Your search keyword '"Jezek P"' showing total 296 results

1. Self-sustained Josephson dynamics and self-trapping in supersolids

Author

Alaña, Aitor, Modugno, Michele, Capuzzi, Pablo, and Jezek, D. M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We explore the self-sustained Josephson junction dynamics in dipolar supersolids, predicting the possibility of self-trapping alongside the experimentally observed Josephson oscillations [Biagioni, G. et al., Nature 629, 773 (2024)]. Using an asymmetric two-mode (ATM) model to describe a triangular dipolar supersolid, validated through Gross-Pitaevskii simulations, we demonstrate that the system's symmetry enables a consistent two-mode mapping despite the presence of seven droplets. Additionally, we show that bringing the system into rotation preserves its ability to sustain the Josephson junction dynamics across its full range, and we assess the robustness of the ATM model under these conditions., Comment: 6 pages, 4 figures; includes supplemental material

Published

2025

2. Experimental noiseless quantum amplification of coherent states of light by two-photon addition and subtraction

Author

Neset, Michal, Fadrný, Jiří, Bielak, Martin, Fiurášek, Jaromír, Ježek, Miroslav, and Bílek, Jan

Subjects

Quantum Physics

Abstract

Noiseless quantum amplifiers are probabilistic quantum devices that enhance amplitude of coherent states without adding any noise, which has far reaching applications in quantum optics and quantum information processing. Here, we report on experimental implementation of an advanced noiseless quantum amplifier for coherent states of light that is based on conditional addition of two photons followed by conditional subtraction of two photons. We comprehensively characterize the noiselessly amplified coherent states via quantum state tomography and analyze the amplification gain and noise properties of the amplifier. We observe very good agreement between the experiment and theoretical predictions. Our work reveals that sequences of multiple photon additions and subtractions represent an efficient and experimentally feasible alternative to multiplexing that was originally proposed to boost the performance of noiseless quantum amplifiers. Beyond noiseless quantum amplification, our experiment represents a significant step forward towards engineering complex quantum operations on traveling light beams by coherent combinations of various sequences of multiphoton additions and subtractions., Comment: 7 pages, 7 figures, REVTeX 4

Published

2024

3. Experimental investigation of heralded Gaussification of phase-randomized coherent states of light

Author

Dostál, Martin, Ježek, Miroslav, Fiurášek, Jaromír, and Bílek, Jan

Subjects

Quantum Physics

Abstract

Probabilistic heralded Gaussification of quantum states of light is an important ingredient of protocols for distillation of continuous variable entanglement and squeezing. An elementary step of heralded Gaussification protocol consists of interference of two copies of the state at a balanced beam splitter, followed by conditioning on outcome of a suitable Gaussian quantum measurement on one output mode. When iterated, the protocol either converges to a Gaussian state, or diverges. Here we report on experimental investigation of the convergence properties of iterative heralded Gaussification. We experimentally implement two iterations of the protocol, which requires simultaneous processing of four copies of the input state. We utilize the phase-randomized coherent states as the input states, which greatly facilitates the experiment, because these states can be generated deterministically and their mean photon number can easily be tuned. We comprehensively characterize the input and partially Gaussified states by balanced homodyne detection and quantum state tomography. Our experimental results are in good agreement with theoretical predictions and they provide new insights into the convergence properties of heralded quantum Gaussification., Comment: 18 pages, 12 figures

Published

2024

4. A many-particle bosonic quantum Maxwell demon

Author

Hloušek, Josef, Denzler, Tobias, Švarc, Vojtěch, Ježek, Miroslav, Lutz, Eric, and Filip, Radim

Subjects

Quantum Physics, Physics - Optics

Abstract

Energy extraction from a measured quantum system is a cornerstone of information thermodynamics as illustrated by Maxwell's demon. The nonequilibrium physics of many-particle systems is additionally strongly influenced by quantum statistics. We here report the first experimental realization of a quantum demon in a many-particle photonic setup made of two identical thermal light beams. We show that single-photon measurements combined with feedforward operation may deterministically increase the mean energy of one beam faster than energy fluctuations, thus improving the thermodynamic stability of the device. We moreover demonstrate that bosonic statistics can enhance the energy output above the classical limit, and further analyze the counterintuitive thermodynamics of the demon using an information-theoretic approach. Our results underscore the pivotal role of many-particle statistics for enhanced energy extraction in quantum thermodynamics., Comment: 10 pages, 7 figures

Published

2024

5. Mammals show faster recovery from capture and tagging in human-disturbed landscapes.

Author

Stiegler, Jonas, Gallagher, Cara, Hering, Robert, Müller, Thomas, Tucker, Marlee, Apollonio, Marco, Arnold, Janosch, Barker, Nancy, Barthel, Leon, Bassano, Bruno, Beest, Floris, Belant, Jerrold, Berger, Anne, Beyer, Dean, Bidner, Laura, Blake, Stephen, Börner, Konstantin, Brivio, Francesca, Brogi, Rudy, Buuveibaatar, Bayarbaatar, Cagnacci, Francesca, Dekker, Jasja, Dentinger, Jane, Duľa, Martin, Duquette, Jarred, Eccard, Jana, Evans, Meaghan, Ferguson, Adam, Fichtel, Claudia, Ford, Adam, Fowler, Nicholas, Gehr, Benedikt, Getz, Wayne, Goheen, Jacob, Goossens, Benoit, Grignolio, Stefano, Haugaard, Lars, Hauptfleisch, Morgan, Heim, Morten, Heurich, Marco, Hewison, Mark, Isbell, Lynne, Janssen, René, Jarnemo, Anders, Jeltsch, Florian, Miloš, Jezek, Kaczensky, Petra, Kamiński, Tomasz, Kappeler, Peter, Kasper, Katharina, Kautz, Todd, Kimmig, Sophia, Kjellander, Petter, Kowalczyk, Rafał, Kramer-Schadt, Stephanie, Kröschel, Max, Krop-Benesch, Anette, Linderoth, Peter, Lobas, Christoph, Lokeny, Peter, Lührs, Mia-Lana, Matsushima, Stephanie, McDonough, Molly, Melzheimer, Jörg, Morellet, Nicolas, Ngatia, Dedan, Obermair, Leopold, Olson, Kirk, Patanant, Kidan, Payne, John, Petroelje, Tyler, Pina, Manuel, Piqué, Josep, Premier, Joseph, Pufelski, Jan, Pyritz, Lennart, Ramanzin, Maurizio, Roeleke, Manuel, Rolandsen, Christer, Saïd, Sonia, Sandfort, Robin, Schmidt, Krzysztof, Schmidt, Niels, Scholz, Carolin, Schubert, Nadine, Selva, Nuria, Sergiel, Agnieszka, Serieys, Laurel, Silovský, Václav, Slotow, Rob, Sönnichsen, Leif, Solberg, Erling, Stelvig, Mikkel, Street, Garrett, Sunde, Peter, Svoboda, Nathan, Thaker, Maria, Tomowski, Maxi, Ullmann, Wiebke, and Vanak, Abi

Subjects

Animals, Humans, Mammals, Ecosystem, Male, Female, Locomotion, Herbivory, Animals, Wild, Behavior, Animal, Species Specificity

Abstract

Wildlife tagging provides critical insights into animal movement ecology, physiology, and behavior amid global ecosystem changes. However, the stress induced by capture, handling, and tagging can impact post-release locomotion and activity and, consequently, the interpretation of study results. Here, we analyze post-tagging effects on 1585 individuals of 42 terrestrial mammal species using collar-collected GPS and accelerometer data. Species-specific displacements and overall dynamic body acceleration, as a proxy for activity, were assessed over 20 days post-release to quantify disturbance intensity, recovery duration, and speed. Differences were evaluated, considering species-specific traits and the human footprint of the study region. Over 70% of the analyzed species exhibited significant behavioral changes following collaring events. Herbivores traveled farther with variable activity reactions, while omnivores and carnivores were initially less active and mobile. Recovery duration proved brief, with alterations diminishing within 4-7 tracking days for most species. Herbivores, particularly males, showed quicker displacement recovery (4 days) but slower activity recovery (7 days). Individuals in high human footprint areas displayed faster recovery, indicating adaptation to human disturbance. Our findings emphasize the necessity of extending tracking periods beyond 1 week and particular caution in remote study areas or herbivore-focused research, specifically in smaller mammals.

Published

2024

6. Measurement-device agnostic quantum tomography

Author

Stárek, Robert, Bielak, Martin, and Ježek, Miroslav

Subjects

Quantum Physics

Abstract

Characterization of quantum states and devices is paramount to quantum science and technology. The characterization consists of individual measurements, which are required to be precisely known. A mismatch between actual and assumed constituent measurements limits the accuracy of this characterization. Here, we show that such a mismatch introduces reconstruction artifacts in quantum state tomography. We use these artifacts to detect and quantify the mismatch and gain information about the actual measurement operators. It consequently allows the mitigation of systematic errors in quantum measurement and state preparation., Comment: 6 pages, 2 figures

Published

2024

7. Experimental preparation of multiphoton-added coherent states of light

Author

Fadrný, Jiří, Neset, Michal, Bielak, Martin, Ježek, Miroslav, Bílek, Jan, and Fiurášek, Jaromír

Subjects

Quantum Physics

Abstract

Conditional addition of photons represents a crucial tool for optical quantum state engineering and it forms a fundamental building block of advanced quantum photonic devices. Here we report on experimental implementation of the conditional addition of several photons. We demonstrate the addition of one, two, and three photons to input coherent states with various amplitudes. The resulting highly nonclassical photon-added states are completely characterized with time-domain homodyne tomography, and the nonclassicality of the prepared states is witnessed by the negativity of their Wigner functions. We experimentally demonstrate that the conditional addition of photons realizes approximate noiseless quantum amplification of coherent states with sufficiently large amplitude. We also investigate certification of the stellar rank of the generated multiphoton-added coherent states, which quantifies the non-Gaussian resources required for their preparation. Our results pave the way towards the experimental realization of complex optical quantum operations based on combination of multiple photon additions and subtractions.

Published

2024

8. Phase-induced vortex pinning in rotating supersolid dipolar systems

Author

Alaña, Aitor, Modugno, Michele, Capuzzi, Pablo, and Jezek, D. M.

Subjects

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

Abstract

We analyze the pinning of vortices for a stationary rotating dipolar supersolid along the low-density paths between droplets as a function of the rotation frequency. We restrict ourselves to the stationary configurations of vortices with the same symmetry as that of the array of droplets. In particular, such an analysis clearly reveals that vortices are not only pinned at local density minima, but instead their coordinates are smooth functions of the rotation frequency. Our approach to explaining such a behavior exploits the fact that the wave function of each rotating droplet acquires a linear phase on the coordinates. Hence, the relative phases between the nearest neighboring droplets allow us to predict the position of the vortices in the intermediate low-density region. Here, we show that for a droplet distribution forming a triangular lattice, the phases of three neighboring droplets are needed for the correct description of the vortex location. In particular, for our confined system, we demonstrate that the estimate accurately reproduces the extended Gross-Pitaevskii results in the spatial regions where the neighboring droplets are well-defined.

Published

2024

9. All-fiber microendoscopic polarization sensing at single-photon level aided by deep-learning

Author

Bielak, Martin, Vašinka, Dominik, and Ježek, Miroslav

Subjects

Physics - Optics, Physics - Instrumentation and Detectors, Quantum Physics

Abstract

The polarization of light conveys crucial information about the spatial ordering and optical properties of a specimen. However, precise polarization measurement in challenging conditions, including constrained spaces, low light levels, and high-speed scenarios, remains a severe challenge. Addressing this problem, we introduce a real-time polarization measurement method that is accurate down to a single-photon level and provides complete information about the polarization state. Free of moving components, the polarization sensor utilizes a short rigid piece of few-mode fiber followed by a fiber array and a detector array. The calibration of the sensor relies on a neural network yielding unprecedented accuracy across all polarization states, including partially polarized light. We validate the approach by visualizing the polarization structure of biological specimens and the liquid crystal polymer sample (birefringent USAF test). Our method offers an efficient and reliable solution for real-time polarization sensing and microendoscopy under low-light conditions., Comment: 17 pages, 6 figures, data & code: https://github.com/VasinkaD/Polarization-Deep-Sense

Published

2024

10. Vortex nucleation processes in rotating lattices of Bose-Einstein condensates ruled by the on-site phases

Author

Jezek, D. M. and Capuzzi, P.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study the nucleation and dynamics of vortices in rotating lattice potentials where weakly linked condensates are formed with each condensate exhibiting an almost axial symmetry. Due to such a symmetry, the on-site phases acquire a linear dependence on the coordinates as a result of the rotation, which allows us to predict the position of vortices along the low density paths that separate the sites. We first show that, for a system of atoms loaded in a four-site square lattice potential, subject to a constant rotation frequency, the analytical expression that we obtain for the positions of vortices of the stationary arrays accurately reproduces the full three-dimensional Gross-Pitaevskii results. We then study the time-dependent vortex nucleation process when a linear ramp of the rotation frequency is applied to a lattice with sixteen sites. We develop a formula for the number of nucleated vortices which turns to have a linear dependence on the rotation frequency with a smaller slope than that of the standard estimate which is valid in absence of the lattice. From time-dependent Gross-Pitaevskii simulations we further find that the on-site populations remain almost constant during the time evolution instead of spreading outwards, as expected from the action of the centrifugal force. Therefore, the time-dependent phase difference between neighboring sites acquires a running behavior typical of a self-trapping regime. We finally show that, in accordance with our predictions, this fast phase-difference evolution provokes a rapid vortex motion inside the lattice. Our analytical expressions may be useful for describing other vortex processes in systems with the same on-site axial symmetry.

Published

2023

11. High-resolution coincidence counting system for large-scale photonics applications

Author

Hloušek, Josef, Grygar, Jan, Dudka, Michal, and Ježek, Miroslav

Subjects

Physics - Optics, Physics - Instrumentation and Detectors, Quantum Physics

Abstract

The increasing complexity of the recent photonic experiments challenges developing efficient multi-channel coincidence counting systems with high-level functionality. Here, we report a coincidence unit able to count detection events ranging from singles to 16-fold coincidences with full channel-number resolution. The device operates within sub-100~ps coincidence time windows, with a maximum input frequency of 1.5~GHz and an overall jitter of less than 10~ps. The unit high-level timing performance renders it suitable for quantum photonic experiments employing low-timing-jitter single-photon detectors. Additionally, the unit can be used in complex photonic systems to drive feed-forward loops. We have demonstrated the developed coincidence counting unit in photon-number-resolving detection to directly quantify the statistical properties of light, specifically coherent and thermal states, with a fidelity exceeding 0.999 up to 60~photons., Comment: 7 pages, 8 figures, 1 table

Published

2023

12. Cold damping of levitated optically coupled nanoparticles

Author

Liska, Vojtech, Zemankova, Tereza, Svak, Vojtech, Jakl, Petr, Jezek, Jan, Branecky, Martin, Simpson, Stephen H., Zemanek, Pavel, and Brzobohaty, Oto

Subjects

Physics - Optics, Quantum Physics

Abstract

Methods for controlling the motion of single particles, optically levitated in vacuum, have developed rapidly in recent years. The technique of cold damping makes use of feedback-controlled, electrostatic forces to increase dissipation without introducing additional thermal fluctuations. This process has been instrumental in the ground-state cooling of individual electrically charged nanoparticles. Here we show that the same method can be applied to a pair of nanoparticles, coupled by optical binding forces. These optical binding forces are about three orders of magnitude stronger than typical Coulombic inter-particle force and result in a coupled motion of both nanoparticles characterized by a pair of normal modes. We demonstrate cold damping of these normal modes, either independently or simultaneously, to sub-Kelvin temperatures at pressures of 5x10^{-3} mbar. Experimental observations are captured by a theoretical model which we use to survey the parameter space more widely and to quantify the limits imposed by measurement noise and time delays. Our work paves the way for the study of quantum interactions between meso-scale particles and the exploration of multiparticle entanglement in levitated optomechanical systems.

Published

2023

13. Synchronization of spin-driven limit cycle oscillators optically levitated in vacuum

Author

Brzobohaty, Oto, Duchan, Martin, Jakl, Petr, Jezek, Jan, Zemanek, Pavel, and Simpson, Stephen H.

Subjects

Physics - Optics

Abstract

We explore, experimentally and theoretically, the emergence of coherent coupled oscillations and synchronization between a pair of non-Hermitian, stochastic, opto-mechanical oscillators, levitated in vacuum. Each oscillator consists of a polystyrene microsphere trapped in a circularly polarized, counter-propagating Gaussian laser beam. Non-conservative, azimuthal forces, deriving from inhomogeneous optical spin, push the micro-particles out of thermodynamic equilibrium. For modest optical powers each particle shows a tendency towards orbital circulation. Initially, their stochastic motion is weakly correlated. As the power is increased, the tendency towards orbital circulation strengthens and the motion of the particles becomes highly correlated. Eventually, centripetal forces overcome optical gradient forces and the oscillators undergo a collective Hopf bifurcation. For laser powers exceeding this threshold, a pair of limit cycles appear, which synchronize due to weak optical and hydrodynamic interactions. In principle, arrays of such Non-Hermitian elements can be arranged, paving the way for opto-mechanical topological materials or, possibly, classical time crystals. In addition, the preparation of synchronized states in levitated optomechanics could lead to new and robust sensors or alternative routes to the entanglement of macroscopic objects.

Published

2023

14. A source of entangled photons based on a cavity-enhanced and strain-tuned GaAs quantum dot

Author

Rota, Michele B., Krieger, Tobias M., Buchinger, Quirin, Beccaceci, Mattia, Neuwirth, Julia, Huet, Hêlio, Horová, Nikola, Lovicu, Gabriele, Ronco, Giuseppe, da Silva, Saimon F. Covre, Pettinari, Giorgio, Moczała-Dusanowska, Magdalena, Kohlberger, Christoph, Manna, Santanu, Stroj, Sandra, Freund, Julia, Yuan, Xueyong, Schneider, Christian, Ježek, Miroslav, Höfling, Sven, Basset, Francesco Basso, Huber-Loyola, Tobias, Rastelli, Armando, and Trotta, Rinaldo

Subjects

Quantum Physics, Condensed Matter - Materials Science

Abstract

A quantum-light source that delivers photons with a high brightness and a high degree of entanglement is fundamental for the development of efficient entanglement-based quantum-key distribution systems. Among all possible candidates, epitaxial quantum dots are currently emerging as one of the brightest sources of highly entangled photons. However, the optimization of both brightness and entanglement currently requires different technologies that are difficult to combine in a scalable manner. In this work, we overcome this challenge by developing a novel device consisting of a quantum dot embedded in a circular Bragg resonator, in turn, integrated onto a micromachined piezoelectric actuator. The resonator engineers the light-matter interaction to empower extraction efficiencies up to 0.69(4). Simultaneously, the actuator manipulates strain fields that tune the quantum dot for the generation of entangled photons with corrected fidelities to a maximally entangled state up to 0.96(1). This hybrid technology has the potential to overcome the limitations of the key rates that plague QD-based entangled sources for entanglement-based quantum key distribution and entanglement-based quantum networks.

Published

2022

15. Sub-0.1 degree phase locking of a single-photon interferometer

Author

Švarc, Vojtěch, Nováková, Martina, Dudka, Michal, and Ježek, Miroslav

Subjects

Quantum Physics

Abstract

We report a single-photon Mach-Zehnder interferometer stabilized to a phase precision of 0.05 degrees over 15 hours. To lock the phase, we employ an auxiliary reference light at a different wavelength than the quantum signal. The developed phase locking operates continuously, with negligible crosstalk, and for an arbitrary phase of the quantum signal. Moreover, its performance is independent of intensity fluctuations of the reference. Since the presented method can be used in a vast majority of quantum interferometric networks it can significantly improve phase-sensitive applications in quantum communication and quantum metrology.

Published

2022

16. Quantum non-Gaussianity certification of photon-number-resolving detectors

Author

Grygar, Jan, Hloušek, Josef, Fiurášek, Jaromír, and Ježek, Miroslav

Subjects

Physics - Optics, Quantum Physics

Abstract

We report on direct experimental certification of the quantum non-Gaussian character of a photon-number resolving detector. The certification protocol is based on an adaptation of the existing quantum non-Gaussianity criteria for quantum states to quantum measurements. In our approach, it suffices to probe the detector with a vacuum state and two different thermal states to test its quantum non-Gaussianity. The certification is experimentally demonstrated for the detector formed by a spatially multiplexed array of ten single-photon avalanche photodiodes. We confirm the quantum non-Gaussianity of POVM elements $\hat{\Pi}_m$ associated with the $m$-fold coincidence counts, up to $m=7$. The experimental ability to certify from the first principles the quantum non-Gaussian character of $\hat{\Pi}_m$ is for large $m$ limited by low probability of the measurement outcomes, especially for vacuum input state. We find that the injection of independent Gaussian background noise into the detector can be helpful and may reduce the measurement time required for reliable confirmation of quantum non-Gaussianity. In addition, we modified and experimentally verified the quantum non-Gaussianity certification protocol employing a third thermal state instead of a vacuum to speed up the whole measurement. Our findings demonstrate the existence of efficient tools for the practical characterization of fundamental non-classical properties and benchmarking of complex optical quantum detectors., Comment: 15 pages, 8 figures

Published

2022

17. Deep learning of quantum entanglement from incomplete measurements

Author

Koutný, Dominik, Ginés, Laia, Moczała-Dusanowska, Magdalena, Höfling, Sven, Schneider, Christian, Predojević, Ana, and Ježek, Miroslav

Subjects

Quantum Physics, Computer Science - Machine Learning

Abstract

The quantification of the entanglement present in a physical system is of para\-mount importance for fundamental research and many cutting-edge applications. Currently, achieving this goal requires either a priori knowledge on the system or very demanding experimental procedures such as full state tomography or collective measurements. Here, we demonstrate that by employing neural networks we can quantify the degree of entanglement without needing to know the full description of the quantum state. Our method allows for direct quantification of the quantum correlations using an incomplete set of local measurements. Despite using undersampled measurements, we achieve a quantification error of up to an order of magnitude lower than the state-of-the-art quantum tomography. Furthermore, we achieve this result employing networks trained using exclusively simulated data. Finally, we derive a method based on a convolutional network input that can accept data from various measurement scenarios and perform, to some extent, independently of the measurement device., Comment: 10 pages, 5 figures, 1 table

Published

2022

18. Computational modeling of ventricular-ventricular interactions suggest a role in clinical conditions involving heart failure.

Author

Kim, Salla, Randall, E, Jezek, Filip, Beard, Daniel, and Chesler, Naomi

Subjects

computational modeling, diastolic dysfunction, heart failure with preserved ejection fraction, right ventricular dysfunction, systolic dysfunction, ventricular interdependence

Abstract

Introduction: The left (LV) and right (RV) ventricles are linked biologically, hemodynamically, and mechanically, a phenomenon known as ventricular interdependence. While LV function has long been known to impact RV function, the reverse is increasingly being realized to have clinical importance. Investigating ventricular interdependence clinically is challenging given the invasive measurements required, including biventricular catheterization, and confounding factors such as comorbidities, volume status, and other aspects of subject variability. Methods: Computational modeling allows investigation of mechanical and hemodynamic interactions in the absence of these confounding factors. Here, we use a threesegment biventricular heart model and simple circulatory system to investigate ventricular interdependence under conditions of systolic and diastolic dysfunction of the LV and RV in the presence of compensatory volume loading. We use the end-diastolic pressure-volume relationship, end-systolic pressure-volume relationship, Frank Starling curves, and cardiac power output as metrics. Results: The results demonstrate that LV systolic and diastolic dysfunction lead to RV compensation as indicated by increases in RV power. Additionally, RV systolic and diastolic dysfunction lead to impaired LV filling, interpretable as LV stiffening especially with volume loading to maintain systemic pressure. Discussion: These results suggest that a subset of patients with intact LV systolic function and diagnosed to have impaired LV diastolic function, categorized as heart failure with preserved ejection fraction (HFpEF), may in fact have primary RV failure. Application of this computational approach to clinical data sets, especially for HFpEF, may lead to improved diagnosis and treatment strategies and consequently improved outcomes.

Published

2023

19. High extraction efficiency source of photon pairs based on a quantum dot embedded in a broadband micropillar cavity

Author

Ginés, Laia, Moczała-Dusanowska, Magdalena, Dlaka, David, Hošák, Radim, Gonzales-Ureta, Junior R., Ježek, Miroslav, Harbord, Edmund, Oulton, Ruth, Höfling, Sven, Young, Andrew B., Schneider, Christian, and Predojević, Ana

Subjects

Quantum Physics

Abstract

The generation of photon pairs in single quantum dots is based on a process that is, in its nature, deterministic. However, an efficient extraction of these photon pairs from a high-index semiconductor host material requires engineering of the photonic environment. We report on a micropillar-based device featuring an extraction efficiency of 69.4(10)$\%$ that is achieved by harnessing a broadband operation suitable for extraction of photon pairs emitted from a single quantum dot. Opposing the approaches that rely solely on Purcell enhancement to realize the enhancement of the extraction efficiency, our solution exploits a suppression of the emission into the modes other than the cavity mode. Our technological implementation requires modest fabrication effort enabling higher device yields that can be scaled up to meet the growing needs of quantum technologies. Furthermore, the design of the device can be further optimized to allow for an extraction efficiency of 85$\%$.

Published

2021

20. Rotation-driven transition into coexistent Josephson modes in an atomtronic dc-SQUID

Author

Jezek, D. M. and Cataldo, H. M.

Subjects

Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics

Abstract

By means of a two-mode model, we show that transitions to different arrays of coexistent regimes in the phase space can be attained by rotating a double-well system, which consists of a toroidal condensate with two diametrically placed barriers. Such a configuration corresponds to the atomtronic counterpart of the well-known direct-current superconducting quantum interference device. Due to the phase gradient experimented by the on-site localized functions when the system is subject to rotation, a phase difference appears on each junction in order to satisfy the quantization of the velocity field around the torus. We demonstrate that such a phase can produce a significant change on the relative values of different types of hopping parameters. In particular, we show that within a determined rotation frequency interval, a hopping parameter, usually disregarded in nonrotating systems, turns out to rule the dynamics. At the limits of such a frequency interval, bifurcations of the stationary points occur, which substantially change the phase space portrait that describes the orbits of the macroscopic canonical conjugate variables. We analyze the emerging dynamics that combines the $0$ and $\pi$ Josephson modes, and evaluate the small-oscillation time-periods of such orbits at the frequency range where each mode survives. All the findings predicted by the model are confirmed by Gross-Pitaevskii simulations., Comment: 13 pages, 8 figures. Accepted in PRA

Published

2021

21. Bidirectional deep learning of polarization transfer in liquid crystals with application to quantum state preparation

Author

Vašinka, Dominik, Bielak, Martin, Neset, Michal, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Optics

Abstract

Accurate control of light polarization represents a core building block in polarization metrology, imaging, and optical and quantum communications. Voltage-controlled liquid crystals offer an efficient way of polarization transformation. However, common twisted nematic liquid crystals are notorious for lacking an accurate theoretical model linking control voltages and output polarization. An inverse model, which would predict control voltages required to prepare a target polarization, is even more challenging. Here we report both the direct and inverse models based on deep neural networks, radial basis functions, and linear interpolation. We present an inverse-direct compound model solving the problem of control voltages ambiguity. We demonstrate one order of magnitude improvement in accuracy using deep learning compared to the radial basis function method and two orders of magnitude improvement compared to the linear interpolation. Errors of the deep neural network model also decrease faster than the other methods with an increasing number of training data. The best direct and inverse models reach the average infidelities of $4 \times 10^{-4}$ and $2 \times 10^{-4}$, respectively, which is the accuracy level not reported yet. Furthermore, we demonstrate local and remote preparation of an arbitrary single-photon polarization state using the deep learning models. The results will impact the application of twisted-nematic liquid crystals, increasing their control accuracy across the board. The presented bidirectional learning can be used for optimal classical control of complex photonic devices and quantum circuits beyond interpolation., Comment: 8 pages, 5 figures, 1 table, data & code: https://github.com/VasinkaD/NeuralLC

Published

2021

22. Experimental observation of anomalous supralinear response of single-photon detectors

Author

Hloušek, Josef, Straka, Ivo, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Optics

Abstract

We demonstrate a direct single-source measurement of absolute nonlinearity of single-photon detectors with unprecedented accuracy. We discover a surprising supralinear behavior of single-photon avalanche diodes and show that it cannot be explained using known theoretical models. We also fully characterize sub- and supra-linear operation regimes of superconducting nanowire single-photon detectors and uncover the supralinearity under faint continuous illumination. The results identify new detector anomalies that supersede existing knowledge of nonlinear effects at the single-photon level., Comment: 19 pages, 16 figures, 4 tables

Published

2021

23. Ethereum Data Structures

Author

Jezek, Kamil

Subjects

Computer Science - Computation and Language

Abstract

Ethereum platform operates with rich spectrum of data structures and hashing and coding functions. The main source describing them is the Yellow paper, complemented by a lot of informal blogs. These sources are somehow limited. In particular, the Yellow paper does not ideally balance brevity and detail, in some parts it is very detail, while too shallow elsewhere. The blogs on the other hand are often too vague and in certain cases contain incorrect information. As a solution, we provide this document, which summarises data structures used in Ethereum. The goal is to provide sufficient detail while keeping brevity. Sufficiently detailed formal view is enriched with examples to extend on clarity.

Published

2021

24. Application of quotient graph theory to three-edge star graphs

Author

Ježek, Vladimír and Lipovský, Jiří

Subjects

Mathematical Physics, Mathematics - Functional Analysis, Mathematics - Group Theory, Quantum Physics, 34B45 (Primary) 20C30 81Q35 (Secondary)

Abstract

We apply the quotient graph theory described by Band, Berkolaiko, Joyner and Liu to particular graphs symmetric with respect to $S_3$ and $C_3$ symmetry groups. We find the quotient graphs for the three-edge star quantum graph with Neumann boundary conditions at the loose ends and three types of coupling conditions at the central vertex (standard, $\delta$ and preferred-orientation coupling). These quotient graphs are smaller than the original graph and the direct sum of quotient graph Hamiltonians is unitarily equivalent to the original Hamiltonian., Comment: 18 pages, 1 figure, submitted to the proceedings of 10th Workshop on Quantum Chaos and Localisation Phenomena, 27-28 May 2021, Warsaw, Poland

Published

2021

25. Non-blocking programmable delay line with minimal dead time and tens of picoseconds jitter

Author

Mazin, Glib, Stejskal, Aleš, Dudka, Michal, and Ježek, Miroslav

Subjects

Physics - Instrumentation and Detectors

Abstract

We report a non-blocking high-resolution digital delay line based on an asynchronous circuit design. Field programmable gate array logic primitives were used as a source of delay and optimally arranged using combinatorial optimization. This approach allows for an efficient trade-off of the resolution and a delay range together with minimized dead time operation. We demonstrate the method by implementing the delay line adjustable from 23 ns up to 1635 ns with a resolution of 10 ps. We present a detailed experimental characterization of the device focusing on thermal instability, timing jitter, and pulse spreading, which represent three main issues of the asynchronous design. We found a linear dependence of the delay on the temperature with the slope of 0.2 ps/K per a logic primitive. We measured the timing jitter of the delay to be in the range of 7 ps - 165 ps, linearly increasing over the dynamic range of the delay. We reduced the effect of pulse spreading by introducing pulse shrinking circuits, and reached the overall dead time of 4 ns - 22.5 ns within the dynamic range of the delay. The presented non-blocking delay line finds usage in applications where the dead time minimization is crucial, and tens of picoseconds excess jitter is acceptable, such as in many advanced photonic networks.

Published

2021

26. Interpreting Logical Metonymy through Dense Paraphrasing

Author

Ye, Bingyang, Tu, Jingxuan, Jezek, Elisabetta, and Pustejovsky, James

Subjects

Artificial Intelligence, Linguistics, Natural Language Processing, Semantics of language, Computational Modeling

Abstract

Compositionality has been argued to a necessary component of interpreting language, yet there appear to be many linguistic phenomena that do not overtly exhibit semantic compositional behavior. One of the challenges involves the phenomena of contextual modulations referred to collectively as semantic coercion or logical metonymy. In this paper, we present a computational model that provides the “compositional flexibility” in the interpretation of a verb with its arguments, for such coercive contexts in English. Specifically, we argue that such constructions typically have surface structural correlates in the form of dense paraphrases, and that these forms can be used to model the masked content in the coerced compositional context. We present preliminary results using a transformer architecture on a masked completion task. Our results show that modeling logical metonymy is a challenging task but can be substantially improved by fine-tuning through dense paraphrasing.

Published

2022

27. Direct experimental certification of quantum non-Gaussian character and Wigner function negativity of single-photon detectors

Author

Hloušek, Josef, Ježek, Miroslav, and Fiurášek, Jaromír

Subjects

Quantum Physics, Physics - Optics

Abstract

Highly nonclassical character of optical quantum detectors, such as single-photon detectors, is essential for preparation of quantum states of light and a vast majority of applications in quantum metrology and quantum information processing. Therefore, it is both fundamentally interesting and practically relevant to investigate the nonclassical features of optical quantum measurements. Here we propose and experimentally demonstrate a procedure for direct certification of quantum non-Gaussianity and Wigner function negativity, two crucial nonclassicality levels, of photonic quantum detectors. Remarkably, we characterize the highly nonclassical properties of the detector by probing it with only two classical thermal states and a vacuum state. We experimentally demonstrate the quantum non-Gaussianity of single-photon avalanche diode even under the presence of background noise, and we also certify the negativity of the Wigner function of this detector. Our results open the way for direct benchmarking of photonic quantum detectors with a few measurements on classical states.

Published

2021

28. Shaping the $g^{(2)}$ autocorrelation and photon statistics

Author

Straka, Ivo and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Optics

Abstract

We propose a method of arbitrarily shaping and scaling the temporal intensity correlations of an optical signal locally, avoiding periodic correlations. We demonstrate our approach experimentally using stochastic intensity modulation. We also analyze and simulate shaping both temporal correlations and photon statistics that are fully specified by the user. We show that within the confines of monotony and convexity, the temporal correlations are independent of photon statistics and can take any shape., Comment: 11 pages, 6 figures, 3 tables

Published

2020

29. Effect of source statistics on utilizing photon entanglement in quantum key distribution

Author

Hošák, Radim, Straka, Ivo, Predojević, Ana, Filip, Radim, and Ježek, Miroslav

Subjects

Quantum Physics

Abstract

A workflow for evaluation of entanglement source quality is proposed. Based on quantum state density matrices obtained from theoretical models and experimental data, we make an estimate of a potential performance of a quantum entanglement source in quantum key distribution protocols. This workflow is showcased for continuously pumped spontaneous parametric down-conversion (SPDC) source, where it highlights the trade-off between entangled pair generation rate and entanglement quality caused by multiphoton nature of the generated quantum states. We employ this characterization technique to show that secure key rate of down-converted photon pairs is limited to 0.029 bits per detection window due to intrinsic multiphoton contributions. We also report that there exists one optimum gain for continuous-wave down-conversion sources. We find a bound for secure key rate extracted from SPDC sources and make a comparison with perfectly single-pair quantum states, such as those produced by quantum dots., Comment: 13 pages, 5 figures

Published

2020

30. Blocked populations in ring-shaped optical lattices

Author

Nigro, M., Capuzzi, P., and Jezek, D. M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study a special dynamical regime of a Bose-Einstein condensate in a ring-shaped lattice where the populations in each site remain constant during the time evolution. The states in this regime are characterized by equal occupation numbers in alternate wells and non-trivial phases, while the phase differences between neighboring sites evolve in time yielding persistent currents that oscillate around the lattice. We show that the velocity circulation around the ring lattice alternates between two values determined by the number of wells and with a specific time period that is only driven by the onsite interaction energy parameter. In contrast to the self-trapping regime present in optical lattices, the occupation number at each site does not show any oscillation and the particle imbalance does not possess a lower bound for the phenomenon to occur. These findings are predicted with a multimode model and confirmed by full three-dimensional Gross-Pitaevskii simulations using an effective onsite interaction energy parameter.

Published

2020

31. Bose-Einstein condensates in rotating ring-shaped lattices: a multimode model

Author

Nigro, M, Capuzzi, P, and Jezek, D M

Subjects

Condensed Matter - Quantum Gases

Abstract

We develop a multimode model that describes the dynamics on a rotating Bose-Einstein condensate confined by a ring-shaped optical lattice with large filling numbers. The parameters of the model are obtained as a function of the rotation frequency using full 3D Gross-Pitaevskii simulations. From such numerical calculations, we extract the velocity field induced at each site and analyze the relation and the differences between the phase of the hopping parameter of our model and the Peierls phase. To this end, a detailed discussion of such phases is presented in geometrical terms which takes into account the position of the junctions for different configurations. For circularly symmetric onsite densities a simple analytical relation between the hopping phase and the angular momentum is found for arbitrary number of sites. Finally, we confront the results of the rotating multimode model dynamics with Gross-Pitaevskii simulations finding a perfect agreement.

Published

2020

32. Experimental quantum decoherence control by dark states of the environment

Author

Stárek, Robert, Mičuda, Michal, Straka, Ivo, Nováková, Martina, Dušek, Miloslav, Ježek, Miroslav, Fiurášek, Jaromír, and Filip, Radim

Subjects

Quantum Physics

Abstract

Coherent interaction of a quantum system with environment usually induces quantum decoherence. However, remarkably, in certain configurations the coherent system-environment coupling can be simultaneously explored to engineer a specific dark state of the environment that eliminates the decoherence. Here we report on experimental demonstration of such protocol for suppression of quantum decoherence by quantum decoherence itself. The protocol is based on indirect control of the environment via quantum measurements on quantum probes interacting with the environment prior to the system that should be protected. No direct manipulation with the environment is required to suppress the decoherence. In our proof-of-principle experiment, we demonstrate protection of a single qubit coupled to another single qubit. We implement the required quantum circuits with linear optics and single photons, which allows us to maintain very high degree of control and flexibility in the experiment. Our results clearly confirm the decoherence suppression achieved by the protocol and pave the way to its application to other physical platforms., Comment: 10 pages, 7 figures

Published

2020

33. Feedforward-enhanced Fock state conversion with linear optics

Author

Švarc, Vojtěch, Hloušek, Josef, Nováková, Martina, Fiurášek, Jaromír, and Ježek, Miroslav

Subjects

Quantum Physics

Abstract

Engineering quantum states of light represents a crucial task in the vast majority of photonic quantum technology applications. Direct manipulation of the number of photons in the light signal, such as single-photon subtraction and addition, proved to be an efficient strategy for the task. Here we propose an adaptive multi-photon subtraction scheme where a particular subtraction task is conditioned by all previous subtraction events in order to maximize the probability of successful subtraction. We theoretically illustrate this technique on the model example of conversion of Fock states via photon subtraction. We also experimentally demonstrate the core building block of the proposal by implementing a feedforward-assisted conversion of two-photon state to a single-photon state. Our experiment combines two elementary photon subtraction blocks where the splitting ratio of the second subtraction beam splitter is affected by the measurement result from the first subtraction block in real time using an ultra-fast feedforward loop. The reported optimized photon subtraction scheme applies to a broad range of photonic states, including highly nonclassical Fock states and squeezed light, advancing the photonic quantum toolbox., Comment: 11 pages, 5 figures

Published

2020

34. The Scientific Legacy of NASA’s Operation IceBridge

Author

MacGregor, Joseph A, Boisvert, Linette N, Medley, Brooke, Petty, Alek A, Harbeck, Jeremy P, Bell, Robin E, Blair, J Bryan, Blanchard‐Wrigglesworth, Edward, Buckley, Ellen M, Christoffersen, Michael S, Cochran, James R, Csathó, Beáta M, Marco, Eugenia L, Dominguez, RoseAnne T, Fahnestock, Mark A, Farrell, Sinéad L, Gogineni, S Prasad, Greenbaum, Jamin S, Hansen, Christy M, Hofton, Michelle A, Holt, John W, Jezek, Kenneth C, Koenig, Lora S, Kurtz, Nathan T, Kwok, Ronald, Larsen, Christopher F, Leuschen, Carlton J, Locke, Caitlin D, Manizade, Serdar S, Martin, Seelye, Neumann, Thomas A, Nowicki, Sophie MJ, Paden, John D, Richter‐Menge, Jacqueline A, Rignot, Eric J, Rodríguez‐Morales, Fernando, Siegfried, Matthew R, Smith, Benjamin E, Sonntag, John G, Studinger, Michael, Tinto, Kirsty J, Truffer, Martin, Wagner, Thomas P, Woods, John E, Young, Duncan A, and Yungel, James K

Subjects

Climate Action, Physical Sciences, Earth Sciences, Engineering, Meteorology & Atmospheric Sciences

Abstract

The National Aeronautics and Space Administration (NASA)’s Operation IceBridge (OIB) was a 13-year (2009–2021) airborne mission to survey land and sea ice across the Arctic, Antarctic, and Alaska. Here, we review OIB’s goals, instruments, campaigns, key scientific results, and implications for future investigations of the cryosphere. OIB’s primary goal was to use airborne laser altimetry to bridge the gap in fine-resolution elevation measurements of ice from space between the conclusion of NASA’s Ice, Cloud, and land Elevation Satellite (ICESat; 2003–2009) and its follow-on, ICESat-2 (launched 2018). Additional scientific requirements were intended to contextualize observed elevation changes using a multisensor suite of radar sounders, gravimeters, magnetometers, and cameras. Using 15 different aircraft, OIB conducted 968 science flights, of which 42% were repeat surveys of land ice, 42% were surveys of previously unmapped terrain across the Greenland and Antarctic ice sheets, Arctic ice caps, and Alaskan glaciers, and 16% were surveys of sea ice. The combination of an expansive instrument suite and breadth of surveys enabled numerous fundamental advances in our understanding of the Earth’s cryosphere. For land ice, OIB dramatically improved knowledge of interannual outlet-glacier variability, ice-sheet, and outlet-glacier thicknesses, snowfall rates on ice sheets, fjord and sub-ice-shelf bathymetry, and ice-sheet hydrology. Unanticipated discoveries included a reliable method for constraining the thickness within difficult-to-sound incised troughs beneath ice sheets, the extent of the firn aquifer within the Greenland Ice Sheet, the vulnerability of many Greenland and Antarctic outlet glaciers to ocean-driven melting at their grounding zones, and the dominance of surface-melt-driven mass loss of Alaskan glaciers. For sea ice, OIB significantly advanced our understanding of spatiotemporal variability in sea ice freeboard and its snow cover, especially through combined analysis of fine-resolution altimetry, visible imagery, and snow radar measurements of the overlying snow thickness. Such analyses led to the unanticipated discovery of an interdecadal decrease in snow thickness on Arctic sea ice and numerous opportunities to validate sea ice freeboards from satellite radar altimetry. While many of its data sets have yet to be fully explored, OIB’s scientific legacy has already demonstrated the value of sustained investment in reliable airborne platforms, airborne instrument development, interagency and international collaboration, and open and rapid data access to advance our understanding of Earth’s remote polar regions and their role in the Earth system.

Published

2021

35. Counting Statistics of Actively Quenched SPADs Under Continuous Illumination

Author

Straka, Ivo, Grygar, Jan, Hloušek, Josef, and Ježek, Miroslav

Subjects

Physics - Instrumentation and Detectors, Physics - Optics, Quantum Physics

Abstract

This work presents stochastic approaches to model the counting behavior of actively quenched single-photon avalanche diodes (SPADs) subjected to continuous-wave constant illumination. We present both analytical expressions and simulation algorithms predicting the distribution of the number of detections in a finite time window. We also present formulas for the mean detection rate. The approaches cover recovery time, afterpulsing, and twilight pulsing. We experimentally compare the theoretical predictions to measured data using commercially available silicon SPADs. Their total variation distances range from $10^{-5}$ to $10^{-2}$., Comment: 11 pages, 5 figures, 1 table

Published

2020

36. Accurate polarization preparation and measurement using twisted nematic liquid crystals

Author

Bielak, Martin, Stárek, Robert, Krčmarský, Vojtěch, Mičuda, Michal, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Instrumentation and Detectors, Physics - Optics

Abstract

Generation of particular polarization states of light, encoding information in polarization degree of freedom, and efficient measurement of unknown polarization are the key tasks in optical metrology, optical communications, polarization-sensitive imaging, and photonic information processing. Liquid crystal devices have proved to be indispensable for these tasks, though their limited precision and the requirement of a custom design impose a limit of practical applicability. Here we report fast preparation and detection of polarization states with unprecedented accuracy using liquid-crystal cells extracted from common twisted nematic liquid-crystal displays. To verify the performance of the device we use it to prepare dozens of polarization states with average fidelity 0.999(1) and average angle deviation 0.5(3) deg. Using four-projection minimum tomography as well as six-projection Pauli measurement, we measure polarization states employing the reported device with the average fidelity of 0.999(1). Polarization measurement data are processed by the maximum likelihood method to reach a valid estimate of the polarization state. In addition to the application in classical polarimetry, we also employ the reported liquid-crystal device for full tomographic characterization of a three-mode Greenberger--Horne--Zeilinger entangled state produced by a photonic quantum processor., Comment: data&code: https://github.com/BielakM/polarimeter

Published

2020

37. Fully tunable and switchable coupler for photonic routing in quantum detection and modulation

Author

Švarc, Vojtěch, Nováková, Martina, Mazin, Glib, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Applied Physics

Abstract

Photonic routing is a key building block of many optical applications challenging its development. We report a 2$\times$2 photonic coupler with splitting ratio switchable by a low-voltage electronic signal with 10~GHz bandwidth and tens of nanoseconds latency. The coupler can operate at any splitting ratio ranging from 0:100 to 100:0 with the extinction ratio of 26 dB in optical bandwidth of 1.3 THz. We show sub-nanosecond switching between arbitrary coupling regimes including balanced 50:50 beam splitter, 0:100 switch, and a photonic tap. The core of the device is based on Mach-Zehnder interferometer in a dual-wavelength configuration allowing real-time phase lock with long-term sub-degree stability at single-photon level. Using the reported coupler, we demonstrate for the first time the perfectly balanced time-multiplexed device for photon-number-resolving detectors and also the active preparation of a photonic temporal qudit state up to four time bins. Verified long-term stable operation of the coupler at the single photon level makes it suitable for wide application range in quantum information processing and quantum optics in general.

Published

2019

38. Collisional dynamics of multiple dark solitons in a toroidal Bose-Einstein condensate: Quasiparticle picture

Author

Cataldo, H. M. and Jezek, D. M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study the collisional dynamics of multiple dark solitons in a Bose-Einstein condensate confined by a toroidal trap. We assume a tight enough confinement in the radial direction to prevent possible dissipative effects due to the presence of solitonic vortices. Analytical expressions for the initial order parameters with imprinted phases are utilized to generate different initial arrays of solitons, for which the time-dependent Gross-Pitaevskii equation is numerically solved. Given that the soliton velocity is conserved due to the lack of dissipation, we are able to apply a simple quasiparticle description of the soliton dynamics. In fact, the trajectory equations are written in terms of the velocities and the angular shifts produced at each collision, in analogy to the infinite one-dimensional system. To calculate the angular shifts, we directly extract them from the trajectories given by the Gross-Pitaevskii simulations and, on the other hand, we show that accurate values can be analytically obtained by adapting a formula valid for the infinite one-dimensional system that involves the healing length, which in our inhomogeneous system must be evaluated in terms of the sound velocity along the azimuthal direction. We further show that very good estimates of such a sound velocity can be directly determined by using the ground state density profile and the values of the imprinted phases. We discuss the possible implementation of the system here proposed using the current experimental techniques., Comment: 13 pages, 8 figures

Published

2019

39. Accurate detection of arbitrary photon statistics

Author

Hloušek, Josef, Dudka, Michal, Straka, Ivo, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Optics

Abstract

We report a measurement workflow free of systematic errors consisting of a reconfigurable photon-number-resolving detector, custom electronic circuitry, and faithful data-processing algorithm. We achieve unprecedentedly accurate measurement of various photon-number distributions going beyond the number of detection channels with average fidelity 0.998, where the error is contributed primarily by the sources themselves. Mean numbers of photons cover values up to 20 and faithful autocorrelation measurements range from g^(2) = 0.006 to 2. We successfully detect chaotic, classical, non-classical, non-Gaussian, and negative-Wigner-function light. Our results open new paths for optical technologies by providing full access to the photon-number information., Comment: manuscript: 4 pages, 3 figures; supplementary material: 11 pages, 5 figures

Published

2018

40. Faithful hierarchy of genuine $n$-photon quantum non-Gaussian light

Author

Lachman, Lukáš, Straka, Ivo, Hloušek, Josef, Ježek, Miroslav, and Filip, Radim

Subjects

Quantum Physics

Abstract

Light is an essential tool for connections between quantum devices and for diagnostic of processes in quantum technology. Both applications deal with advanced nonclassical states beyond Gaussian coherent and squeezed states. Current development requires a loss-tolerant diagnostic of such nonclassical aspects. We propose and experimentally verify a faithful hierarchy of genuine $n$-photon quantum non-Gaussian light. We conclusively witnessed 3-photon quantum non-Gaussian light in the experiment. Measured data demonstrates a direct applicability of the hierarchy for a large class of real states.

Published

2018

41. The optimal reordering of measurements for photonic quantum tomography

Author

Hošák, Radim, Stárek, Robert, and Ježek, Miroslav

Subjects

Quantum Physics

Abstract

Quantum tomography is an essential method of the photonic technology toolbox and is routinely used for evaluation of experimentally prepared states of light and characterization of devices transforming such states. The tomography procedure consists of many different sequentially performed measurements. We present considerable tomography speedup by optimally arranging the individual constituent measurements, which is equivalent to solving an instance of the traveling salesman problem. As an example, we obtain solutions for photonic systems of up to five qubits, and conclude that already for systems of three or more qubits, the total duration of the tomography procedure can be halved. The reported speedup has been verified experimentally for quantum state tomography and also for full quantum process characterization up to six qubits, without resorting to any complexity reduction or simplification of the system of interest. Our approach is versatile and reduces the time of an input-output characterization of optical devices and various scattering processes as well., Comment: 7 pages, 5 figures, 5 tables, references added, github: https://github.com/rhosak/tomo-tsp

Published

2018

42. Tunable soft-matter optofluidic waveguides assembled by light

Author

Brzobohaty, Oto, Chvatal, Lukas, Jonas, Alexandr, Siler, Martin, Kanka, Jan, Jezek, Jan, and Zemanek, Pavel

Subjects

Physics - Optics, Condensed Matter - Soft Condensed Matter

Abstract

Development of artificial materials exhibiting unusual optical properties is one of the major strands of current photonics research. Of particular interest are soft-matter systems reconfigurable by external stimuli that play an important role in research fields ranging from physics to chemistry and life sciences. Here, we prepare and study unconventional self-assembled colloidal optical waveguides (CWs) created from wavelength-size dielectric particles held together by long-range optical forces. We demonstrate robust non-linear optical properties of these CWs that lead to optical transformation characteristics remarkably similar to those of gradient refractive index materials and enable reversible all-optical tuning of light propagation through the CW. Moreover, we characterize strong optomechanical interactions responsible for the CW self-assembly; in particular, we report self-sustained oscillations of the whole CW structure tuned so that the wavelength of the laser beams forming the CW is not allowed to propagate through. The observed significant coupling between the mechanical motion of the CW and the intensity of light transmitted through the CW can form a base for designing novel mesoscopic-scale photonic devices that are reconfigurable by light.

Published

2018

43. Dynamics in multiple-well Bose-Einstein condensates

Author

Nigro, M., Capuzzi, P., Cataldo, H. M., and Jezek, D. M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study the dynamics of three-dimensional weakly linked Bose-Einstein condensates using a multimode model with an effective interaction parameter. The system is confined by a ring-shaped four-well trapping potential. By constructing a two-mode Hamiltonian in a reduced highly symmetric phase space, we examine the periodic orbits and calculate their time periods both in the self-trapping and Josephson regimes. The dynamics in the vicinity of the reduced phase space is investigated by means of a Floquet multiplier analysis, finding regions of different linear stability and analyzing their implications on the exact dynamics. The numerical exploration in an extended region of the phase space demonstrates that two-mode tools can also be useful for performing a partition of the space in different regimes. Comparisons with Gross-Pitaevskii simulations confirm these findings and emphasize the importance of properly determining the effective on-site interaction parameter governing the multimode dynamics., Comment: 12 pages, 13 figures

Published

2018

44. Effective two-mode model in Bose-Einstein condensates versus Gross-Pitaevskii simulations

Author

Nigro, Mauro, Capuzzi, Pablo, Cataldo, Horacio M., and Jezek, Dora M.

Subjects

Condensed Matter - Quantum Gases

Abstract

We study the dynamics of three-dimensional Bose-Einstein condensates confined by double-well potentials using a two-mode model with an effective on-site interaction energy parameter. The effective on-site interaction energy parameter is evaluated for different numbers of particles ranging from a low experimental value to larger ones approaching the Thomas-Fermi limit, yielding important corrections to the dynamics. We analyze the time periods as functions of the initial imbalance and find a closed integral form that includes all interaction-driven parameters. A simple analytical formula for the self-trapping period is introduced and shown to accurately reproduce the exact values provided by the two-mode model. Systematic numerical simulations of the problem in 3D demonstrate the excellent agreement of the two-mode model for experimental parameters., Comment: 7 pages, 5 figures

Published

2018

45. Generation of ideal thermal light in warm atomic vapor

Author

Mika, J., Podhora, L., Lachman, L., Obšil, P., Hloušek, J., Ježek, M., Filip, R., and Slodička, L.

Subjects

Quantum Physics

Abstract

We present the experimental generation of light with directly observable close-to ideal thermal statistical properties. The thermal light state is prepared using a spontaneous Raman emission in a warm atomic vapor. The photon number statistics is evaluated by both the measurement of second-order correlation function and by the detailed analysis of the corresponding photon number distribution, which certifies the quality of the Bose-Einstein statistics generated by natural physical mechanism. We further demonstrate the extension of the spectral bandwidth of the generated light to hundreds of MHz domain while keeping the ideal thermal statistics, which suggests a direct applicability of the presented source in a broad range of applications including optical metrology, tests of robustness of quantum communication protocols, or quantum thermodynamics.

Published

2018

46. Work and information from thermal states after subtraction of energy quanta

Author

Hloušek, J., Ježek, M., and Filip, R.

Subjects

Quantum Physics

Abstract

Quantum oscillators prepared out of thermal equilibrium can be used to produce work and transmit information. By intensive cooling of a single oscillator, its thermal energy deterministically dissipates to a colder environment, and the oscillator substantially reduces its entropy. This out-of-equilibrium state allows us to obtain work and to carry information. Here, we propose and experimentally demonstrate an advanced approach, conditionally preparing more efficient out-of-equilibrium states only by a weak dissipation, an inefficient quantum measurement of the dissipated thermal energy, and subsequent triggering of that states. Although it conditionally subtracts the energy quanta from the oscillator, average energy grows, and second-order correlation function approaches unity as by coherent external driving. On the other hand, the Fano factor remains constant and the entropy of the subtracted state increases, which raise doubts about a possible application of this approach. To resolve it, we predict and experimentally verify that both available work and transmitted information can be conditionally higher in this case than by arbitrary cooling or adequate thermal heating up to the same average energy. It qualifies the conditional procedure as a useful source for experiments in quantum information and thermodynamics., Comment: 10 pages, 6 figures

Published

2018

47. Generator of arbitrary classical photon statistics

Author

Straka, Ivo, Mika, Jaromír, and Ježek, Miroslav

Subjects

Quantum Physics, Physics - Optics

Abstract

We propose and experimentally demonstrate a device for generating light with arbitrary classical photon-number distribution. We use programmable acousto-optical modulation to control the intensity of light within the dynamic range of more than 30 dB and inter-level transitions faster than 500 ns. We propose a universal method that allows high-fidelity generation of user-defined photon statistics. Extremely high precision <0.001 can be reached for lower photon numbers, and faithful tail behavior can be reached for very high photon numbers. We demonstrate arbitrary statistics generation for up to 500 photons. The proposed device can produce any classical light statistics with given parameters including Poissonian, super-Poissonian, thermal, and heavy-tailed distributions like log-normal. The presented method can be used to simulate communication channels, calibrate the response of photon-number-resolving detectors, or probe physical phenomena sensitive to photon statistics., Comment: 10 pages, 5 figures, 1 table

Published

2018

48. Arbitrary digital pulse sequence generator with delay-loop timing

Author

Hošák, Radim and Ježek, Miroslav

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment, Quantum Physics

Abstract

We propose an idea of an electronic multi-channel arbitrary digital sequence generator with temporal granularity equal to a single clock cycle. We implement the generator with 32 channels using a low-cost ARM microcontroller and demonstrate its capability to produce temporal delays ranging from tens of nanoseconds to hundreds of seconds, with 12 ns timing granularity and linear scaling of delay with respect to the number of delay loop iterations. The generator is optionally synchronized with an external clock source to provide 100 ps jitter and overall sequence repeatability within the whole temporal range. The generator is fully programmable and able to produce digital sequences of high complexity. The concept of the generator can be implemented using different microcontrollers and applied for controlling of various optical, atomic, and nuclear physics measurement setups., Comment: 5 pages, 4 figures

Published

2018

49. Nonclassical photon pairs from warm atomic vapor using a single driving laser

Author

Podhora, L., Obšil, P., Straka, I., Ježek, M., and Slodička, L.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Generation of nonclassical light is an essential tool for quantum optics research and applications in quantum information technology. We present realization of the source of nonclassically correlated photon pairs based on the process of spontaneous four-wave-mixing in warm atomic vapor. Atoms are excited only by a single laser beam in retro-reflected configuration and narrowband frequency filtering is employed for selection of correlated photon pairs. Nonclassicality of generated light fields is proved by analysis of their statistical properties. Measured parameters of the presented source promise further applicability for efficient interaction with atomic ensembles.

Published

2017

50. Deterministic phase measurements exhibiting super-sensitivity and super-resolution

Author

Schäfermeier, Clemens, Ježek, Miroslav, Madsen, Lars S., Gehring, Tobias, and Andersen, Ulrik L.

Subjects

Quantum Physics

Abstract

Phase super-sensitivity is obtained when the sensitivity in a phase measurement goes beyond the quantum shot noise limit, whereas super-resolution is obtained when the interference fringes in an interferometer are narrower than half the input wavelength. Here we show experimentally that these two features can be simultaneously achieved using a relatively simple setup based on Gaussian states and homodyne measurement. Using 430 photons shared between a coherent- and a squeezed vacuum state, we demonstrate a 22-fold improvement in the phase resolution while we observe a 1.7-fold improvement in the sensitivity. In contrast to previous demonstrations of super-resolution and super-sensitivity, this approach is fully deterministic., Comment: v2:Published Optica version with supplemental information

Published

2017