Experimental realization of topologically protected unidirectional surface magnon polaritons on ceramic YIG ferrites

Abstract The Hofstadter model, well known for its fractal butterfly spectrum, describes two-dimensional electrons under a perpendicular magnetic field, which gives rise to the integer quantum Hall effect. Inspired by the real-space building blocks of non-Abelian gauge fields from a recent experiment, we introduce and theoretically study two non-Abelian generalizations of the Hofstadter model. Each model describes two pairs of Hofstadter butterflies that are spin–orbit coupled. In contrast to the original Hofstadter model that can be equivalently studied in the Landau and symmetric gauges, the corresponding non-Abelian generalizations exhibit distinct spectra due to the non-commutativity of the gauge fields. We derive the genuine (necessary and sufficient) non-Abelian condition for the two models from the commutativity of their arbitrary loop operators. At zero energy, the models are gapless and host Weyl and Dirac points protected by internal and crystalline symmetries. Double (8-fold), triple (12-fold), and quadrupole (16-fold) Dirac points also emerge, especially under equal hopping phases of the non-Abelian potentials. At other fillings, the gapped phases of the models give rise to topological insulators. We conclude by discussing possible schemes for experimental realization of the models on photonic platforms.

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Development and experimental realization of an adaptive neural-based discrete model predictive direct torque and flux controller for induction motor drive

Applied Soft Computing ◽

10.1016/j.asoc.2021.107418 ◽

2021 ◽

Vol 108 ◽

pp. 107418

Author(s):

Abhimanyu Sahu ◽

Kanungo Barada Mohanty ◽

Rabi Narayan Mishra

Keyword(s):

Induction Motor ◽

Discrete Model ◽

Motor Drive ◽

Induction Motor Drive ◽

Experimental Realization

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Experimental realization of atomically flat and AlO2 -terminated LaAlO3 (001) substrate surfaces

Physical Review Materials ◽

10.1103/physrevmaterials.3.023801 ◽

2019 ◽

Vol 3 (2) ◽

Cited By ~ 2

Author(s):

Jeong Rae Kim ◽

Jiyeon N. Lee ◽

Junsik Mun ◽

Yoonkoo Kim ◽

Yeong Jae Shin ◽

...

Keyword(s):

Experimental Realization ◽

Substrate Surfaces ◽

Atomically Flat

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Experimental realization of a nonlinear acoustic lens with a tunable focus

Applied Physics Letters ◽

10.1063/1.4857635 ◽

2014 ◽

Vol 104 (1) ◽

pp. 014103 ◽

Cited By ~ 49

Author(s):

Carly M. Donahue ◽

Paul W. J. Anzel ◽

Luca Bonanomi ◽

Thomas A. Keller ◽

Chiara Daraio

Keyword(s):

Experimental Realization ◽

Acoustic Lens ◽

Nonlinear Acoustic

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Non-Hermitian route to higher-order topology in an acoustic crystal

Nature Communications ◽

10.1038/s41467-021-22223-y ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

He Gao ◽

Haoran Xue ◽

Zhongming Gu ◽

Tuo Liu ◽

Jie Zhu ◽

...

Keyword(s):

Higher Order ◽

Order Topology ◽

Topological Phases ◽

Edge States ◽

Experimental Realization ◽

Artificial Materials ◽

Intrinsic Loss ◽

Topological Phases Of Matter ◽

Hierarchical Features ◽

Nontrivial Topology

AbstractTopological phases of matter are classified based on their Hermitian Hamiltonians, whose real-valued dispersions together with orthogonal eigenstates form nontrivial topology. In the recently discovered higher-order topological insulators (TIs), the bulk topology can even exhibit hierarchical features, leading to topological corner states, as demonstrated in many photonic and acoustic artificial materials. Naturally, the intrinsic loss in these artificial materials has been omitted in the topology definition, due to its non-Hermitian nature; in practice, the presence of loss is generally considered harmful to the topological corner states. Here, we report the experimental realization of a higher-order TI in an acoustic crystal, whose nontrivial topology is induced by deliberately introduced losses. With local acoustic measurements, we identify a topological bulk bandgap that is populated with gapped edge states and in-gap corner states, as the hallmark signatures of hierarchical higher-order topology. Our work establishes the non-Hermitian route to higher-order topology, and paves the way to exploring various exotic non-Hermiticity-induced topological phases.

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Experimental realization of the classical Dicke model

Physical Review Research ◽

10.1103/physrevresearch.2.033169 ◽

2020 ◽

Vol 2 (3) ◽

Author(s):

Mario A. Quiroz-Juárez ◽

Jorge Chávez-Carlos ◽

José L. Aragón ◽

Jorge G. Hirsch ◽

Roberto de J. León-Montiel

Keyword(s):

Experimental Realization ◽

Dicke Model

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Double moiré localized plasmon structured illumination microscopy

Nanophotonics ◽

10.1515/nanoph-2020-0521 ◽

2020 ◽

Vol 0 (0) ◽

Author(s):

Ruslan Röhrich ◽

A. Femius Koenderink

Keyword(s):

Near Field ◽

Super Resolution ◽

Reconstruction Algorithm ◽

Structured Illumination ◽

Structured Illumination Microscopy ◽

Experimental Realization ◽

Spatial Frequencies ◽

Wide Range ◽

Localized Plasmon ◽

Plasmonic Grating

AbstractStructured illumination microscopy (SIM) is a well-established fluorescence imaging technique, which can increase spatial resolution by up to a factor of two. This article reports on a new way to extend the capabilities of structured illumination microscopy, by combining ideas from the fields of illumination engineering and nanophotonics. In this technique, plasmonic arrays of hexagonal symmetry are illuminated by two obliquely incident beams originating from a single laser. The resulting interference between the light grating and plasmonic grating creates a wide range of spatial frequencies above the microscope passband, while still preserving the spatial frequencies of regular SIM. To systematically investigate this technique and to contrast it with regular SIM and localized plasmon SIM, we implement a rigorous simulation procedure, which simulates the near-field illumination of the plasmonic grating and uses it in the subsequent forward imaging model. The inverse problem, of obtaining a super-resolution (SR) image from multiple low-resolution images, is solved using a numerical reconstruction algorithm while the obtained resolution is quantitatively assessed. The results point at the possibility of resolution enhancements beyond regular SIM, which rapidly vanishes with the height above the grating. In an initial experimental realization, the existence of the expected spatial frequencies is shown and the performance of compatible reconstruction approaches is compared. Finally, we discuss the obstacles of experimental implementations that would need to be overcome for artifact-free SR imaging.

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Quantum loop states in spin-orbital models on the honeycomb lattice

Nature Communications ◽

10.1038/s41467-021-23033-y ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Lucile Savary

Keyword(s):

Realistic Model ◽

Quantum Spin ◽

Honeycomb Lattice ◽

Spin Liquids ◽

Spin Orbital ◽

Experimental Realization ◽

Quantum Phases ◽

Quantum Spin Liquids ◽

Quantum Spin Liquid ◽

Symmetry Protected

AbstractThe search for truly quantum phases of matter is a center piece of modern research in condensed matter physics. Quantum spin liquids, which host large amounts of entanglement—an entirely quantum feature where one part of a system cannot be measured without modifying the rest—are exemplars of such phases. Here, we devise a realistic model which relies upon the well-known Haldane chain phase, i.e. the phase of spin-1 chains which host fractional excitations at their ends, akin to the hallmark excitations of quantum spin liquids. We tune our model to exactly soluble points, and find that the ground state realizes Haldane chains whose physical supports fluctuate, realizing both quantum spin liquid like and symmetry-protected topological phases. Crucially, this model is expected to describe actual materials, and we provide a detailed set of material-specific constraints which may be readily used for an experimental realization.

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