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3. Photonic topological insulator in synthetic dimensions

Author

Lustig, Eran, Weimann, Steffen, Plotnik, Yonatan, Lumer, Yaakov, Bandres, Miguel A., Szameit, Alexander, and Segev, Mordechai

Subjects
Electrical insulators -- Models -- Analysis, Photonics -- Analysis -- Models, Waveguides, Electronics, Magnetic fields, Electromagnetism, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Topological phases enable protected transport along the edges of materials, offering immunity against scattering from disorder and imperfections. These phases have been demonstrated for electronic systems, electromagnetic waves.sup.1-5, cold atoms.sup.6,7, acoustics.sup.8 and even mechanics.sup.9, and their potential applications include spintronics, quantum computing and highly efficient lasers.sup.10-12. Typically, the model describing topological insulators is a spatial lattice in two or three dimensions. However, topological edge states have also been observed in a lattice with one spatial dimension and one synthetic dimension (corresponding to the spin modes of an ultracold atom.sup.13-15), and atomic modes have been used as synthetic dimensions to demonstrate lattice models and physical phenomena that are not accessible to experiments in spatial lattices.sup.13,16,17. In photonics, topological lattices with synthetic dimensions have been proposed for the study of physical phenomena in high dimensions and interacting photons.sup.18-22, but so far photonic topological insulators in synthetic dimensions have not been observed. Here we demonstrate experimentally a photonic topological insulator in synthetic dimensions. We fabricate a photonic lattice in which photons are subjected to an effective magnetic field in a space with one spatial dimension and one synthetic modal dimension. Our scheme supports topological edge states in this spatial-modal lattice, resulting in a robust topological state that extends over the bulk of a two-dimensional real-space lattice. Our system can be used to increase the dimensionality of a photonic lattice and induce long-range coupling by design, leading to lattice models that can be used to study unexplored physical phenomena. A spatially oscillating two-dimensional waveguide array is used to realize a photonic topological insulator in synthetic dimensions with modal-space edge states, unidirectionality and robust topological protection., Author(s): Eran Lustig [sup.1] , Steffen Weimann [sup.2] , Yonatan Plotnik [sup.1] , Yaakov Lumer [sup.3] , Miguel A. Bandres [sup.1] , Alexander Szameit [sup.2] , Mordechai Segev [sup.1] Author [...]

Published
2019
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5. Photonic Floquet topological insulators

Author

Rechtsman, Mikael C., Zeuner, Julia M., Plotnik, Yonatan, Lumer, Yaakov, Podolsky, Daniel, Dreisow, Felix, Nolte, Stefan, Segev, Mordechai, and Szameit, Alexander

Subjects
Geochemical cycles -- Research, Matter -- Properties, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Topological insulators are a new phase of matter (1), with the striking property that conduction ofelectrons occurs only on theirsurfaces1 3. In two dimensions, electrons on the surface of a [...]

Published
2013

6. Photonic topological Anderson insulators

Author

Mordechai Segev, Mikael C. Rechtsman, Alexander Szameit, Paraj Titum, Yonatan Plotnik, Yaakov Lumer, Simon Stützer, and Netanel H. Lindner

Subjects
Physics, Anderson localization, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Band gap, Scattering, business.industry, Phase (waves), FOS: Physical sciences, Insulator (electricity), 02 engineering and technology, 021001 nanoscience & nanotechnology, Topology, 01 natural sciences, 3. Good health, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, Refractive index contrast, Photonics, 010306 general physics, 0210 nano-technology, business, Quantum, Physics - Optics, Optics (physics.optics)
Abstract

The hallmark property of two-dimensional topological materials is the incredible robustness of the quantized Hall conductivity to disorder. That robustness arises from the fact that in the topological band gap, transport can occur only along the edges modes, which are immune to scattering. However, for sufficiently strong disorder, the band gap closes and the system becomes topologically trivial as all states become localized, such that all transport vanishes -- in accordance with Anderson localization. It therefore came as a surprise when it was suggested that, for a two-dimensional quantum spin-Hall topological system, the opposite could occur. In so-called topological Anderson insulators, the emergence of protected edge states and quantized transport is caused by the introduction of disorder. However, to date, the observation of the topological Anderson insulator phase has been elusive. In this article, we report the first experimental demonstration of a topological Anderson insulator. We do that in a photonic implementation: an array of helical, evanescently-coupled waveguides in a detuned honeycomb geometry. Under proper conditions, adding on-site disorder, in the form of random variations in the refractive index contrast defining the waveguides, drives the system from a trivial phase into a topological state., Comment: 20 pages, 4 figures

Published
2018
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7. Photonic topological insulator in synthetic dimensions

Author

Yaakov Lumer, Steffen Weimann, Alexander Szameit, Mordechai Segev, Miguel A. Bandres, Eran Lustig, and Yonatan Plotnik

Subjects
Physics, Anderson localization, Multidisciplinary, Photon, Spintronics, business.industry, Physical system, FOS: Physical sciences, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Theoretical physics, Topological insulator, Lattice (order), 0103 physical sciences, Photonics, 010306 general physics, 0210 nano-technology, business, Physics - Optics, Optics (physics.optics), Quantum computer
Abstract

Topological phases enable protected transport along the edges of materials, offering immunity against scattering from disorder and imperfections. These phases were suggested and demonstrated not only for electronic systems, but also for electromagnetic waves, cold atoms, acoustics, and even mechanics. Their potential applications range from spintronics and quantum computing to highly efficient lasers. Traditionally, the underlying model of these systems is a spatial lattice in two or three dimensions. However, it recently became clear that many lattice systems can exist also in synthetic dimensions which are not spatial but extend over a different degree of freedom. Thus far, topological insulators in synthetic dimensions were demonstrated only in cold atoms, where synthetic dimensions have now become a useful tool for demonstrating a variety of lattice models that are not available in spatial lattices. Subsequently, efforts have been directed towards realizing topological lattices with synthetic dimensions in photonics, where they are connected to physical phenomena in high-dimensions, interacting photons, and more. Here we demonstrate experimentally the first photonic topological insulator in synthetic dimensions. The ability to study experimentally photonic systems in synthetic dimensions opens the door for a plethora of unexplored physical phenomena ranging from PT-symmetry, exceptional points and unidirectional invisibility to Anderson localization in high dimensions and high-dimensional lattice solitons, topological insulator lasers in synthetic dimensions and more. Our study here paves the way to these exciting phenomena, which are extremely hard (if not impossible) to observe in other physical systems.

Published
2018

8. Photonic topological Anderson insulators

Author

Stützer, Simon, primary, Plotnik, Yonatan, additional, Lumer, Yaakov, additional, Titum, Paraj, additional, Lindner, Netanel H., additional, Segev, Mordechai, additional, Rechtsman, Mikael C., additional, and Szameit, Alexander, additional

Published
2018
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9. Photonic Floquet topological insulators

Author

Daniel K. Podolsky, Mordechai Segev, Mikael C. Rechtsman, Stefan Nolte, Felix Dreisow, Yonatan Plotnik, Alexander Szameit, Yaakov Lumer, and Julia M. Zeuner

Subjects
Floquet theory, Topological degeneracy, FOS: Physical sciences, 02 engineering and technology, Quantum Hall effect, Symmetry protected topological order, 01 natural sciences, Electromagnetic radiation, 010305 fluids & plasmas, Quantum mechanics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, Topological order, 010306 general physics, Topological quantum number, Photonic crystal, Quantum computer, Physics, Condensed Matter - Materials Science, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed matter physics, Spintronics, business.industry, Materials Science (cond-mat.mtrl-sci), 021001 nanoscience & nanotechnology, Condensed Matter - Other Condensed Matter, Topological insulator, Photonics, 0210 nano-technology, business, Physics - Optics, Optics (physics.optics), Other Condensed Matter (cond-mat.other)
Abstract

The topological insulator is a fundamentally new phase of matter, with the striking property that the conduction of electrons occurs only on its surface, not within the bulk, and that conduction is topologically protected. Topological protection, the total lack of scattering of electron waves by disorder, is perhaps the most fascinating and technologically important aspect of this material: it provides robustness that is otherwise known only for superconductors. However, unlike superconductivity and the quantum Hall effect, which necessitate low temperatures or magnetic fields, the immunity to disorder of topological insulators occurs at room temperature and without any external magnetic field. For this reason, topological protection is predicted to have wide-ranging applications in fault-tolerant quantum computing and spintronics. Recently, a large theoretical effort has been directed towards bringing the concept into the domain of photonics: achieving topological protection of light at optical frequencies. Besides the interesting new physics involved, photonic topological insulators hold the promise for applications in optical isolation and robust photon transport. Here, we theoretically propose and experimentally demonstrate the first photonic topological insulator: a photonic lattice exhibiting topologically protected transport on the lattice edges, without the need for any external field. The system is composed of an array of helical waveguides, evanescently coupled to one another, and arranged in a graphene-like honeycomb lattice. The chirality of the waveguides results in scatter-free, one-way edge states that are topologically protected from scattering., Comment: 21 pages, 5 figures

Published
2013
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10. Random sudoku light

Author

Eichelkraut, Toni and Szameit, Alexander

Subjects
Photonics -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

A clever approach has been used to imprint a phase pattern on a laser beam. The pattern is not only random at each point, but also depends on information stored [...]

Published
2015

12. Random sudoku light

Author

Alexander Szameit and Toni Eichelkraut

Subjects
Physics, Multidisciplinary, Optics, business.industry, Phase (waves), Point (geometry), Photonics, business, Laser beams
Abstract

A clever approach has been used to imprint a phase pattern on a laser beam. The pattern is not only random at each point, but also depends on information stored elsewhere in the pattern.

Published
2015
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13. Photonics: Random sudoku light.

Author

Eichelkraut, Toni and Szameit, Alexander

Subjects
*MARKOV spectrum, *PHASE transitions, *LASER beams, *SCIENTIFIC experimentation
Abstract

The article discusses a study which reported the first experimental demonstration of non-Markovian light. Information is provided on how a phase-imprinting approach was used to form a light field with a fully random phase at each spatial point and a local random nature determined by both nearby and farther away points.

Published
2015
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