodic boundary conditions) is difficult to establish in experiment, an alternative approach is to observe the “line states” in truncated lattices with appropriate boundaries. The existence of the line states does not rely on the spatial size of the lattice but rather on the boundary termination.…”

Section: Figurementioning

confidence: 99%

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Flatband Line States in Photonic Super‐Honeycomb Lattices

Yan

Zhong

Song

et al. 2020

Advanced Optical Materials

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We establish experimentally a photonic super-honeycomb lattice (sHCL) by use of a cw-laser writing technique, and thereby demonstrate two distinct flatband line states that manifest as noncontractible-loop-states in an infinite flatband lattice. These localized states ("straight" and "zigzag" lines) observed in the sHCL with tailored boundaries cannot be obtained by superposition of conventional compact localized states because they represent a new topological entity in flatband systems. In fact, the zigzag-line states, unique to the sHCL, are in contradistinction with those previously observed in the Kagome and Lieb lattices. Their momentum-space spectrum emerges in the high-order Brillouin zone where the flat band touches the dispersive bands, revealing the characteristic of topologically protected bandcrossing. Our experimental results are corroborated by numerical simulations based on the coupled mode theory. This work may provide insight to Dirac-like 2D materials beyond graphene.

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Flatband Line States in Photonic Super‐Honeycomb Lattices

Yan

Zhong

Song

et al. 2020

Advanced Optical Materials

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“…Like the protection of the Dirac points of graphene, the mechanism for this stability is topological. Very recently, Rhim and Yang [93] showed that flat-bands can be classified into two distinct classes, singular or nonsingular, based on whether the corresponding Bloch functions exhibit a discontinuity at the crossing points with other bands.…”

Section: Numerical Methods and Flat-band Classificationmentioning

confidence: 99%

“…Such missing states are accounted for by noncontractible loops around the torus under periodic boundary conditions (the so-called NLSs). More recently, Rhim et al theoretically found that the NLSs are inherent to the singular flat-band, where an immovable singularity exists in the band-crossing of the Bloch wavefunctions [93]. Once the degeneracy at the band-crossing point is lifted, the flat-band becomes dispersive and may acquire a finite Chern number in general.…”

Section: Line States In Lieb and Superhoneycomb Latticesmentioning

confidence: 99%

Photonic flat-band lattices and unconventional light localization

et al. 2020

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AbstractFlat-band systems have attracted considerable interest in different branches of physics in the past decades, providing a flexible platform for studying fundamental phenomena associated with completely dispersionless bands within the whole Brillouin zone. Engineered flat-band structures have now been realized in a variety of systems, in particular, in the field of photonics. Flat-band localization, as an important phenomenon in solid-state physics, is fundamentally interesting in the exploration of exotic ground-state properties of many-body systems. However, direct observation of some flat-band phenomena is highly nontrivial in conventional condensed-matter systems because of intrinsic limitations. In this article, we briefly review recent developments on flat-band localization and the associated phenomena in various photonic lattices, including compact localized states, unconventional line states, and noncontractible loop states. We show that the photonic lattices offer a convenient platform for probing the underlying physics of flat-band systems, which may provide inspiration for exploring the fundamentals and applications of flat-band physics in other structured media from metamaterials to nanophotonic materials.

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“…On the other hand, in the electronic models, the flat bands can have singular character due to the immovable discontinuity of Bloch wave functions, which result in the incompleteness of the CLSs and bring forth the new states at flat band energy. Several previous works have theoretically studied the additional noncompact states in the frustrated lattices and other singular flat band models [25][26][27][28]. In photonic systems, a missing line state has recently been experimentally found in a finite Lieb system under bearded truncations using the photonic writing waveguides [29].…”

Section: Introductionmentioning

confidence: 99%

Photonic zero-energy modes in a metal-based Lieb lattice

Chen

2019

New J. Phys.

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We design a photonic tight-binding system using the dispersive background, and observe the noncompact photonic zero-energy modes for both monopole and dipolar states in a finite Lieb lattice with flat truncations. In such a photonic Lieb system, the compact localization of s, p, and d flat bands is also checked. We show that this photonic zero-energy mode is provided by one dispersive band for singular touching, which has the same frequency with the flat band states. Specially, the zero-energy mode can be completely excited by merely one point source at the flat band frequency, covering all the minority sites and forming a noncompact state. This work may provide a deep understanding about the photonic zero-energy mode for higher order states in the Lieb or other flat band models.

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Classification of flat bands according to the band-crossing singularity of Bloch wave functions

Cited by 156 publications

References 75 publications

Flatband Line States in Photonic Super‐Honeycomb Lattices

Flatband Line States in Photonic Super‐Honeycomb Lattices

Photonic flat-band lattices and unconventional light localization

Photonic zero-energy modes in a metal-based Lieb lattice

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