Your search keyword '"Szameit, A."' showing total 2,142 results

1. Eigenmodes of latent-symmetric quantum photonic networks

Author

Himmel, Jonas, Ehrhardt, Max, Heinrich, Matthias, Röntgen, Malte, Szameit, Alexander, and Wolterink, Tom A. W.

Subjects

Physics - Optics, Quantum Physics

Abstract

We investigate the impact of latent symmetries on the dynamics of photonic systems and their eigenmodes. Residing solely within the eigenspectral domain, latent symmetries are not visible in real space, yet promise intriguing new ways to engineer the functionality of photonic systems. We study the eigenmodes of a 9-site latent-symmetric photonic network and find that an anti-symmetric input state is fundamentally precluded from populating so-called singlet sites. Furthermore, arbitrary extensions of the system at these sites do not break its latent symmetry. Therefore anti-symmetric excitations cannot leave the initial system, which can be leveraged e.g. for the storage of information. This holds true for both single-photon states, or classical light, as well as both distinguishable and indistinguishable two-photon quantum states. Latent symmetries introduce a powerful new set of tools to the design of systems with desired functionality on any nanophotonic platform, paving the way for applications in photonic information processing., Comment: 10 pages, 4 figures

Published

2025

2. State Transfer in Latent-Symmetric Networks

Author

Himmel, Jonas, Ehrhardt, Max, Heinrich, Matthias, Weidemann, Sebastian, Wolterink, Tom A. W., Röntgen, Malte, Schmelcher, Peter, and Szameit, Alexander

Subjects

Quantum Physics, Physics - Optics

Abstract

The transport of quantum states is a crucial aspect of information processing systems, facilitating operations such as quantum key distribution and inter-component communication within quantum computers. Most quantum networks rely on symmetries to achieve an efficient state transfer. A straightforward way to design such networks is to use spatial symmetries, which severely limits the design space. Our work takes a novel approach to designing photonic networks that do not exhibit any conventional spatial symmetries, yet nevertheless support an efficient transfer of quantum states. Paradoxically, while a perfect transfer efficiency is technically unattainable in these networks, a fidelity arbitrarily close to unity is always reached within a finite time of evolution. Key to this approach are so-called latent, or 'hidden', symmetries, which are embodied in the spectral properties of the network. Latent symmetries substantially expand the design space of quantum networks and hold significant potential for applications in quantum cryptography and secure state transfer. We experimentally realize such a nine-site latent-symmetric network and successfully observe state transfer between two sites with a measured fidelity of 75%. Furthermore, by launching a two-photon state, we show that quantum interference is preserved by the network. This demonstrates that the latent symmetries enable efficient quantum state transfer, while offering greater flexibility in designing quantum networks., Comment: 14 pages, 5 figures; Update: inserted arXiv identifier to related reference

Published

2025

3. Crossing exceptional points in non-Hermitian quantum systems

Author

Klauck, Friederike U. J., Heinrich, Matthias, Szameit, Alexander, and Wolterink, Tom A. W.

Subjects

Quantum Physics, Physics - Optics

Abstract

Exceptional points facilitate peculiar dynamics in non-Hermitian systems. Yet, in photonics, they have mainly been studied in the classical realm. In this work, we reveal the behavior of two-photon quantum states in non-Hermitian systems across the exceptional point. We probe the lossy directional coupler with an indistinguishable two-photon input state and observe distinct changes of the quantum correlations at the output as the system undergoes spontaneous breaking of parity-time symmetry. Moreover, we demonstrate a switching in the quantum interference of photons directly at the exceptional point, where Hong-Ou-Mandel dips are transformed into peaks by a change of basis. These results show that quantum interference and exceptional points are linked in curious ways that can now be further explored., Comment: 12 pages, 4 figures

Published

2024

4. Topological Edge State Nucleation in Frequency Space and its Realization with Floquet Electrical Circuits

Author

Stegmaier, Alexander, Fritzsche, Alexander, Sorbello, Riccardo, Greiter, Martin, Brand, Hauke, Barko, Christine, Hofer, Maximilian, Schwingenschlögl, Udo, Moessner, Roderich, Lee, Ching Hua, Szameit, Alexander, Alu, Andrea, Kießling, Tobias, and Thomale, Ronny

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

We build Floquet-driven capactive circuit networks to realize topological states of matter in the frequency domain. We find the Floquet circuit network equations of motion to reveal a potential barrier which effectively acts as a boundary in frequency space. By implementing a Su-Shrieffer-Heeger Floquet lattice model and measuring the associated circuit Laplacian and characteristic resonances, we demonstrate how topological edge modes can nucleate at such a frequency boundary., Comment: 4 pages, 3 figures, supplement

Published

2024

5. Spacetime-topological events

Author

Feis, Joshua, Weidemann, Sebastian, Sheppard, Tom, Price, Hannah M., and Szameit, Alexander

Subjects

Physics - Optics

Abstract

Time is, figuratively and literally, becoming the new dimension for crystalline matter. As such, rapid recent progress on time-varying media gave rise to the notion of temporal and spatiotemporal crystals. Fundamentally rethinking the role of time, which, in contrast to space exhibits a unique unidirectionality often referred to as the arrow of time, promises a new dimension also for topological physics. Here, we enter the new realm of time and spacetime topology: Firstly, we implement a time-topological time interface state. Secondly, we propose and observe a spacetime-topological event and demonstrate unique features like its limited collapse under disorder and causality-suppressed coupling. The new paradigms of time and spacetime topology unveil a distinctive role of causality and non-Hermiticity in topology and pave the way towards topological spatiotemporal wave control with unique robustness.

Published

2024

6. Observation of Joule–Thomson photon-gas expansion

Author

Kirsch, Marco S., Pyrialakos, Georgios G., Altenkirch, Richard, A. Selim, Mahmoud, Beck, Julius, Wolterink, Tom A. W., Ren, Huizhong, Jung, Pawel S., Khajavikhan, Mercedeh, Szameit, Alexander, Heinrich, Matthias, and Christodoulides, Demetrios N.

Published

2025

7. Demonstration of Lossy Linear Transformations and Two-Photon Interference on a Photonic Chip

Author

Wang, Kai, White, Simon J. U., Szameit, Alexander, Sukhorukov, Andrey A., and Solntsev, Alexander S.

Subjects

Quantum Physics, Physics - Optics

Abstract

Studying quantum correlations in the presence of loss is of critical importance for the physical modeling of real quantum systems. Here, we demonstrate the control of spatial correlations between entangled photons in a photonic chip, designed and modeled using the singular value decomposition approach. We show that engineered loss, using an auxiliary waveguide, allows one to invert the spatial statistics from bunching to antibunching. Furthermore, we study the photon statistics within the loss-emulating channel and observe photon coincidences, which may provide insights into the design of quantum photonic integrated chips., Comment: 5 pages, 4 figures

Published

2024

8. Non-adiabatic holonomies as photonic quantum gates

Author

Neef, Vera, Pinske, Julien, Wolterink, Tom A. W., Becker, Karo, Heinrich, Matthias, Scheel, Stefan, and Szameit, Alexander

Subjects

Quantum Physics, Physics - Optics

Abstract

One of the most promising nascent technologies, quantum computation faces a major challenge: The need for stable computational building blocks. We present the quantum-optical realization of non-adiabatic holonomies that can be used as single-qubit quantum gates. The hallmark topological protection of non-Abelian geometric phases reduces the need for quantum error correction on a fundamental physical level, while the inherent non-adiabaticity of the structures paves the way for unprecedented miniaturization. To demonstrate their versatility, we realize the Hadamard and Pauli-X gates, experimentally show their non-Abelian nature, and combine them into a single-qubit quantum algorithm, the PQ penny flipover. The planar geometry of such designs enables them to be substituted for the conventional directional coupler meshes currently in wide-spread use in photonic quantum architectures across all platforms.

Published

2024

9. Harnessing collective radiative phenomena on a photonic kagome lattice

Author

Salinas, Ignacio, Cornejo, Javier Cubillos, Szameit, Alexander, Solano, Pablo, and Vicencio, Rodrigo A.

Subjects

Physics - Optics, Physics - Atomic Physics, Quantum Physics

Abstract

Photonic lattices enable experimental exploration of transport and localization phenomena, two of the mayor goals in physics and technology. In particular, the optical excitation of some lattice sites which evanescently couple to a lattice array emulates radiation processes into structured reservoirs, a fundamental subject in quantum optics. Moreover, the simultaneous excitation of two sites simulates collective phenomena, leading to phase-controlled enhanced or suppressed radiation, namely super and subradiance. This work presents an experimental study of collective radiative processes on a photonic kagome lattice. A single or simultaneous -- in or out-of-phase -- excitation of the outlying sites controls the radiation dynamics. Specifically, we demonstrate a controlable transition between a fully localized profile at the two outlying sites and a completely dispersed state into the quasi-continuum. Our result presents photonic lattices as a platform to emulate and experimentally explore quantum optical phenomena in two-dimensional structured reservoirs, while harnessing such phenomena for controlling transport dynamics and implementing all-optical switching devices., Comment: 7 pages, 4 figures

Published

2023

10. Discrete nonlinear topological photonics

Author

Szameit, Alexander and Rechtsman, Mikael C.

Published

2024

11. Realizing efficient topological temporal pumping in electrical circuits

Author

Stegmaier, Alexander, Brand, Hauke, Imhof, Stefan, Fritzsche, Alexander, Helbig, Tobias, Hofmann, Tobias, Boettcher, Igor, Greiter, Martin, Lee, Ching Hua, Bahl, Gaurav, Szameit, Alexander, Kießling, Tobias, Thomale, Ronny, and Upreti, Lavi K.

Subjects

Condensed Matter - Other Condensed Matter, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

Quantized adiabatic transport can occur when a system is slowly modulated over time. In most realizations however, the efficiency of such transport is reduced by unwanted dissipation, back-scattering, and non-adiabatic effects. In this work, we realize a topological adiabatic pump in an electrical circuit network that supports remarkably stable and long-lasting pumping of a voltage signal. We further characterize the topology of our system by deducing the Chern number from the measured edge band structure. To achieve this, the experimental setup makes use of active circuit elements that act as time-variable voltage-controlled inductors., Comment: main (5 pages, 3 figures) plus supplement (8 pages, 4 figures)

Published

2023

12. Hybrid aeromaterials for enhanced and rapid volumetric photothermal response

Author

Saure, Lena M., Kohlmann, Niklas, Qiu, Haoyi, Shetty, Shwetha, Nia, Ali Shaygan, Ravishankar, Narayanan, Feng, Xinliang, Szameit, Alexander, Kienle, Lorenz, Adelung, Rainer, and Schütt, Fabian

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

Conversion of light into heat is essential for a broad range of technologies such as solar thermal heating, catalysis and desalination. Three-dimensional (3D) carbon nanomaterial-based aerogels have shown to hold great promise as photothermal transducer materials. However, till now, their light-to-heat conversion is limited by surface-near absorption, resulting in a strong heat localization only at the illuminated surface region, while most of the aerogel volume remains unused. We present an innovative fabrication concept for highly porous (>99.9%) photothermal hybrid aeromaterials, that enable an ultra-rapid and volumetric photothermal response with an enhancement by a factor of around 2.5 compared to the pristine variant. The hybrid aeromaterial is based on strongly light-scattering framework structures composed of interconnected hollow silicon dioxide (SiO${_2}$) microtubes, which are functionalized with extremely low amounts (in order of a few ${\mu}$g cm${^-}$${^3}$) of reduced graphene oxide (rGO) nanosheets, acting as photothermal agents. Tailoring the density of rGO within the framework structure enables us to control both, light scattering and light absorption, and thus the volumetric photothermal response. We further show that by rapid and repeatable gas activation these transducer materials expand the field of photothermal applications, like untethered light-powered and -controlled microfluidic pumps and soft pneumatic actuators.

Published

2023

13. Order-invariant two-photon quantum correlations in PT-symmetric interferometers

Author

Wolterink, Tom A. W., Heinrich, Matthias, Scheel, Stefan, and Szameit, Alexander

Subjects

Quantum Physics, Physics - Optics

Abstract

Multiphoton correlations in linear photonic quantum networks are governed by matrix permanents. Yet, surprisingly few systematic properties of these crucial algebraic objects are known, while their calculation is a computationally hard task. As such, predicting the overall multiphoton behavior of a network from its individual building blocks typically defies intuition. In this work we identify sequences of concatenated two-mode linear optical transformations whose two-photon behavior is invariant under reversal of the order. We experimentally verify this systematic behavior in parity-time-symmetric complex interferometer arrangements of varying composition. Our results underline new ways in which quantum correlations may be preserved in counterintuitive ways even in small-scale non-Hermitian networks., Comment: 7 pages, 4 figures

Published

2023

14. Parity–time-symmetric photonic topological insulator

Author

Fritzsche, Alexander, Biesenthal, Tobias, Maczewsky, Lukas J., Becker, Karo, Ehrhardt, Max, Heinrich, Matthias, Thomale, Ronny, Joglekar, Yogesh N., and Szameit, Alexander

Published

2024

15. Supersymmetric reshaping and higher-dimensional rearrangement of photonic lattices

Author

Wolterink, Tom A. W., Heinrich, Matthias, and Szameit, Alexander

Subjects

Physics - Optics, Quantum Physics

Abstract

Integrated Jx photonic lattices, inspired by the quantum harmonic oscillator and due to their equidistant eigenvalue spectrum, have been proven extremely useful for various applications, such as perfect imaging and coherent transfer of quantum states. However, to date their large-scale implementation remains challenging. We apply concepts from supersymmetry to construct two-dimensional (2D) systems with spectra identical to that of one-dimensional (1D) Jx lattices. While exhibiting different dynamics, these 2D systems retain the key imaging and state transfer properties of the 1D Jx lattice. Our method extends to other systems with separable spectra, facilitates experimental fabrication, and may increase robustness to fabrication imperfections in large-scale photonic circuits., Comment: 5 pages, 4 figures

Published

2022

16. Three-dimensional photonic topological insulator induced by lattice dislocations

Author

Lustig, Eran, Maczewsky, Lukas J., Beck, Julius, Biesenthal, Tobias, Heinrich, Matthias, Yang, Zhaoju, Plotnik, Yonatan, Szameit, Alexander, and Segev, Mordechai

Subjects

Physics - Optics

Abstract

The hallmark of topological insulators is the scatter-free propagation of waves in topologically protected edge channels. This transport is strictly chiral on the outer edge of the medium, and therefore capable of bypassing sharp corners and imperfections, even in the presence of substantial disorder. In photonics, two-dimensional topological edge states have been demonstrated on several different platforms, and are emerging as a promising tool for robust lasers, quantum devices, and other applications. However, three-dimensional photonic topological insulators, specifically those supporting topologically protected edge states in all 3D, have thus far remained out of experimental reach. Here, we demonstrate a three-dimensional photonic topological insulator with protected topological edge states. The topological protection is enabled by a screw dislocation. For this purpose, we utilize the concept of synthetic dimensions in a 2D photonic waveguide array by introducing an additional modal dimension to transform the system into a 3D photonic topological insulator. The lattice dislocation endows the system with edge states propagating along three-dimensional trajectories, with topological protection akin to strong photonic topological insulators. Our work paves the way for utilizing three-dimensional topology in photonic science and technology.

Published

2022

17. Exploring new states of matter with a photonic emulator

Author

Karbstein, Felix, Stützer, Simon, Gies, Holger, and Szameit, Alexander

Subjects

Physics - Optics, High Energy Physics - Phenomenology, Quantum Physics

Abstract

We implement the equation of motion of the large-N Gross-Neveu model from strong interaction physics in photonic waveguide arrays and study one of its paradigmatic multi-fermion bound state solutions in an optical experiment. The present study constitutes an important first step towards waveguide-based simulations of phenomena relevant for high-energy physics.

Published

2022

18. Bimorphic Floquet Topological Insulators

Author

Pyrialakos, Georgios G., Beck, Julius, Heinrich, Matthias, Maczewsky, Lukas J., Kantartzis, Nikolaos V., Khajavikhan, Mercedeh, Szameit, Alexander, and Christodoulides, Demetrios N.

Subjects

Physics - Optics

Abstract

Topological theories have established a new set of rules that govern the transport properties in a wide variety of wave-mechanical settings. In a marked departure from the established approaches that induce Floquet topological phases by specifically tailored discrete coupling protocols or helical lattice motions, we introduce a new class of bimorphic Floquet topological insulators that leverage connective chains with periodically modulated on-site potentials to unlock new topological features in the system. In exploring a 'chain-driven' generalization of the archetypical Floquet honeycomb lattice, we identify a rich phase structure that can host multiple non-trivial topological phases associated simultaneously with both Chern-type and anomalous chiral states. Experiments carried out in photonic waveguide lattices reveal a unique and strongly confined helical edge state that, owing to its origin in bulk flat bands, can be set into motion in a topologically protected fashion, or halted at will, without compromising its adherence to individual lattice sites., Comment: 17 pages, 7 figures

Published

2022

19. Populating and probing protected edge states through topology-entailed trivial states

Author

Piccioli, Francesco S., Kremer, Mark, Ehrhardt, Max, Maczewsky, Lukas J., Schmitt, Nora, Heinrich, Matthias, Carusotto, Iacopo, and Szameit, Alexander

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Topological insulators enable non-reciprocal light propagation that is insensitive to disorder and imperfections. Yet, despite considerable attention from the photonics community and beyond, the very feature that has inspired numerous proposals for applications of topological transport also turns out to be one of the main stumbling blocks for practical implementations: Accessing topologically protected states is generally assumed to require their protection to be lifted. We overcome this limitation by topology-entailed trivial (TET) states that arise from the hybridization of counter-propagating interface states. We demonstrate selective injection and extraction of light into topological states as well as long-range coherent light exchange between spatially separated topological channels. Our results highlight the potential of TET states as protection-preserving paradigm to manipulate the flow of light in topological platforms., Comment: Main text: 14 pages, 4 figures Supplementary Informations: 8 pages, 4 figures

Published

2022

20. 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

21. Topologically protected frequency control of broadband signals in dynamically modulated waveguide arrays

Author

Piccioli, Francesco S., Szameit, Alexander, and Carusotto, Iacopo

Subjects

Physics - Optics

Abstract

We theoretically propose a synthetic frequency dimension scheme to control the spectrum of a light beam propagating through an array of evanescently coupled waveguides modulated in time by a propagating sound wave via the acousto-optical effect. Configurations are identified where the emerging two-dimensional synthetic space-frequency lattice displays a non-trivial topological band structure. The corresponding chiral edge states can be exploited to manipulate the frequency spectrum of an incident beam in a robust way. In contrast to previous works, our proposal is not based on discrete high-Q cavity modes, which paves the way to the manipulation of broadband signals., Comment: 23 pages, 6 figures

Published

2021

22. Floquet Edge Multicolor Solitons

Author

Ivanov, Sergey K., Kartashov, Yaroslav V., Szameit, Alexander, Torner, Lluis, and Konotop, Vladimir V.

Subjects

Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

Topological insulators are unique physical structures that are insulators in their bulk, but support currents at their edges which can be unidirectional and topologically protected from scattering on disorder and inhomogeneities. Photonic topological insulators can be crafted in materials that exhibit a strong nonlinear response, thus opening the door to the exploration of the interplay between nonlinearity and topological effects. Among the fascinating new phenomena arising from this interplay is the formation of topological edge solitons -- hybrid asymmetric states localized across and along the interface due to different physical mechanisms. Such solitons have so far been studied only in materials with Kerr-type, or cubic, nonlinearity. Here the first example of the topological edge soliton supported by parametric interactions in $\chi^{(2)}$ nonlinear media is presented. Such solitons exist in Floquet topological insulators realized in arrays of helical waveguides made of a phase-matchable $\chi^{(2)}$ material. Floquet edge solitons bifurcate from topological edge states in the spectrum of the fundamental frequency wave and remain localized over propagation distances drastically exceeding the helix period, while travelling along the edge of the structure. A theory of such states is developed. It is shown that multicolor solitons in a Floquet system exists in the vicinity of (formally infinite) set of linear resonances determined by the Floquet phase matching conditions. Away from resonance, soliton envelopes can be described by a period-averaged single nonlinear Schr\"odinger equation with an effective cubic nonlinear coefficient whose magnitude and sign depend on the overall phase-mismatch between the fundamental frequency and second harmonic waves.

Published

2021

23. Theory of Topological Corner State Laser in Kagome Waveguide Arrays

Author

Zhong, Hua, Kartashov, Yaroslav V., Szameit, Alexander, Li, Yongdong, Liu, Chunliang, and Zhang, Yiqi

Subjects

Physics - Optics

Abstract

In comparison with conventional lasers, topological lasers are more robust and can be immune to disorder or de-fects if lasing occurs in topologically protected states. Previously reported topological lasers were almost exclu-sively based on the first-order photonic topological insulators. Here, we show that lasing can be achieved in the zero-dimensional corner state in a second-order photonic topological insulator, which is based on Kagome wave-guide array with a rhombic configuration. If gain is present in the corner of the structure, where topological corner state resides, stable lasing in this state is achieved, with lowest possible threshold, in the presence of uniform loss-es and two-photon absorption. When gain acts in other corners of the structure, lasing may occur in edge or bulk states, but it requires substantially larger thresholds and transition to stable lasing occurs over much larger propa-gation distances, sometimes due to instabilities, which are absent for lasing in corner states. We find that increasing two-photon absorption generally plays strong stabilizing action for nonlinear lasing states. The transition to stable lasing stimulated by noisy inputs is illustrated. Our work demonstrates the realistic setting for corner state laser based on higher-order topological insulator realised with waveguide arrays., Comment: 20 pages

Published

2021

24. Observation-dependent suppression and enhancement of two-photon coincidences by tailored losses

Author

Ehrhardt, Max, Heinrich, Matthias, and Szameit, Alexander

Subjects

Quantum Physics

Abstract

The uncanny ability of multiple particles to interfere with one another is one of the core principles of quantum mechanics, and serves as foundation for quantum information processing. In particular, the interplay of constructive and destructive interference with the characteristic exchange statistics of indistinguishable particles give rise to the Hong-Ou-Mandel (HOM) effect, where the bunching of bosons can lead to a perfect suppression of two-particle coincidences between the output ports of a balanced beam splitter. Conversely, in the case of two fermions, anti-bunching can systematically enhance these coincidences up to twice the baseline value of distinguishable particles. As such, the respective emergence of dips or peaks in the HOM experiment may at first glance appear to be indicative of the bosonic/fermionic nature of the incident particles. In this work, we demonstrate experimentally that the two-particle coincidence statistics of two bosons can instead be seamlessly tuned from the expected case of suppression to substantial enhancement by an appropriate choice of the observation basis. To this end, our photonic setting leverages birefringent polarization couplers to selectively introduce dissipation in the photons polarization degree of freedom. Notably, the mechanism underpinning this this highly unusual behaviour does not act on the individual phases accumulated by pairs of particles along specific paths, but instead allows them to jointly evade losses, while indistinguishable photons are prevented from being simultaneously detected in orthogonal modes. Our findings reveal a new approach to harnessing non-Hermitian settings for the manipulation of multi-particle quantum states and as functional elements in quantum simulation and information processing.

Published

2021

25. Nonlinear second-order photonic topological insulators

Author

Kirsch, Marco S., Zhang, Yiqi, Kremer, Mark, Maczewsky, Lukas J., Ivanov, Sergey K., Kartashov, Yaroslav V., Torner, Lluis, Bauer, Dieter, Szameit, Alexander, and Heinrich, Matthias

Subjects

Physics - Optics

Abstract

Higher-order topological insulators (HOTI) are a novel topological phase beyond the framework of the conventional bulk-boundary correspondence. In these peculiar systems, the topologically nontrivial boundary modes are characterized by a co-dimension of at least two. Despite several promising preliminary considerations regarding the impact of nonlinearity in such systems, the flourishing field of experimental HOTI research has thus far been confined to the linear evolution of topological states. As such, the observation of the interplay between nonlinearity and the dynamics of higher-order topological phases in conservative systems remains elusive. In our work, we experimentally demonstrate nonlinear higher-order topological corner states. Our photonic platform enables us to observe nonlinear topological corner states as well as the formation of solitons in such topological structures. Our work paves the way towards the exploration of topological properties of matter in the nonlinear regime, and may herald a new class of compact devices that harnesses the intriguing features of topology in an on-demand fashion.

Published

2021

26. Towards probing for hypercomplex quantum mechanics in a waveguide interferometer

Author

Gstir, Sebastian, Chan, Edmond, Eichelkraut, Toni, Szameit, Alexander, Keil, Robert, and Weihs, Gregor

Subjects

Quantum Physics, Physics - Optics

Abstract

We experimentally investigate the suitability of a multi-path waveguide interferometer with mechanical shutters for performing a test for hypercomplex quantum mechanics. Probing the interferometer with coherent light we systematically analyse the influence of experimental imperfections that could lead to a false-positive test result. In particular, we analyse the effects of detector nonlinearity, input-power and phase fluctuations on different timescales, closed-state transmissivity of shutters and crosstalk between different interferometer paths. In our experiment, a seemingly small shutter transmissivity in the order of about $2 \times 10^{-4}$ is the main source of systematic error, which suggests that this is a key imperfection to monitor and mitigate in future experiments., Comment: 23 pages, 7 figures

Published

2021

27. Photonic Topological Anderson Insulators

Author

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

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, 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

2021

28. Topological dipole Floquet solitons

Author

Ivanov, Sergey K., Kartashov, Yaroslav V., Heinrich, Matthias, Szameit, Alexander, Torner, Lluis, and Konotop, Vladimir V.

Subjects

Nonlinear Sciences - Pattern Formation and Solitons, Condensed Matter - Quantum Gases, Physics - Optics

Abstract

We theoretically introduce a new type of topological dipole solitons propagating in a Floquet topological insulator based on a kagome array of helical waveguides. Such solitons bifurcate from two edge states belonging to different topological gaps and have bright envelopes of different symmetries: fundamental for one component, and dipole for the other. The formation of dipole solitons is enabled by unique spectral features of the kagome array which allow the simultaneous coexistence of two topological edge states from different gaps at the same boundary. Notably, these states have equal and nearly vanishing group velocities as well as the same sign of the effective dispersion coefficients. We derive envelope equations describing components of dipole solitons and demonstrate in full continuous simulations that such states indeed can survive over hundreds of helix periods without any noticeable radiation into the bulk., Comment: 13 pages, 6 figures, to appear in Physical Review A

Published

2021

29. Tracing Information Flow from Open Quantum Systems

Author

Dziewior, Jan, Ruscio, Leonardo, Knips, Lukas, Mayer, Eric, Szameit, Alexander, and Meinecke, Jasmin D. A.

Subjects

Quantum Physics

Abstract

Open quantum systems are highly relevant, both for practical applications as well as for fundamental questions about the nature of information and its transfer, encompassing for example decoherence and memory effects. Quantum mechanics introduces additional complexity to the transfer of information, e.g., storage of information in non-classical correlations. Yet, some of these aspects tend to be neglected by the usual framework of open system research. In this work we use photons in a waveguide array to implement a quantum simulation of the coupling of a qubit with a low-dimensional discrete environment. Using the trace distance between quantum states as a measure of information, we analyze different types of information transfer. Extending the usual perspective which is focused on the system alone, we also investigate the presence of information in the environment., Comment: 7 pages, 4 figures

Published

2021

30. Symmetry allows for distinguishability in totally destructive many-particle interference

Author

Münzberg, Julian, Dittel, Christoph, Lebugle, Maxime, Buchleitner, Andreas, Szameit, Alexander, Weihs, Gregor, and Keil, Robert

Subjects

Quantum Physics, Physics - Optics

Abstract

We investigate, in a four photon interference experiment in a laser-written waveguide structure, how symmetries control the suppression of many-body output events of a $J_x$ unitary. We show that totally destructive interference does not require mutual indistinguishability between all, but only between symmetrically paired particles, in agreement with recent theoretical predictions. The outcome of the experiment is well described by a quantitative simulation which accounts for higher order emission of the photon source, imbalances in the scattering network, partial distinguishability, and photon loss., Comment: 14 pages, 7 figures

Published

2021

31. Theory of nonlinear corner states in photonic fractal lattices

Author

Ren Boquan, Kartashov Yaroslav V., Maczewsky Lukas J., Kirsch Marco S., Wang Hongguang, Szameit Alexander, Heinrich Matthias, and Zhang Yiqi

Subjects

higher-order topological insulator, fractal lattice, corner state soliton, Physics, QC1-999

Abstract

We study linear and nonlinear higher-order topological insulators (HOTIs) based on waveguide arrays arranged into Sierpiński gasket and Sierpiński carpet structures, both of which have non-integer effective Hausdorff dimensionality. Such fractal structures possess different discrete rotational symmetries, but both lack transverse periodicity. Their characteristic feature is the existence of multiple internal edges and corners in their optical potential landscape, and the formal absence of an insulating bulk. Nevertheless, we show that a systematic geometric shift of the waveguides in the first generation of such fractal arrays, which affects the coupling strengths between sites of this building block as well as in subsequent structure generations, enables the formation of corner states of topological origin at the outer corners of the array. We find that, in contrast to HOTIs based on periodic arrays, Sierpiński gasket arrays always support topological corner states, irrespective of the direction of the shift of the waveguides, while in Sierpiński carpet structures, corner states emerge only for one direction of the waveguide shift. We also find families of corner solitons bifurcating from linear corner states of fractal structures that remain stable practically in the entire gap in which they form. These corner states can be efficiently excited by injecting Gaussian beams into the outer corner sites of the fractal arrays. Our results pave the way toward the investigation of nonlinear effects in topological insulators with non-integer dimensionality and enrich the variety of higher-order topological states.

Published

2023

32. Harnessing collective radiative phenomena on a photonic Kagome lattice

Author

Ignacio Salinas, Javier Cubillos Cornejo, Alexander Szameit, Pablo Solano, and Rodrigo A. Vicencio

Subjects

Applied optics. Photonics, TA1501-1820

Abstract

Photonic lattices enable experimental exploration of transport and localization phenomena, two of the major goals in physics and technology. In particular, the optical excitation of some lattice sites, which evanescently couple to a lattice array, emulates radiation processes in structured reservoirs, a fundamental subject in quantum optics. Moreover, the simultaneous excitation of two sites simulates collective phenomena, leading to phase-controlled enhanced or suppressed radiation, namely super- and subradiance. This work presents an experimental study of collective radiative processes on a photonic Kagome lattice. A single or simultaneous—in-phase or out-of-phase—excitation of the outlying sites controls the radiation dynamics. Specifically, we demonstrate a controllable transition between a fully localized profile at the two outlying sites and a completely dispersed state into the quasi-continuum. Our result presents photonic lattices as a platform to emulate and experimentally explore quantum optical phenomena in two-dimensional structured reservoirs, while harnessing such phenomena for controlling transport dynamics and implementing all-optical switching devices.

Published

2024

33. Topological defect engineering and PT-symmetry in non-Hermitian electrical circuits

Author

Stegmaier, Alexander, Imhof, Stefan, Helbig, Tobias, Hofmann, Tobias, Lee, Ching Hua, Kremer, Mark, Fritzsche, Alexander, Feichtner, Thorsten, Klembt, Sebastian, Höfling, Sven, Boettcher, Igor, Fulga, Ion Cosma, Schmidt, Oliver G., Greiter, Martin, Kiessling, Tobias, Szameit, Alexander, and Thomale, Ronny

Subjects

Physics - Applied Physics, Condensed Matter - Other Condensed Matter, Physics - Optics

Abstract

We employ electric circuit networks to study topological states of matter in non-Hermitian systems enriched by parity-time symmetry $\mathcal{PT}$ and chiral symmetry anti-$\mathcal{PT}$ ($\mathcal{APT}$). The topological structure manifests itself in the complex admittance bands which yields excellent measurability and signal to noise ratio. We analyze the impact of $\mathcal{PT}$ symmetric gain and loss on localized edge and defect states in a non-Hermitian Su--Schrieffer--Heeger (SSH) circuit. We realize all three symmetry phases of the system, including the $\mathcal{APT}$ symmetric regime that occurs at large gain and loss. We measure the admittance spectrum and eigenstates for arbitrary boundary conditions, which allows us to resolve not only topological edge states, but also a novel $\mathcal{PT}$ symmetric $\mathbb{Z}_2$ invariant of the bulk. We discover the distinct properties of topological edge states and defect states in the phase diagram. In the regime that is not $\mathcal{PT}$ symmetric, the topological defect state disappears and only reemerges when $\mathcal{APT}$ symmetry is reached, while the topological edge states always prevail and only experience a shift in eigenvalue. Our findings unveil a future route for topological defect engineering and tuning in non-Hermitian systems of arbitrary dimension., Comment: 4 pages, 3 figures, 6 pages supplement (separate file)

Published

2020

34. Nonlinear control of PT-symmetry and non-Hermitian topological states

Author

Xia, Shiqi, Kaltsas, Dimitrios, Song, Daohong, Komis, Ioannis, Xu, Jingjun, Szameit, Alexander, Buljan, Hrvoje, Makris, Konstantinos G., and Chen, Zhigang

Subjects

Physics - Optics

Abstract

Advances in topological photonics and non-Hermitian optics have drastically changed our perception on how interdisciplinary concepts may empower unprecedented applications. Bridging the two areas could uncover the reciprocity between topology and non-Hermiticity in complex systems. So far, such endeavors have focused mainly on linear-optics regime. Here, we establish a nonlinear non-Hermitian topological platform for control of parity-time (PT) symmetry and topological edge states. Experimentally, we demonstrate that optical nonlinearity effectively modulates the gain and loss of a topological interface waveguide in a non-Hermitian Su-Schrieffer-Heeger lattice, leading to switching between PT and non-PT-symmetric regimes accompanied by destruction and restoration of topological zero modes. Theoretically, we examine the fundamental issue of the interplay between two antagonistic effects: the sensitivity close to exceptional points and the robustness of non-Hermitian topological modes. Realizing single-channel control of global PT-symmetry via local nonlinearity may herald new possibilities for light manipulation and unconventional device applications.

Published

2020

35. Nonlinearity-induced photonic topological insulator

Author

Maczewsky, Lukas J., Heinrich, Matthias, Kremer, Mark, Ivanov, Sergey K., Ehrhardt, Max, Martinez, Franklin, Kartashov, Yaroslav V., Konotop, Vladimir V., Torner, Lluis, Bauer, Dieter, and Szameit, Alexander

Subjects

Physics - Optics

Abstract

The hallmark feature of topological insulators renders edge transport virtually impervious to scattering at defects and lattice disorder. In our work, we experimentally demonstrate a topological system, using a photonic platform, in which the very existence of the topological phase is brought about by nonlinearity. Whereas in the linear regime, the lattice structure remains topologically trivial, light beams launched above a certain power threshold drive the system into its transient topological regime, and thereby define a nonlinear unidirectional channel along its edge. Our work studies topological properties of matter in the nonlinear regime, and may pave the way towards compact devices that harness topological features in an on-demand fashion.

Published

2020

36. Transport and spectral features in non-Hermitian open systems

Author

Tzortzakakis, A. F., Makris, K. G., Szameit, A., and Economou, E. N.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

We study the transport and spectral properties of a non-Hermitian one-dimensional disordered lattice, the diagonal matrix elements of which are random complex variables taking both positive (loss) and negative (gain) imaginary values: Their distribution is either the usual rectangular one or a binary pair-correlated one possessing, in its Hermitian version, delocalized states, and unusual transport properties. Contrary to the Hermitian case, all states in our non-Hermitian system are localized. In addition, the eigenvalue spectrum, for the binary pair-correlated case, exhibits an unexpected intricate fractallike structure on the complex plane and with increasing non-Hermitian disorder, the eigenvalues tend to coalesce in particular small areas of the complex plane, a feature termed "eigenvalue condensation". Despite the strong Anderson localization of all eigenstates, the system appears to exhibit transport not by diffusion but by a new mechanism through sudden jumps between states located even at distant sites. This seems to be a general feature of open non-Hermitian random systems. The relation of our findings to recent experimental results is also discussed., Comment: 10 pages, 10 figures

Published

2020

37. Exploring complex graphs using three-dimensional quantum walks of correlated photons

Author

Ehrhardt, Max, Keil, Robert, Maczewsky, Lukas J., Dittel, Christoph, Heinrich, Matthias, and Szameit, Alexander

Subjects

Physics - Optics, Quantum Physics

Abstract

Graph representations are a powerful concept for solving complex problems across natural science, as patterns of connectivity can give rise to a multitude of emergent phenomena. Graph-based approaches have proven particularly fruitful in quantum communication and quantum search algorithms in highly branched quantum networks. Here we introduce a new paradigm for the direct experimental realization of excitation dynamics associated with three-dimensional networks by exploiting the hybrid action of spatial and polarization degrees of freedom of photon pairs in complex waveguide circuits with tailored birefringence. This novel testbed for the experimental exploration of multi-particle quantum walks on complex, highly connected graphs paves the way towards exploiting the applicative potential of fermionic dynamics in integrated quantum photonics.

Published

2020

38. Non-Hermitian Anderson Transport

Author

Weidemann, Sebastian, Kremer, Mark, Longhi, Stefano, and Szameit, Alexander

Subjects

Physics - Optics

Abstract

Andersons groundbreaking discovery that the presence of stochastic imperfections in a crystal may result in a sudden breakdown of conductivity revolutionized our understanding of disordered media. After stimulating decades of lively studies, Anderson localization has found intriguing applications in various areas of physics, such mesoscopic physics, strongly-correlated systems, light localization, cavity quantum electrodynamics, random lasers, and topological phases of matter. However, a fundamental assumption in Andersons treatment is that no energy is exchanged with the environment, in contrast to the common knowledge that every real system is subject to dissipation. Recently, a growing number of theoretical studies has addressed disordered media with dissipation. In particular it has been predicted that in such systems all eigenstates exponentially localize, similar to the original case without dissipation that Anderson considered. However, in dissipative systems an eigenstate analysis is insufficient for characterizing the transport dynamics of wave, in stark contrast to Hermitian systems, where the localization of all eigenstates necessarily suppresses transport. In our work, we show in theory and experiment that systems with dissipative disorder allow for a new type of spatial transport, despite the fact that all eigenstates are exponentially localized. This Anderson transport is characterized by super-diffusive spreading and ultra-far spatial jumps between localized states. We anticipate our findings to mark the starting point towards novel phenomena in dissipative media, which are subject to general non-Hermitian disorder.

Published

2020

39. Nontrivial coupling of light into a defect: the interplay of nonlinearity and topology

Author

Xia, Shiqi, Jukić, Dario, Wang, Nan, Smirnova, Daria, Smirnov, Lev, Tang, Liqin, Song, Daohong, Szameit, Alexander, Leykam, Daniel, Xu, Jingjun, Chen, Zhigang, and Buljan, Hrvoje

Subjects

Physics - Optics, Condensed Matter - Other Condensed Matter

Abstract

The flourishing of topological photonics in the last decade was achieved mainly due to developments in linear topological photonic structures. However, when nonlinearity is introduced, many intriguing questions arise. For example, are there universal fingerprints of underlying topology when modes are coupled by nonlinearity, and what can happen to topological invariants during nonlinear propagation? To explore these questions, here we experimentally demonstrate nonlinearity-induced coupling to topologically protected edge states using a photonic platform, and theoretically develop a general framework for interpreting the mode-coupling dynamics in nonlinear topological systems. Performed in laser-written photonic Su-Schrieffer-Heeger lattices, our experiments reveal nonlinear coupling of light into a nontrivial edge or interface defect channel otherwise not permissible due to topological protection. Our theory explains well all the observations. Furthermore, we introduce the concepts of inherited and emergent nonlinear topological phenomena, and a protocol capable of unveiling the interplay of nonlinearity and topology. These concepts are applicable for other nonlinear topological systems, either in higher dimensions or beyond our photonic platform., Comment: are welcome!

Published

2020

40. Experimental observation of Aharonov-Bohm caging using orbital angular momentum modes in optical waveguides

Author

Jörg, C., Queraltó, G., Kremer, M., Pelegrí, G., Schulz, J., Szameit, A., von Freymann, G., Mompart, J., and Ahufinger, V.

Subjects

Physics - Optics

Abstract

The discovery of artificial gauge fields, controlling the dynamics of uncharged particles that otherwise elude the influence of standard electric or magnetic fields, has revolutionized the field of quantum simulation. Hence, developing new techniques to induce those fields is essential to boost quantum simulation in photonic structures. Here, we experimentally demonstrate in a photonic lattice the generation of an artificial gauge field by modifying the input state, overcoming the need to modify the geometry along the evolution or imposing the presence of external fields. In particular, we show that an effective magnetic flux naturally appears when light beams carrying orbital angular momentum are injected into waveguide lattices with certain configurations. To demonstrate the existence of that flux, we measure the resulting Aharonov-Bohm caging effect. Therefore, we prove the possibility of switching on and off artificial gauge fields by changing the topological charge of the input state, paving the way to access different topological regimes in one single structure, which represents an important step forward for optical quantum simulation.

Published

2020

41. Bragg solitons in topological Floquet insulators

Author

Ivanov, Sergey K., Kartashov, Yaroslav V., Maczewsky, Lukas J., Szameit, Alexander, and Konotop, Vladimir V.

Subjects

Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

We consider a topological Floquet insulator consisting of two honeycomb arrays of identical waveguides having opposite helicities. The interface between the arrays supports two distinct topological edge states, which can be resonantly coupled by additional weak longitudinal refractive index modulation with a period larger than the helix period. In the presence of Kerr nonlinearity, such coupled edge states enable topological Bragg solitons. Theory and examples of such solitons are presented., Comment: 5 pages, 5 figures

Published

2020

42. Efficient Light Funneling based on the non-Hermitian Skin Effect

Author

Weidemann, Sebastian, Kremer, Mark, Helbig, Tobias, Hofmann, Tobias, Stegmaier, Alexander, Greiter, Martin, Thomale, Ronny, and Szameit, Alexander

Subjects

Physics - Optics

Abstract

In the last two decades, the ubiquitous effect of dissipation has proven to entail astonishing non-Hermitian features, rather than just being an inescapable nuisance. As an alternative route to non-Hermiticity, we tailor the anisotropy of a lattice, which constitutes an, up to now, barely exploited degree of freedom. In this case, the appearance of an interface dramatically alters the entire eigenmode spectrum, leading to the exponential localization of all modes at the interface, which goes beyond the expectations for Hermitian systems. This effect is dubbed "non-Hermitian skin effect". We experimentally demonstrate it by studying the propagation of light in a large scale photonic mesh lattice. For arbitrary excitations, we find that light is always transported to the interface, realizing a highly efficient funnel for light.

Published

2020

43. Possible link between the distribution of atomic spectral lines and the radiation-matter-equilibrium in the early universe

Author

Richardt, Tim, Heinrich, Matthias, Gräfe, Markus, and Szameit, Alexander

Subjects

Physics - General Physics

Abstract

We report on the uncanny resemblance of the global distribution of all experimentally known atomic spectral lines to the Planckian spectral distribution associated with black body radiation at a temperature of $T\approx9000\,\mathrm{K}$. This value coincides with the critical temperature of equilibrium between the respective densities of radiation and matter in the early universe.

Published

2020

44. Edge Solitons in Lieb Topological Floquet Insulators

Author

Ivanov, Sergey K., Kartashov, Yaroslav V., Maczewsky, Lukas J., Szameit, Alexander, and Konotop, Vladimir V.

Subjects

Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

We describe topological edge solitons in a continuous dislocated Lieb array of helical waveguides. The linear Floquet spectrum of this structure is characterized by the presence of two topological gaps with edge states residing in them. A focusing nonlinearity enables families of topological edge solitons bifurcating from the linear edge states. Such solitons are localized both along and across the edge of the array. Due to the non-monotonic dependence of the propagation constant of the edge states on the Bloch momentum, one can construct topological edge solitons that either propagate in different directions along the same boundary or do not move. This allows us to study collisions of edge solitons moving in the opposite directions. Such solitons always interpenetrate each other without noticeable radiative losses; however, they exhibit a spatial shift that depends on the initial phase difference., Comment: 5 pages, 5 figures

Published

2020

45. Vector Topological Edge Solitons in Floquet Insulators

Author

Ivanov, Sergey K., Kartashov, Yaroslav V., Szameit, Alexander, Torner, Lluis, and Konotop, Vladimir V.

Subjects

Physics - Optics, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

We introduce topological vector edge solitons in a Floquet insulator, consisting of two honeycomb arrays of helical waveguides with opposite directions of rotation in a focusing nonlinear optical medium. Zigzag edges of two arrays placed in contact create a zigzag-zigzag interface between two structures with different topology. A characteristic feature of such a photonic insulator is that, in the linear limit, it simultaneously supports two topologically protected chiral edge states at the interface between the two arrays. In the presence of nonlinearity, either bright or dark scalar Floquet edge soliton can bifurcate from a linear topological edge state. Such solitons are unidirectional and are localized in both directions, along the interface due to nonlinear self-action, and across the interface as being an edge state. The presence of two edge states with equal averaged group velocities enables the existence of stable topological vector edge solitons. In our case, these are nonlinearly coupled bright and dark solitons bifurcating from different branches of the topological Floquet edge states. Here we put forward a new mathematical description of scalar and vector small-amplitude Floquet envelope solitons in the above-mentioned continuous system. Importantly for the design of future photonic devices based on Floquet edge solitons, we find that the latter can be described by nonlinear Schrodinger equations for the mode envelopes obtained by averaging over one rotation period in the evolution coordinate., Comment: 12 pages, 8 figures

Published

2020

46. Quantum Random Number Generation using a Solid-State Single-Photon Source

Author

White, Simon J. U., Klauck, Friederike, Tran, Toan Trong, Schmitt, Nora, Kianinia, Mehran, Steinfurth, Andrea, Heinrich, Matthias, Toth, Milos, Szameit, Alexander, Aharonovich, Igor, and Solntsev, Alexander

Subjects

Physics - Optics, Quantum Physics

Abstract

Quantum random number generation (QRNG) harnesses the intrinsic randomness of quantum mechanical phenomena. Demonstrations of such processes have, however, been limited to probabilistic sources, for instance, spontaneous parametric down-conversion or faint lasers, which cannot be triggered deterministically. Here, we demonstrate QRNG with a quantum emitter in hexagonal boron nitride; an emerging solid-state quantum source that can generate single photons on demand and operates at room temperature. We achieve true random number generation through the measurement of single photons exiting one of four integrated photonic waveguides, and subsequently, verify the randomness of the sequences in accordance with the National Institute of Standards and Technology benchmark suite. Our results open a new avenue to the fabrication of on-chip deterministic random number generators and other solid-state-based quantum-optical devices., Comment: 5 Pages, 3 Figures

Published

2020

47. Topological state engineering via supersymmetric transformations

Author

Queralto, Gerard, Kremer, Mark, Maczewsky, Lukas J., Heinrich, Matthias, Mompart, Jordi, Ahufinger, Veronica, and Szameit, Alexander

Subjects

Physics - Optics, Quantum Physics

Abstract

The quest to explore new techniques for the manipulation of topological states simultaneously promotes a deeper understanding of topological physics, and is essential in identifying new ways to harness their unique features. Here, we examine the potential of supersymmetric (SUSY) transformations to systematically address, alter and reconfigure the topological properties of a system. To this end, we theoretically and experimentally study the changes that topologically protected states in photonic lattices undergo as SUSY transformations are applied to their host system. In particular, we show how SUSY-induced phase transitions can selectively suspend and re-establish topological protection of specific states. Furthermore, we reveal how understanding the interplay between internal symmetries and the symmetry constraints of supersymmetric transformations provides a roadmap to directly access the desirable topological properties of a system. Our findings pave the way for establishing SUSY-inspired techniques as a powerful and versatile tool for topological state engineering.

Published

2019

48. Roadmap on STIRAP applications

Author

Bergmann, Klaas, Nägerl, Hanns-Christoph, Panda, Cristian, Gabrielse, Gerald, Miloglyadov, Eduard, Quack, Martin, Seyfang, Georg, Wichmann, Gunther, Ospelkaus, Silke, Kuhn, Axel, Longhi, Stefano, Szameit, Alexander, Pirro, Philipp, Hillebrands, Burkard, Zhu, Xue-Feng, Zhu, Jie, Drewsen, Michael, Hensinger, Winfried K., Weidt, Sebastian, Halfmann, Thomas, Wang, Hailin, Paraoanu, G. S., Vitanov, Nikolay V., Mompart, J., Busch, Th., Barnum, Timothy J., Grimes, David D., Field, Robert W., Raizen, Mark G., Narevicius, Edvardas, Auzinsh, Marcis, Budker, Dmitry, Pálffy, Adriana, and Keitel, Christoph H.

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Chemical Physics

Abstract

STIRAP (Stimulated Raman Adiabatic Passage) is a powerful laser-based method, usually involving two photons, for efficient and selective transfer of population between quantum states. A particularly interesting feature is the fact that the coupling between the initial and the final quantum states is via an intermediate state even though the lifetime of the latter can be much shorter than the interaction time with the laser radiation. Nevertheless, spontaneous emission from the intermediate state is prevented by quantum interference. Maintaining the coherence between the initial and final state throughout the transfer process is crucial. STIRAP was initially developed with applications in chemical dynamics in mind. That is why the original paper of 1990 was published in The Journal of Chemical Physics. However, as of about the year 2000, the unique capabilities of STIRAP and its robustness with respect to small variations of some experimental parameters stimulated many researchers to apply the scheme in a variety of other fields of physics. The successes of these efforts are documented in this collection of articles., Comment: accepted for publication in Journal of Physics B: Atomic, Molecular and Optical Physics

Published

2019

49. Observation of bulk boundary correspondence breakdown in topolectrical circuits

Author

Helbig, Tobias, Hofmann, Tobias, Imhof, Stefan, Abdelghany, Mohamed, Kiessling, Tobias, Molenkamp, Laurens W., Lee, Ching Hua, Szameit, Alexander, Greiter, Martin, and Thomale, Ronny

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The study of the laws of nature has traditionally been pursued in the limit of isolated systems, where energy is conserved. This is not always a valid approximation, however, as the inclusion of features like gain and loss, or periodic driving, qualitatively amends these laws. A contemporary frontier of meta-material research is the challenge open systems pose to the established characterization of topological matter. There, one of the most relied upon principles is the bulk-boundary correspondence (BBC), which intimately relates the properties of the surface states to the topological classification of the bulk. The presence of gain and loss, in combination with the violation of reciprocity, has recently been predicted to affect this principle dramatically. Here, we report the experimental observation of BBC violation in a non-reciprocal topolectric circuit. The circuit admittance spectrum exhibits an unprecedented sensitivity to the presence of a boundary, displaying an extensive admittance mode localization despite a translationally invariant bulk. Intriguingly, we measure a non-local voltage response due to broken BBC. Depending on the AC current feed frequency, the voltage signal accumulates at the left or right boundary, and increases as a function of nodal distance to the current feed., Comment: 36 pages, 9 figures

Published

2019

50. Experimental realisation of $\mathcal{PT}$-symmetric flat bands

Author

Biesenthal, Tobias, Kremer, Mark, Heinrich, Matthias, and Szameit, Alexander

Subjects

Physics - Optics

Abstract

The capability to temporarily arrest the propagation of optical signals is one of the main challenges hampering the ever more widespread use of light in rapid long-distance transmission as well as all-optical on-chip signal processing or computations. To this end, flat-band structures are of particular interest, since their hallmark compact eigenstates do not only allow for the localization of wave packets, but importantly also protect their transverse profile from deterioration without the need for additional diffraction management. In this work, we experimentally demonstrate that, far from being a nuisance to be compensated, judiciously tailored loss distributions can in fact be the key ingredient in synthesizing such flat bands in non-Hermitian environments. We probe their emergence in the vicinity of an exceptional point and directly observe the associated compact localised modes that can be excited at arbitrary positions of the periodic lattice.

Published

2019