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1. Relation between interface symmetry and propagation robustness along domain walls based on valley topological photonic crystals

Author

Lévêque, Gaëtan, Szriftgiser, Pascal, Amo, Alberto, and Pennec, Yan

Subjects
Physics - Optics
Abstract

Valley photonic crystals provide efficient designs for the routing of light through channels in extremely compact geometries. The topological origin of the robust transport and the specific geometries under which it can take place have been questioned in recent works. In this article, we introduce a design for valley photonic crystals with richer arrangement possibilities than the standard valley photonic crystals based on two holes of different sizes in the unit cell. Our approach is based on the permutation of three sets of rhombi in an hexagonal lattice to investigate the interplay between Berry curvature, valley Chern number and chirality of interfaces to achieve robust edge-modes propagation along domain walls. We study three types of interfaces with different symmetries: the non-chiral interface with glide-mirror symmetry commonly used in honeycomb-type valley crystals, and two chiral interfaces with or without inversion symmetry of the adjacent bulk lattices. In the latter case, no valley topology is expected. We show that for the three families, edges preserving the shape of the interface through 120{\deg} sharp corners can sustain edge-modes with comparable robustness. Moreover, interfaces with glide-mirror symmetry offer promising performances in circuits with more exotic configurations, like 60{\deg} and 90{\deg} corners or arbitrary curves in which valley preservation is not guaranteed. Our work raises questions about the topological origin of the robustness of transport in valley photonic crystals, discusses the role of the chirality of the interfaces in the propagation around sharp corners, and provides a lattice scheme with broad design possibilities., Comment: 2 pages, 6 figures, 1 supplemental materials file, 2 supplemental materials movies

Published
2024

2. Edge-dependent anomalous topology in synthetic photonic lattices subject to discrete step walks

Author

Sokhen, Rabih El, Gómez-León, Álvaro, Adiyatullin, Albert F., Randoux, Stéphane, Delplace, Pierre, and Amo, Alberto

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Anomalous topological phases, where edge states coexist with topologically trivial Chern bands, can only appear in periodically driven lattices. When the driving is smooth and continuous, the bulk-edge correspondence is guaranteed by the existence of a bulk invariant known as the winding number. However, in lattices subject to periodic discrete-step walks the existence of edge states does not only depend on bulk invariants but also on the boundary. This is a consequence of the absence of an intrinsic time-dependence or micromotion in discrete-step walks. We report the observation of edge states and a simultaneous measurement of the bulk invariants in anomalous topological phases in a two-dimensional synthetic photonic lattice subject to discrete-step walks. The lattice is implemented using time multiplexing of light pulses in two coupled fibre rings, in which one of the dimensions displays real space dynamics and the other one is parametric. The presence of edge states is inherent to the periodic driving and depends on the properties of the boundary in the implemented two-band model with zero Chern number. We provide a suitable expression for the topological invariants whose calculation does not rely on micromotion dynamics., Comment: 12 pages main text plus 7 pages of apppendix (19 pages total). Published version

Published
2023
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4. Scattering-matrix approach for a quantitative evaluation of the topological protection in valley photonic crystals

Author

Lévêque, Gaëtan, Pennec, Yan, Szriftgiser, Pascal, Amo, Alberto, and Martínez, Alejandro

Subjects
Physics - Optics
Abstract

In this work, we use valley-topological triangular resonators coupled to an input waveguide to evaluate the quality of the topological protection. To that purpose, we first analyze via numerical simulations the existence of backward scattering at cavity corners or transmission with pseudo-spin conversion at the splitter between the input waveguide and the cavity. We evidence that a breakdown of topological protection takes place, in particular at sharp corners, which results in transmission minima and split-resonances, otherwise non-existent. In order to evaluate the small coupling coefficients associated to this breakdown, a phenomenological model based on an exact parameterization of scattering matrices at splitters and corners of the resonators is then introduced. By comparison with the numerical simulations, we are able to quantify the loss of topological protection at sharp bends and splitters. Finally, we use the obtained set of phenomenological parameters to compare the predictions of the phenomenological model with full numerical simulations for fractal-inspired cavities based on the Sierpi\'nski triangle construction. We show that the agreement is overall good, but shows more differences for the cavity composed of the smallest triangles. Our results suggest that even in a system exempt of geometrical and structural defects, topological protection is not complete at corners, sharp bends and splitters. However, simpler but predictive calculations can be realized with a phenomenological approach, allowing simulations of very large devices beyond the reach of standard simulation methods, which is crucial to design photonic devices which gather compactness and low losses through topological conduction of electromagnetic waves., Comment: 24 pages, 7 figures, one supplementary informations file

Published
2023

5. Spectral edge-to-edge topological state transfer in diamond photonic lattices

Author

Cáceres-Aravena, Gabriel, Real, Bastián, Guzmán-Silva, Diego, Vildoso, Paloma, Salinas, Ignacio, Amo, Alberto, Ozawa, Tomoki, and Vicencio, Rodrigo A.

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Transfer of information between topological edge states is a robust way of spatially manipulating quantum states while preserving their coherence in lattice environments. This method is particularly efficient when the edge modes are kept within the topological gap of the lattice during the transfer. In this work we show experimentally the transfer of photonic modes between topological edge states located at opposite ends of a dimerized one-dimensional photonic lattice. We use a diamond lattice of coupled waveguides and show that the transfer is insensitive both to the presence of a high density of states in the form of a flat band at an energy close to that of the edge states, and to the presence of disorder in the hoppings. We explore dynamics in the waveguide lattice using wavelength-scan method, where different input wavelength translates into different effective waveguide length. These results open the way to the implementation of more efficient protocols based on the active driving of the hoppings., Comment: 6 pages and 3 figures

Published
2023

6. Topological properties of Floquet winding bands in a photonic lattice

Author

Adiyatullin, Albert F., Upreti, Lavi K., Lechevalier, Corentin, Evain, Clement, Copie, Francois, Suret, Pierre, Randoux, Stephane, Delplace, Pierre, and Amo, Alberto

Subjects
Physics - Optics
Abstract

The engineering of synthetic materials characterised by more than one class of topological invariants is one of the current challenges of solid-state based and synthetic materials. Using a synthetic photonic lattice implemented in a two-coupled ring system we engineer an anomalous Floquet metal that is gapless in the bulk and shows simultaneously two different topological properties. On the one hand, this synthetic lattice presents bands characterised by a winding number. The winding emerges from the breakup of inversion symmetry and it directly relates to the appearance of Bloch suboscillations within its bulk. On the other hand, the Floquet nature of the lattice results in well-known anomalous insulating phases with topological edge states. The combination of broken inversion symmetry and periodic time modulation studied here enrich the variety of topological phases available in lattices subject to Floquet driving and suggest the possible emergence of novel phases when periodic modulation is combined with the breakup of spatial symmetries., Comment: Published version. Includes supplementary information

Published
2022
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7. Roadmap on Topological Photonics

Author

Price, Hannah, Chong, Yidong, Khanikaev, Alexander, Schomerus, Henning, Maczewsky, Lukas J., Kremer, Mark, Heinrich, Matthias, Szameit, Alexander, Zilberberg, Oded, Yang, Yihao, Zhang, Baile, Alù, Andrea, Thomale, Ronny, Carusotto, Iacopo, St-Jean, Philippe, Amo, Alberto, Dutt, Avik, Yuan, Luqi, Fan, Shanhui, Yin, Xuefan, Peng, Chao, Ozawa, Tomoki, and Blanco-Redondo, Andrea

Subjects
Physics - Optics
Abstract

Topological photonics seeks to control the behaviour of the light through the design of protected topological modes in photonic structures. While this approach originated from studying the behaviour of electrons in solid-state materials, it has since blossomed into a field that is at the very forefront of the search for new topological types of matter. This can have real implications for future technologies by harnessing the robustness of topological photonics for applications in photonics devices. This Roadmap surveys some of the main emerging areas of research within topological photonics, with a special attention to questions in fundamental science, which photonics is in an ideal position to address. Each section provides an overview of the current and future challenges within a part of the field, highlighting the most exciting opportunities for future research and developments., Comment: Invited Roadmap submission to Journal of Physics: Photonics

Published
2022

8. Observation of KPZ universal scaling in a one-dimensional polariton condensate

Author

Fontaine, Quentin, Squizzato, Davide, Baboux, Florent, Amelio, Ivan, Lemaître, Aristide, Morassi, Marina, Sagnes, Isabelle, Gratiet, Luc Le, Harouri, Abdelmounaim, Wouters, Michiel, Carusotto, Iacopo, Amo, Alberto, Richard, Maxime, Minguzzi, Anna, Canet, Léonie, Ravets, Sylvain, and Bloch, Jacqueline

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Physics - Optics
Abstract

Revealing universal behaviors is a hallmark of statistical physics. Phenomena such as the stochastic growth of crystalline surfaces, of interfaces in bacterial colonies, and spin transport in quantum magnets all belong to the same universality class, despite the great plurality of physical mechanisms they involve at the microscopic level. This universality stems from a common underlying effective dynamics governed by the non-linear stochastic Kardar-Parisi-Zhang (KPZ) equation. Recent theoretical works suggest that this dynamics also emerges in the phase of out-of-equilibrium systems displaying macroscopic spontaneous coherence. Here, we experimentally demonstrate that the evolution of the phase in a driven-dissipative one-dimensional polariton condensate falls in the KPZ universality class. Our demonstration relies on a direct measurement of KPZ space-time scaling laws, combined with a theoretical microscopic analysis that consistently reveals the other key signatures of this universality class, together with the possible resilience of KPZ dynamics to the presence of space-time vortices. Our results highlight fundamental physical differences between out-of-equilibrium condensates and their equilibrium counterparts, and open a new paradigm for exploring universal behaviors in open systems.

Published
2021
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9. Few-photon all-optical phase rotation in a quantum-well micropillar cavity

Author

Kuriakose, Tintu, Walker, Paul M., Dowling, Toby, Kyriienko, Oleksandr, Shelykh, Ivan A., St-Jean, Phillipe, Zambon, Nicola Carlon, Lemaître, Aristide, Sagnes, Isabelle, Legratiet, Luc, Harouri, Abdelmounaim, Ravets, Sylvain, Skolnick, Maurice S., Amo, Alberto, Bloch, Jacqueline, and Krizhanovskii, Dmitry N.

Subjects
Physics - Optics, Condensed Matter - Other Condensed Matter
Abstract

Photonic platforms are an excellent setting for quantum technologies because weak photon-environment coupling ensures long coherence times. The second key ingredient for quantum photonics is interactions between photons, which can be provided by optical nonlinearities in the form of cross-phase-modulation (XPM). This approach underpins many proposed applications in quantum optics and information processing, but achieving its potential requires strong single-photon-level nonlinear phase shifts and also scalable nonlinear elements. In this work we show that the required nonlinearity can be provided by exciton-polaritons in micropillars with embedded quantum wells. These combine the strong interactions of excitons with the scalability of micrometer-sized emitters. We observe XPM up to $3 \pm 1$ mrad per particle using laser beams attenuated to below single photon average intensity. With our work serving as a first stepping stone, we lay down a route for quantum information processing in polaritonic lattices.

Published
2021
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10. Single shot measurement of the photonic band structure in a Floquet-Bloch lattice realised with coupled fiber rings

Author

Lechevalier, Corentin, Evain, Clément, Suret, Pierre, Copie, François, Amo, Alberto, and Randoux, Stéphane

Subjects
Physics - Optics
Abstract

Floquet-Bloch lattices are systems in which wave packets are subjet to periodic modulations both in time and space, showing rich dynamics. While this type of lattices is difficult to implement in solid-state physics, optical systems have provided excellent platforms to probe their physics: among other effects, they have revealed genuine phenomena such as the anomalous Floquet topological insulator and the funnelling of light into localised interface modes. Despite the crucial importance of the band dispersion in the photon dynamics and the topological properties of the lattice, the direct experimental measurement of the Floquet-Bloch bands has remained elusive. Here we report the direct measurement of the Floquet-Bloch bands of a photonic lattice with a single shot method. We use a system of two coupled fibre rings that implements a time-multiplexed Floquet-Bloch lattice. By Fourier transforming the impulse response of the lattice we obtain the band structure together with an accurate characterization of the lattice eigenmodes, i. e. the amplitudes and the phases of the Floquet-Bloch eigenvectors over the entire Brillouin zone. Our results open promising perspectives for the observation of topological effects in the linear and nonlinear regime in Floquet systems.

Published
2021

11. Microcavity polaritons for topological photonics

Author

Solnyshkov, Dmitry D., Malpuech, Guillaume, St-Jean, Philippe, Ravets, Sylvain, Bloch, Jacqueline, and Amo, Alberto

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Microcavity polaritons are light-matter quasiparticles that arise from the strong coupling between excitons and photons confined in a semiconductor microcavity. They typically operate at visible or near visible wavelengths. They combine the properties of confined electromagnetic fields, including a sizeable spin-orbit coupling, and the sensitivity to external magnetic fields and particle interactions inherited from their partly matter nature. These features make polaritons an excellent platform to study topological phases in photonics in one and two dimensional lattices, which band properties can be directly accessed using standard optical tools. In this review we describe the main properties of microcavity polaritons and the main observations in the field of topological photonics, which include, among others, lasing in topological edge states, the implementation of a polariton Chern insulator under an external magnetic field and the direct measurement of fundamental quantities such as the quantum geometric tensor and winding numbers in one- and two-dimensional lattices. Polariton interactions open exciting perspectives for the study of nonlinear topological phases., Comment: 19 pages, 8 figures, review article

Published
2020

12. Microcavity Polaritons for Quantum simulation

Author

Boulier, Thomas, Jacquet, Maxime J., Maître, Anne, Lerario, Giovanni, Claude, Ferdinand, Pigeon, Simon, Glorieux, Quentin, Bramati, Alberto, Giacobino, Elisabeth, Amo, Alberto, and Bloch, Jacqueline

Subjects
Condensed Matter - Quantum Gases, Quantum Physics
Abstract

Quantum simulations are one of the pillars of quantum technologies. These simulations provide insight in fields as varied as high energy physics, many-body physics, or cosmology to name only a few. Several platforms, ranging from ultracold-atoms to superconducting circuits through trapped ions have been proposed as quantum simulators. This article reviews recent developments in another well established platform for quantum simulations: polaritons in semiconductor microcavities. These quasiparticles obey a nonlinear Schr\"odigner equation (NLSE), and their propagation in the medium can be understood in terms of quantum hydrodynamics. As such, they are considered as "fluids of light". The challenge of quantum simulations is the engineering of configurations in which the potential energy and the nonlinear interactions in the NLSE can be controlled. Here, we revisit some landmark experiments with polaritons in microcavities, discuss how the various properties of these systems may be used in quantum simulations, and highlight the richness of polariton systems to explore non-equilibrium physics

Published
2020

13. Polaritonic XY-Ising Machine

Author

Kalinin, Kirill P., Amo, Alberto, Bloch, Jacqueline, and Berloff, Natalia G.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Emerging Technologies, Physics - Optics
Abstract

Gain-dissipative systems of various physical origin have recently shown the ability to act as analogue minimisers of hard combinatorial optimisation problems. Whether or not these proposals will lead to any advantage in performance over the classical computations depends on the ability to establish controllable couplings for sufficiently dense short- and long-range interactions between the spins. Here, we propose a polaritonic XY-Ising machine based on a network of geometrically isolated polariton condensates capable of minimising discrete and continuous spin Hamiltonians. We elucidate the performance of the proposed computing platform for two types of couplings: relative and absolute. The interactions between the network nodes might be controlled by redirecting the emission between the condensates or by sending the phase information between nodes using resonant excitation. We discuss the conditions under which the proposed machine leads to a pure polariton simulator with pre-programmed couplings or results in a hybrid classical polariton simulator. We argue that the proposed architecture for the remote coupling control offers an improvement over geometrically coupled condensates in both accuracy and stability as well as increases versatility, range and connectivity of spin Hamiltonians that can be simulated with polariton networks., Comment: 23 pages, 3 figures, invited submission

Published
2020

14. Active topological photonics

Author

Ota, Yasutomo, Takata, Kenta, Ozawa, Tomoki, Amo, Alberto, Jia, Zhetao, Kante, Boubacar, Notomi, Masaya, Arakawa, Yasuhiko, and Iwamoto, Satoshi

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Topological photonics has emerged as a novel route to engineer the flow of light. Topologically-protected photonic edge modes, which are supported at the perimeters of topologically-nontrivial insulating bulk structures, have been of particular interest as they may enable low-loss optical waveguides immune to structural disorder. Very recently, there is a sharp rise of interest in introducing gain materials into such topological photonic structures, primarily aiming at revolu-tionizing semiconductor lasers with the aid of physical mechanisms existing in topological physics. Examples of re-markable realizations are topological lasers with unidirectional light output under time-reversal symmetry breaking and topologically-protected polariton and micro/nano-cavity lasers. Moreover, the introduction of gain and loss provides a fascinating playground to explore novel topological phases, which are in close relevance to non-Hermitian and parity-time symmetric quantum physics and are in general difficult to access using fermionic condensed matter systems. Here, we review the cutting-edge research on active topological photonics, in which optical gain plays a pivotal role. We discuss recent realizations of topological lasers of various kinds, together with the underlying physics explaining the emergence of topological edge modes. In such demonstrations, the optical modes of the topological lasers are deter-mined by the dielectric structures and support lasing oscillation with the help of optical gain. We also address recent researches on topological photonic systems in which gain and loss themselves essentially influence on topological prop-erties of the bulk systems. We believe that active topological photonics provides powerful means to advance mi-cro/nanophotonics systems for diverse applications and topological physics itself as well., Comment: 23 pages, 11 figures, review paper to appear in Nanophotonics

Published
2019
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15. Multi-orbital tight binding model for cavity-polariton lattices

Author

Mangussi, Franco, Milićević, Marijana, Sagnes, Isabelle, Gratiet, Luc Le, Harouri, Abdelmounaim, Lemaître, Aristide, Bloch, Jacqueline, Amo, Alberto, and Usaj, Gonzalo

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this work we present a tight-binding model that allows to describe with a minimal amount of parameters the band structure of exciton-polariton lattices. This model based on $s$ and $p$ non-orthogonal photonic orbitals faithfully reproduces experimental results reported for polariton graphene ribbons. We analyze in particular the influence of the non-orthogonality, the inter-orbitals interaction and the photonic spin-orbit coupling on the polarization and dispersion of bulk bands and edge states., Comment: 14 pages, 8 figures

Published
2019
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16. Floquet Winding Metals

Author

Upreti, Lavi Kumar, Evain, Clément, Randoux, Stephane, Suret, Pierre, Amo, Alberto, and Delplace, Pierre

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

We propose a generic scattering matrix model implementable in photonics to engineer a new Floquet metallic phase that combines two distinct topological properties: the winding of the bulk bands and the existence of robust chiral edge states. The winding of the bulk bands gives rise to a wavepacket oscillations in real space while conserving its initial momentum. Our findings open the way to the study of a new class of winding Floquet systems., Comment: New improved version: arXiv:2203.01056

Published
2019

17. Orbital angular momentum bistability in a microlaser

Author

Zambon, Nicola Carlon, St-Jean, Philippe, Lemaître, Aristide, Harouri, Abdelmounaim, Gratiet, Luc Le, Sagnes, Isabelle, Ravets, Sylvain, Amo, Alberto, and Bloch, Jacqueline

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Light's orbital angular momentum (OAM) is an unbounded degree of freedom emerging in helical beams that appears very advantageous technologically. Using a chiral microlaser, i.e. an integrated device that allows generating an emission carrying a net OAM, we demonstrate a regime of bistability involving two modes presenting distinct OAM (L = 0 and L = 2). Furthermore, thanks to an engineered spin-orbit coupling of light in the device, these modes also exhibit distinct polarization patterns, i.e. cirular and azimuthal polarizations. Using a dynamical model of rate euqations, we show that this bistability arises from polarization-dependent saturation of the gain medium. Such a bistable regime appears very promising for implementing ultrafast optical switches based on the OAM of light. As well, it paves the way to the exploration of dynamical processes involving phase and polarization vortices.

Published
2018
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20. Gap solitons in a one-dimensional driven-dissipative topological lattice

Author

Pernet, Nicolas, St-Jean, Philippe, Solnyshkov, Dmitry D., Malpuech, Guillaume, Carlon Zambon, Nicola, Fontaine, Quentin, Real, Bastian, Jamadi, Omar, Lemaître, Aristide, Morassi, Martina, Le Gratiet, Luc, Baptiste, Téo, Harouri, Abdelmounaim, Sagnes, Isabelle, Amo, Alberto, Ravets, Sylvain, and Bloch, Jacqueline

Published
2022
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21. Dispersion relation of the collective excitations in a resonantly driven polariton fluid

Author

Stepanov, Petr, Amelio, Ivan, Rousset, Jean-Guy, Bloch, Jacqueline, Lemaître, Aristide, Amo, Alberto, Minguzzi, Anna, Carusotto, Iacopo, and Richard, Maxime

Subjects
Condensed Matter - Quantum Gases
Abstract

Exciton-polaritons in semiconductor microcavities constitute the archetypal realization of a quantum fluid of light. Under coherent optical drive, remarkable effects such as superfluidity, dark solitons or the nucleation of hydrodynamic vortices have been observed. These phenomena can be all understood as a specific manifestation of collective excitations forming on top of the polariton condensate. In this work, we performed a Brillouin scattering experiment to measure their dispersion relation $\omega(\mathbf{k})$ directly. The result, such as a speed of sound which is apparently twice too low, cannot be explained upon considering the polariton condensate alone. In a combined theoretical and experimental analysis, we demonstrate that the presence of a reservoir of long-lived excitons interacting with polaritons has a dramatic influence on the nature and characteristic of the quantum fluid, and that it explains our measurement quantitatively. This work clarifies the role of such a reservoir in the different polariton hydrodynamics phenomena occurring under resonant optical drive. It also provides an unambiguous tool to determine the condensate-to-reservoir fraction in the quantum fluid, and sets an accurate framework to approach novel ideas for polariton-based quantum-optical applications.

Published
2018
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22. Optically controlling the emission chirality of microlasers

Author

Zambon, Nicola Carlon, St-Jean, Philippe, Milićević, Marijana, Lemaître, Aristide, Harouri, Abdelmounaim, LeGratiet, Luc, Bleu, Olivier, Solnyshkov, Dmitry, Malpuech, Guillaume, Sagnes, Isabelle, Ravets, Sylvain, Amo, Alberto, and Bloch, Jacqueline

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Orbital angular momentum (OAM) carried by helical light beams is an unbounded degree of freedom of photons that offers a promising playground in modern photonics. So far, integrated sources of coherent light carrying OAM are based on resonators whose design imposes a single, non-tailorable chirality of the wavefront (i.e. clockwise or counter clockwise vortices). Here, we propose and demonstrate the realization of an integrated microlaser where the chirality of the wavefront can be optically controlled. Importantly, the scheme that we use, based on an effective spin-orbit coupling of photons in a semiconductor microcavity, can be extended to different laser architectures, thus paving the way to the realization of a new generation of OAM microlasers with tunable chirality.

Published
2018
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23. Topological Photonics

Author

Ozawa, Tomoki, Price, Hannah M., Amo, Alberto, Goldman, Nathan, Hafezi, Mohammad, Lu, Ling, Rechtsman, Mikael, Schuster, David, Simon, Jonathan, Zilberberg, Oded, and Carusotto, Iacopo

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Quantum Physics
Abstract

Topological photonics is a rapidly emerging field of research in which geometrical and topological ideas are exploited to design and control the behavior of light. Drawing inspiration from the discovery of the quantum Hall effects and topological insulators in condensed matter, recent advances have shown how to engineer analogous effects also for photons, leading to remarkable phenomena such as the robust unidirectional propagation of light, which hold great promise for applications. Thanks to the flexibility and diversity of photonics systems, this field is also opening up new opportunities to realize exotic topological models and to probe and exploit topological effects in new ways. This article reviews experimental and theoretical developments in topological photonics across a wide range of experimental platforms, including photonic crystals, waveguides, metamaterials, cavities, optomechanics, silicon photonics, and circuit QED. A discussion of how changing the dimensionality and symmetries of photonics systems has allowed for the realization of different topological phases is offered, and progress in understanding the interplay of topology with non-Hermitian effects, such as dissipation, is reviewed. As an exciting perspective, topological photonics can be combined with optical nonlinearities, leading toward new collective phenomena and novel strongly correlated states of light, such as an analog of the fractional quantum Hall effect., Comment: 87 pages, 30 figures, published version

Published
2018
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24. Quantum-correlated photons from semiconductor cavity polaritons

Author

Muñoz-Matutano, Guillermo, Wood, Andrew, Johnson, Mattias, Asensio, Xavier Vidal, Baragiola, Ben, Reinhard, Andreas, Lemaitre, Aristide, Bloch, Jaqueline, Amo, Alberto, Besga, Benjamin, Richard, Maxime, and Volz, Thomas

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Over the past decade, exciton-polaritons in semiconductor microcavities have attracted a great deal of interest as a driven-dissipative quantum fluid. These systems offer themselves as a versatile platform for performing Hamiltonian simulations with light, as well as for experimentally realizing nontrivial out-of-equilibrium phase transitions. In addition, polaritons exhibit a sizeable mutual interaction strength that opens up a whole range of possibilities in the context of quantum state generation. While squeezed light emission from polaritons has been reported previously, the granular nature of polaritons has not been observed to date. The latter capability is particularly attractive for realizing strongly correlated many-body quantum states of light on scalable arrays of coupled cavities. Here we demonstrate that by optically confining polaritons to a very small effective mode volume, one can reach the weak blockade regime, in which the nonlinearity turns strong enough to become significant at the few particle level, and thus produce a non-negligible antibunching in the emitted photons statistics. Our results act as a door opener for accessing the newly emerging field of quantum polaritonics, and as a proof of principle that optically confined exciton-polaritons can be considered as a realistic, new strategy to generate single photons., Comment: 12 pages, 10 figures

Published
2017
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25. Klein tunneling in driven-dissipative photonic graphene

Author

Ozawa, Tomoki, Amo, Alberto, Bloch, Jacqueline, and Carusotto, Iacopo

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We theoretically investigate Klein tunneling processes in photonic artificial graphene. Klein tunneling is a phenomenon in which a particle with Dirac dispersion going through a potential step shows a characteristic angle- and energy-dependent transmission. We consider a generic photonic system consisting of a honeycomb-shaped array of sites with losses, illuminated by coherent monochromatic light. We show how the transmission and reflection coefficients can be obtained from the steady-state field profile of the driven-dissipative system. Despite the presence of photonic losses, we recover the main scattering features predicted by the general theory of Klein tunneling. Signatures of negative refraction and the orientation dependence of the intervalley scattering are also highlighted. Our results will stimulate the experimental study of intricate transport phenomena using driven-dissipative photonic simulators., Comment: 11 pages, 8 figures

Published
2017
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26. Orbital edge states in a photonic honeycomb lattice

Author

Milićević, Marijana, Ozawa, Tomoki, Montambaux, Gilles, Carusotto, Iacopo, Galopin, Elisabeth, Lemaître, Aristide, Gratiet, Luc Le, Sagnes, Isabelle, Bloch, Jacqueline, and Amo, Alberto

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Physics - Optics
Abstract

We experimentally reveal the emergence of edge states in a photonic lattice with orbital bands. We use a two-dimensional honeycomb lattice of coupled micropillars whose bulk spectrum shows four gapless bands arising from the coupling of $p$-like photonic orbitals. We observe zero-energy edge states whose topological origin is similar to that of conventional edge states in graphene. Additionally, we report novel dispersive edge states that emerge not only in zigzag and bearded terminations, but also in armchair edges. The observations are reproduced by tight-binding and analytical calculations. Our work shows the potentiality of coupled micropillars in elucidating some of the electronic properties of emergent 2D materials with orbital bands.

Published
2016
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27. Phase-controlled bistability of a dark soliton train in a polariton fluid

Author

Goblot, Valentin, Nguyen, Hai Son, Carusotto, Iacopo, Galopin, Elisabeth, Lemaître, Aristide, Sagnes, Isabelle, Amo, Alberto, and Bloch, Jacqueline

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Physics - Optics
Abstract

We use a one-dimensional polariton fluid in a semiconductor microcavity to explore the rich nonlinear dynamics of counter-propagating interacting Bose fluids. The intrinsically driven-dissipative nature of the polariton fluid allows to use resonant pumping to impose a phase twist across the fluid. When the polariton-polariton interaction energy becomes comparable to their kinetic energy, linear interference fringes transform into a train of solitons. A novel type of bistable behavior controlled by the phase twist across the fluid is experimentally evidenced., Comment: 5 pages Main + 4 pages Supplementary, 8 figures

Published
2016
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28. Theoretical study of stimulated and spontaneous Hawking effects from an acoustic black hole in a hydrodynamically flowing fluid of light

Author

Grisins, Pjotrs, Nguyen, Hai Son, Bloch, Jacqueline, Amo, Alberto, and Carusotto, Iacopo

Subjects
Condensed Matter - Quantum Gases
Abstract

We propose an experiment to detect and characterize the analog Hawking radiation in an analog model of gravity consisting of a flowing exciton-polariton condensate. Under a suitably designed coherent pump configuration, the condensate features an acoustic event horizon for sound waves that at the semiclassical level is equivalent to an astrophysical black hole horizon. We show that a continuous-wave pump-and-probe spectroscopy experiment allows to measure the analog Hawking temperature from the dependence of the stimulated Hawking effect on the pump-probe detuning. We anticipate the appearance of an emergent resonant cavity for sound waves between the pump beam and the horizon, which results in marked oscillations on top of an overall exponential frequency dependence. We finally analyze the spatial correlation function of density fluctuations and identify the hallmark features of the correlated pairs of Bogoliubov excitations created by the spontaneous Hawking process, as well as novel signatures characterizing the emergent cavity.

Published
2016
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29. Surface-enhanced gallium arsenide photonic resonator with a quality factor of six million

Author

Guha, Biswarup, Marsault, Felix, Cadiz, Fabian, Morgenroth, Laurence, Ulin, Vladimir, Berkovitz, Vladimir, Lemaître, Aristide, Gomez, Carmen, Amo, Alberto, Combrié, Sylvian, Gérard, Bruno, Leo, Giuseppe, and Favero, Ivan

Subjects
Physics - Optics
Abstract

Gallium Arsenide and related compound semiconductors lie at the heart of optoelectronics and integrated laser technologies. Shaped at the micro and nano-scale, they allow strong interaction with quantum dots and quantum wells, and promise to result in stunning devices. However gallium arsenide optical structures presently exhibit lower performances than their silicon-based counterparts, notably in nanophotonics where the surface plays a chief role. Here we report on advanced surface control of miniature gallium arsenide optical resonators, using two distinct techniques that produce permanent results. One leads to extend the lifetime of free-carriers and enhance luminescence, while the other strongly reduces surface absorption originating from mid-gap states and enables ultra-low optical dissipation devices. With such surface control, the quality factor of wavelength-sized optical disk resonators is observed to rise up to six million at telecom wavelength, greatly surpassing previous realizations and opening new prospects for Gallium Arsenide nanophotonics.

Published
2016

30. Stochastic precession of the polarization in a polariton laser

Author

Sala, Vera Giulia, Marsault, Félix, Wouters, Michiel, Galopin, Elisabeth, Sagnes, Isabelle, Lemaître, Aristide, Bloch, Jacqueline, and Amo, Alberto

Subjects
Condensed Matter - Quantum Gases, Physics - Optics
Abstract

Microcavity polaritons in the lasing regime undergo a spontaneous symmetry breaking transition resulting in coherent emission with a well defined polarization. The order parameter is thus a vector describing both the laser global phase and polarization. Using an ultrafast single-shot detection technique we show that polariton lasing in GaAs-based microcavities presents a high degree of second order coherence ($g^{(2)}(\tau=0) \approx 1$) above threshold, and that the initial polarization is stochastic, taking any possible direction in the Poincar\'e sphere (linear, elliptical or circular). Once the polarization direction is established, subsequent oscillations of the emission probability witness the presence of an intrinsic polarization splitting. Our results show the negligible role of polariton interactions in the total emission statistics and in the establishment of the initial polarization., Comment: 9 pages, 6 figures

Published
2015
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31. Realization of an all optical exciton-polariton router

Author

Marsault, Félix, Nguyen, Hai Son, Tanese, Dimitrii, Lemaître, Aristide, Galopin, Elisabeth, Sagnes, Isabelle, Amo, Alberto, and Bloch, Jacqueline

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on the experimental realization of an all optical router for exciton-polaritons. This device is based on the design proposed by H. Flayac and I.G. Savenko [APL 103, 201105 (2013)], in which a zero-dimensional island is connected through tunnel barriers to two periodically modulated wires of different periods. Selective transmission of polaritons injected in the island, into either of the two wires, is achieved by tuning the energy of the island state across the band structure of the modulated wires. We show such polariton routing using an optical control beam which blueshifts the island quantum states thanks to polariton-exciton interactions. Operation of the device is demonstrated both under cw and pulsed operation., Comment: 12 pages, 3 figures

Published
2015
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33. Quantum confinement of zero-dimensional hybrid organic-inorganic polaritons at room temperature

Author

Nguyen, Hai Son, Han, Zheng, Abdel-Baki, Katia, Lafosse, Xavier, Amo, Alberto, Lauret, Jean-Sébastien, Deleporte, Emmanuelle, Bouchoule, Sophie, and Bloch, Jacqueline

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

We report on the quantum confinement of zero-dimensional polaritons in perovskite-based microcavity at room temperature. Photoluminescence of discrete polaritonic states are observed for polariton localized in symmetric sphere-like defects which are spontaneously nucleated on the top dielectric Bragg mirror. The linewidth of these confined states are found much sharper (almost one order of magnitude) than that of photonic modes in the perovskite planar microcavity. Our results show the possibility to study organic-inorganic cavity polariton in confined microstructure and suggest a fabrication method to realize integrated polaritonic devices operating at room temperature.

Published
2014
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34. Polaritonic XY-Ising machine

Author

Kalinin Kirill P., Amo Alberto, Bloch Jacqueline, and Berloff Natalia G.

Subjects
analogue computing machine, exciton-polaritons, ising hamiltonian, polaritonic xy-ising machine, xy hamiltonian, unconventional computing, Physics, QC1-999
Abstract

Gain-dissipative systems of various physical origin have recently shown the ability to act as analogue minimisers of hard combinatorial optimisation problems. Whether or not these proposals will lead to any advantage in performance over the classical computations depends on the ability to establish controllable couplings for sufficiently dense short- and long-range interactions between the spins. Here, we propose a polaritonic XY-Ising machine based on a network of geometrically isolated polariton condensates capable of minimising discrete and continuous spin Hamiltonians. We elucidate the performance of the proposed computing platform for two types of couplings: relative and absolute. The interactions between the network nodes might be controlled by redirecting the emission between the condensates or by sending the phase information between nodes using resonant excitation. We discuss the conditions under which the proposed machine leads to a pure polariton simulator with pre-programmed couplings or results in a hybrid classical polariton simulator. We argue that the proposed architecture for the remote coupling control offers an improvement over geometrically coupled condensates in both accuracy and stability as well as increases versatility, range, and connectivity of spin Hamiltonians that can be simulated with polariton networks.

Published
2020
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35. Active topological photonics

Author

Ota Yasutomo, Takata Kenta, Ozawa Tomoki, Amo Alberto, Jia Zhetao, Kante Boubacar, Notomi Masaya, Arakawa Yasuhiko, and Iwamoto Satoshi

Subjects
topological physics, nanophotonics, semiconductor lasers, microcavity lasers, photonic crystals, non-hermitian photonics, Physics, QC1-999
Abstract

Topological photonics emerged as a novel route to engineer the flow of light. Topologically protected photonic edge modes, which are supported at the perimeters of topologically nontrivial insulating bulk structures, are of particular interest as they may enable low-loss optical waveguides immune to structural disorder. Very recently, there has been a sharp rise of interest in introducing gain materials into such topological photonic structures, primarily aiming at revolutionizing semiconductor lasers with the aid of physical mechanisms existing in topological physics. Examples of remarkable realizations are topological lasers with unidirectional light output under time-reversal symmetry breaking and topologically protected polariton and micro/nanocavity lasers. Moreover, the introduction of gain and loss provides a fascinating playground to explore novel topological phases, which are in close relevance to non-Hermitian and parity-time symmetric quantum physics and are, in general, difficult to access using fermionic condensed matter systems. Here, we review the cutting-edge research on active topological photonics, in which optical gain plays a pivotal role. We discuss recent realizations of topological lasers of various kinds, together with the underlying physics explaining the emergence of topological edge modes. In such demonstrations, the optical modes of the topological lasers are determined by the dielectric structures and support lasing oscillation with the help of optical gain. We also address recent research on topological photonic systems in which gain and loss, themselves, essentially influence topological properties of the bulk systems. We believe that active topological photonics provides powerful means to advance micro/nanophotonics systems for diverse applications and topological physics, itself, as well.

Published
2020
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37. Fractal energy spectrum of a polariton gas in a Fibonacci quasi-periodic potential

Author

Tanese, Dimitrii, Gurevich, Evgeni, Baboux, Florent, Jacqmin, Thibaut, Lemaître, Aristide, Galopin, Elisabeth, Sagnes, Isabelle, Amo, Alberto, Bloch, Jacqueline, and Akkermans, Eric

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter
Abstract

We report on the study of a polariton gas confined in a quasi-periodic one dimensional cavity, described by a Fibonacci sequence. Imaging the polariton modes both in real and reciprocal space, we observe features characteristic of their fractal energy spectrum such as the opening of mini-gaps obeying the gap labeling theorem and log-periodic oscillations of the integrated density of states. These observations are accurately reproduced solving an effective 1D Schr\"{o}dinger equation, illustrating the potential of cavity polaritons as a quantum simulator in complex topological geometries., Comment: 10 pages, 8 figures, includes Supplementary Information

Published
2013
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38. Direct observation of Dirac cones and a flatband in a honeycomb lattice for polaritons

Author

Jacqmin, Thibaut, Carusotto, Iacopo, Sagnes, Isabelle, Abbarchi, Marco, Solnyshkov, Dmitry, Malpuech, Guillaume, Galopin, Elisabeth, Lemaître, Aristide, Bloch, Jacqueline, and Amo, Alberto

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Two-dimensional lattices of coupled micropillars etched in a planar semiconductor microcavity offer a workbench to engineer the band structure of polaritons. We report experimental studies of honeycomb lattices where the polariton low-energy dispersion is analogous to that of electrons in graphene. Using energy-resolved photoluminescence we directly observe Dirac cones, around which the dynamics of polaritons is described by the Dirac equation for massless particles. At higher energies, we observe p orbital bands, one of them with the nondispersive character of a flatband. The realization of this structure which holds massless, massive and infinitely massive particles opens the route towards studies of the interplay of dispersion, interactions, and frustration in a novel and controlled environment.

Published
2013
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39. Realization of a double barrier resonant tunneling diode for cavity polaritons

Author

Nguyen, Hai Son, Vishnevsky, Dmitry, Sturm, Chris, Tanese, Dimitrii, Solnyshkov, Dmitry, Galopin, Elisabeth, Lemaître, Aristide, Sagnes, Isabelle, Amo, Alberto, Malpuech, Guillaume, and Bloch, Jacqueline

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on the realization of a double barrier resonant tunneling diode for cavity polaritons, by lateral patterning of a one-dimensional cavity. Sharp transmission resonances are demonstrated when sending a polariton flow onto the device. We use a non-resonant beam can be used as an optical gate and control the device transmission. Finally we evidence distortion of the transmission profile when going to the high density regime, signature of polariton-polariton interactions., Comment: 5 pages, 4 figures

Published
2013
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40. Polariton condensation in photonic molecules

Author

Galbiati, Marta, Ferrier, Lydie, Solnyshkov, Dmitry D., Tanese, Dimitrii, Wertz, Esther, Amo, Alberto, Senellart, Pascale, Sagnes, Isabelle, Lemaitre, Aristide, Galopin, Elisabeth, Malpuech, Guillaume, and Bloch, Jacqueline

Subjects
Condensed Matter - Other Condensed Matter, Condensed Matter - Quantum Gases
Abstract

We report on polariton condensation in photonic molecules formed by two coupled micropillars. We show that the condensation process is strongly affected by the interaction with the cloud of uncondensed excitons. Depending on the spatial position of these excitons within the molecule, condensation can be triggered on both binding and anti-binding polariton states of the molecule, on a metastable state or a total transfer of the condensate into one of the micropillars can be obtained. Our results highlight the crucial role played by relaxation kinetics in the condensation process., Comment: 5 pages, 4 figures, supplementary information

Published
2011
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41. Backscattering suppression in supersonic 1D polariton condensates

Author

Tanese, Dimitrii, Solnyshkov, Dmitry, Amo, Alberto, Ferrier, Lydie, Bernet-Rolland, Emmanuel, Wertz, Esther, Sagnes, Isabelle, Lemaitre, Aristide, Senellart, Pascale, Malpuech, Guillaume, and Bloch, Jacqueline

Subjects
Condensed Matter - Quantum Gases, Condensed Matter - Other Condensed Matter
Abstract

We investigate the effects of disorder on the propagation of one-dimensional polariton condensates in semiconductor microcavities. We observe a strong suppression of the backscattering produced by the imperfections of the structure when increasing the condensate density. This suppression occurs in the supersonic regime and is simultaneous to the onset of parametric instabilities which enable the "hopping" of the condensate through the disorder. Our results evidence a new mechanism for the frictionless flow of polaritons at high speeds., Comment: 5 pages, 3 figures

Published
2011
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43. THz topological Waveguides in 600 GHz frequency Region

Author

Mohammed, Abdu Subahan, primary, Lebouvier, Edouard, additional, Lévêque, Gaëtan, additional, Pennec, Yan, additional, Faucher, Marc, additional, Amo, Alberto, additional, Szriftgiser, Pascal, additional, and Ducournau, Guillaume, additional

Published
2023
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48. Liquidación de sociedad de gananciales y adjudicación de herencia

Author

Cubero Amo, Alberto, Mateo Sanz, Jacobo Bernardo, Universidad de Valladolid. Facultad de Derecho, Cubero Amo, Alberto, Mateo Sanz, Jacobo Bernardo, and Universidad de Valladolid. Facultad de Derecho

Abstract

Como consecuencia del fallecimiento de D. Miguel se produce la división y posterior adjudicación de los bienes que conforman el caudal relicto del causante entre los herederos. Sin embargo, antes de llevar a cabo tales operaciones particionales, es necesario liquidar la sociedad legal de gananciales existente como consecuencia del matrimonio vigente hasta la defunción de D. Miguel. El presente dictamen se centra en la cautela socini, una figura utilizada frecuentemente por el testador con el fin de proteger y reforzar los derechos hereditarios del cónyuge supérstite. No obstante, ha generado polémica y controversia por entender que se grava la legítima de los herederos. A pesar de ello, esta figura ha sido admitida doctrinal y jurisprudencialmente., Because of Mr. Miguel’s death, the division and subsequent distribution of the inheritance assets among the heirs occurred. However, before carrying out such partitioning operations, it is necessary to liquidate the community property existing as a result of the current marriage until the death of Mr. Miguel. This opinion focuses on the cautela socini, a figure frequently used by the testator in order to protect and reinforce the inheritance rights of the surviving spouse. Nevertheless, it has generated controversy because it is understood that the heirs legitimacy is encumbered. In spite of that, this figure has been doctrinally and jurisprudentially admitted., Departamento de Derecho Civil

Published
2023

49. Gastrosquisis: manejo enfermero prenatal y posnatal. Revisión sistemática.

Author

Sánchez del Amo, Alberto, Carnicero Gila, Estela María, Universidad de Valladolid. Facultad de Enfermería de Valladolid, Sánchez del Amo, Alberto, Carnicero Gila, Estela María, and Universidad de Valladolid. Facultad de Enfermería de Valladolid

Abstract

La gastrosquisis es un defecto congénito de la pared abdominal, que conlleva la evisceración intestinal a través de un orificio paraumbilical derecho. Su prevalencia a nivel mundial se está incrementando y está relacionada con factores de riesgo multifactoriales. Se beneficia de un enfoque de atención multidisciplinar coordinado y requiere de grandes conocimientos para su manejo., Grado en Enfermería

Published
2023

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