Your search keyword '"Francesco V"' showing total 89 results

1. Quantum error mitigation in optimized circuits for particle-density correlations in real-time dynamics of the Schwinger model

Author

Pomarico, Domenico, Pandey, Mahul, Cioli, Riccardo, Dell'Anna, Federico, Pascazio, Saverio, Pepe, Francesco V., Facchi, Paolo, and Ercolessi, Elisa

Subjects

Quantum Physics

Abstract

Quantum computing gives direct access to the study of real-time dynamics of quantum many-body systems. In principle, it is possible to directly calculate non-equal-time correlation functions, from which one can detect interesting phenomena, such as the presence of quantum scars or dynamical quantum phase transitions. In practice, these calculations are strongly affected by noise, due to the complexity of the required quantum circuits. As a testbed for the evaluation of real-time evolution of observables and correlations, the dynamics of the Zn Schwinger model in a one dimensional lattice is considered. To control the computational cost, we adopt a quantum-classical strategy that reduces the dimensionality of the system by restricting the dynamics to the Dirac vacuum sector and optimizes the embedding into a qubit model by minimizing the number of three-qubit gates. We derive a digital circuit implementation of the time-evolution of particle-density correlation operators and their correlation, comparing results from exact evolution, bare noisy simulations and simulations with different error mitigation techniques. For the evolution of the particle-density operators we also perform runs on a physical IBM quantum device.

Published

2025

2. Non-Markovian dynamics of BIC generation via single-photon scattering

Author

Magnifico, Giuseppe, Maffei, Maria, Pomarico, Domenico, Das, Debmalya, Facchi, Paolo, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics, Physics - Computational Physics

Abstract

The excitation of bound states in the continuum (BICs) in two- or multi-qubit systems lies at the heart of entanglement generation and harnessing in waveguide quantum electrodynamics platforms. However, the generation of qubit pair BICs through single-photon scattering is hindered by the fact that these states are effectively decoupled from propagating photons. We prove that scattering of a parity-invariant single photon on a qubit pair, combined with a properly engineered time variation of the qubit detuning, is not only feasible, but also more effective than strategies based on the relaxation of the excited states of the qubits. The use of tensor network methods to simulate the proposed scheme enables to include photon delays in collision models, thus opening the possibility to follow the time evolution of the full quantum system, including qubits and field, and to efficiently implement and characterize the dynamics in non-ideal cases, which turn out to be optimal for the BIC generation strategy., Comment: 10 pages, 4 figures. For associated video, see http://drive.google.com/file/d/1DJSWkWYcf8sV5oVKmoLxkNXZ-26SuPhJ/view

Published

2025

3. Robustness of chaotic-light correlation imaging against turbulence

Author

Scala, Giovanni, Massaro, Gianlorenzo, Borreggine, Germano, Lupo, Cosmo, D'Angelo, Milena, and Pepe, Francesco V.

Subjects

Physics - Optics, Quantum Physics

Abstract

We consider an imaging scheme, inspired by microscopy, in which both correlation imaging and first-order intensity imaging can be performed simultaneously, to investigate the effects of strong turbulence on the two different kinds of images. The comparison between direct and correlation imaging in the presence of strong turbulence unambiguously revealed an advantage of the latter. Remarkably, this advantage, quantified by analyzing the visibility of periodic sample patterns, is more striking when the presence of turbulence becomes the dominant factor in determining the image resolution., Comment: 14 pages, 3 figures

Published

2024

4. Dressed atom revisited: Hamiltonian-independent treatment of the radiative cascade

Author

Pepe, Francesco V. and Słowik, Karolina

Subjects

Quantum Physics

Abstract

The dressed atom approach provides a tool to investigate the dynamics of an atom-laser system by fully retaining the quantum nature of the coherent mode. In its standard derivation, the internal atom-laser evolution is described within the rotating-wave approximation, which determines a doublet structure of the spectrum and the peculiar fluorescence triplet in the steady state. However, the rotating wave approximation may fail to apply to atomic systems subject to femtosecond light pulses, light-matter systems in the strong-coupling regime or sustaining permanent dipole moments. This work aims to demonstrate how the general features of the steady-state radiative cascade are affected by the interaction of the dressed atom with propagating radiation modes. Rather than focusing on a specific model, we analyze how these features depend on the parameters characterizing the dressed eigenstates in arbitrary atom-laser dynamics, given that a set of general hypotheses is satisfied. Our findings clarify the general conditions in which a description of the radiative cascade in terms of transition between dressed states is self-consistent. We provide a guideline to determine the properties of photon emission for any atom-laser interaction model, which can be particularly relevant when the model should be tailored to enhance a specific line. We apply the general results to the case in which a permanent dipole moment is a source of low-energy emission, whose frequency is of the order of the Rabi coupling., Comment: 13 pages, 4 figures

Published

2024

5. Correlation Hyperspectral Imaging

Author

Massaro, Gianlorenzo, Pepe, Francesco V., and D'Angelo, Milena

Subjects

Physics - Optics, Quantum Physics

Abstract

Hyperspectral imaging aims at providing information on both the spatial and the spectral distribution of light, with high resolution. However, state-of-the-art protocols are characterized by an intrinsic trade-off imposing to sacrifice either resolution or image acquisition speed. We address this limitation by exploiting light intensity correlations, which are shown to enable overcoming the typical downsides of traditional hyperspectral imaging techniques, both scanning and snapshot. The proposed approach also opens possibilities that are not otherwise achievable, such as sharper imaging and natural filtering of broadband spectral components that would otherwise hide the spectrum of interest. The enabled combination of high spatial and spectral resolution, high speed, and insensitivity to undesired spectral features shall lead to a paradigm change in hyperspectral imaging devices and open-up new application scenarios., Comment: 11 pages, 4 figures

Published

2024

6. Condensation of vanishing photon emission rates in random atomic clouds

Author

Viggiano, Viviana, Bachelard, Romain, Cunden, Fabio Deelan, Facchi, Paolo, Kaiser, Robin, Pascazio, Saverio, Pepe, Francesco V., and Scardicchio, Antonello

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Mathematical Physics

Abstract

In the collective photon emission from atomic clouds both the atomic transition frequency and the decay rate are modified compared to a single isolated atom, leading to the effects of superradiance and subradiance. In this Letter, we analyse the properties of the Euclidean random matrix associated to the radiative dynamics of a cold atomic cloud, previously investigated in the contexts of photon localization and Dicke super- and subradiance. We present evidence of a new type of phase transition, surprisingly controlled by the cooperativeness parameter, rather than the spatial density or the diagonal disorder. The numerical results corroborate the occurrence of such a phase transition at a critical value of the cooperativeness parameter, above which the lower edge of the spectrum vanishes exhibiting a macroscopic accumulation of eigenvalues. Independent evaluations based on the two phenomena provide the same value of the critical cooperativeness parameter., Comment: 8 pages, 6 figures

Published

2024

7. 3D correlation imaging for localized phase disturbance mitigation

Author

Pepe, Francesco V. and D'Angelo, Milena

Subjects

Physics - Optics, Quantum Physics

Abstract

Correlation plenoptic imaging is a procedure to perform light-field imaging without spatial resolution loss, by measuring second-order spatio-temporal correlations of light. We investigate the possibility to use correlation plenoptic imaging to mitigate the effect of a phase disturbance in the propagation from the object to the main lens. We assume that this detrimental effect, that can be due to a turbulent medium, is localized at a specific distance from the lens, and is slowly varying in time. The mitigation of turbulence effects has already fostered the development of both light-field imaging and correlation imaging procedures. Here, we aim at merging these aspects, proposing a correlation light-field imaging method to overcome the effects of slowly varying turbulence, without the loss of lateral resolution, typical of traditional plenoptic imaging devices., Comment: 7 pages, 1 figure

Published

2024

8. Light Field Ghost Imaging

Author

Paniate, Alberto, Massaro, Gianlorenzo, Avella, Alessio, Meda, Alice, Pepe, Francesco V., Genovese, Marco, D'Angelo, Milena, and Berchera, Ivano Ruo

Subjects

Physics - Optics, Quantum Physics

Abstract

Techniques based on classical and quantum correlations in light beams, such as ghost imaging, allow us to overcome many limitations of conventional imaging and sensing protocols. Despite their advantages, applications of such techniques are often limited in practical scenarios where the position and the longitudinal extension of the target object are unknown. In this work, we propose and experimentally demonstrate a novel imaging technique, named Light Field Ghost Imaging, that exploits light correlations and light field imaging principles to enable going beyond the limitations of ghost imaging in a wide range of applications. Notably, our technique removes the requirement to have prior knowledge of the object distance allowing the possibility of refocusing in post-processing, as well as performing 3D imaging while retaining all the benefits of ghost imaging protocols.

Published

2023

9. Periodic patterns for resolution limit characterization of correlation plenoptic imaging

Author

Scattarella, Francesco, Massaro, Gianlorenzo, Stoklasa, Bohumil, D'Angelo, Milena, and Pepe, Francesco V.

Subjects

Physics - Optics, Quantum Physics

Abstract

The measurement of the spatio-temporal correlations of light provides an interesting tool to overcome the traditional limitations of standard imaging, such as the strong trade-off between spatial resolution and depth of field. In particular, using correlation plenoptic imaging, one can detect both the spatial distribution and the direction of light in a scene, pushing both resolution and depth of field to the fundamental limit imposed by wave-optics. This allows one to perform refocusing of different axial planes and three-dimensional reconstruction without any spatial scanning. In the present work, we investigate the resolution limit in a particular correlation plenoptic imaging scheme, by considering periodic test patterns, which provide, through analytical results, a deeper insight in the resolution properties of this second-order imaging technique, also in comparison with standard imaging., Comment: 16 pages, 4 figures

Published

2023

10. Cooperative photon emission rates in random atomic clouds

Author

Viggiano, Viviana, Bachelard, Romain, Cunden, Fabio Deelan, Facchi, Paolo, Kaiser, Robin, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Mathematical Physics

Abstract

We investigate the properties of the cooperative decay modes of a cold atomic cloud, characterized by a Gaussian distribution in three dimensions, initially excited by a laser in the linear regime. We study the properties of the decay rate matrix $S$, whose dimension coincides with the number of atoms in the cloud, in order to get a deeper insight into properties of cooperative photon emission. Since the atomic positions are random, $S$ is a Euclidean random matrix whose entries are function of the atom distances. We show that, in the limit of a large number of atoms in the cloud, the eigenvalue distribution of $S$ depends on a single parameter $b_0$, called the cooperativeness parameter, which can be viewed as a quantifier of the number of atoms that are coherently involved in an emission process. For very small values of $b_0$, we find that the limit eigenvalue density is approximately triangular. We also study the nearest-neighbour spacing distribution and the eigenvector statistics, finding that, although the decay rate matrices are Euclidean, the bulk of their spectra mostly behaves according to the expectations of classical random matrix theory. In particular, in the bulk there is level repulsion and the eigenvectors are delocalized, therefore exhibiting the universal behaviour of chaotic quantum systems., Comment: 14 pages, 8 figures

Published

2023

11. Dynamical quantum phase transitions of the Schwinger model: real-time dynamics on IBM Quantum

Author

Pomarico, Domenico, Cosmai, Leonardo, Facchi, Paolo, Lupo, Cosmo, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics

Abstract

Simulating real-time dynamics of gauge theories represents a paradigmatic use case to test the hardware capabilities of a quantum computer, since it can involve non-trivial input states preparation, discretized time evolution, long-distance entanglement, and measurement in a noisy environment. We implement an algorithm to simulate the real-time dynamics of a few-qubit system that approximates the Schwinger model in the framework of lattice gauge theories, with specific attention to the occurrence of a dynamical quantum phase transition. Limitations in the simulation capabilities on IBM Quantum are imposed by noise affecting the application of single-qubit and two-qubit gates, which combine in the decomposition of Trotter evolution. The experimental results collected in quantum algorithm runs on IBM Quantum are compared with noise models to characterize the performance in the absence of error mitigation.

Published

2023

12. Dimensional reduction of the Dirac equation in arbitrary spatial dimensions

Author

Lonigro, Davide, Maggi, Rocco, Angelone, Giuliano, Ercolessi, Elisa, Facchi, Paolo, Marmo, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Mathematical Physics

Abstract

We investigate the general properties of the dimensional reduction of the Dirac theory, formulated in a Minkowski spacetime with an arbitrary number of spatial dimensions. This is done by applying Hadamard's method of descent, which consists in conceiving low-dimensional theories as a specialization of high-dimensional ones that are uniform along the additional space coordinate. We show that the Dirac equation reduces to either a single Dirac equation or two decoupled Dirac equations, depending on whether the higher-dimensional manifold has even or odd spatial dimensions, respectively. Furthermore, we construct and discuss an explicit hierarchy of representations in which this procedure becomes manifest and can easily be iterated., Comment: 22 pages, several figures

Published

2022

13. Correlated-photon imaging at 10 volumetric images per second

Author

Massaro, Gianlorenzo, Mos, Paul, Vasiukov, Sergii, Di Lena, Francesco, Scattarella, Francesco, Pepe, Francesco V., Ulku, Arin, Giannella, Davide, Charbon, Edoardo, Bruschini, Claudio, and D'Angelo, Milena

Subjects

Quantum Physics, Physics - Optics

Abstract

The correlation properties of light provide an outstanding tool to overcome the limitations of traditional imaging techniques. A relevant case is represented by correlation plenoptic imaging (CPI), a quantum-inspired volumetric imaging protocol employing spatio-temporally correlated photons from either entangled or chaotic sources to address the main limitations of conventional light-field imaging, namely, the poor spatial resolution and the reduced change of perspective for 3D imaging. However, the application potential of high-resolution imaging modalities relying on photon correlations is limited, in practice, by the need to collect a large number of frames. This creates a gap, unacceptable for many relevant tasks, between the time performance of correlated-light imaging and that of traditional imaging methods. In this article, we address this issue by exploiting the photon number correlations intrinsic in chaotic light, combined with a cutting-edge ultrafast sensor made of a large array of single-photon avalanche diodes (SPADs). This combination of source and sensor is embedded within a novel single-lens CPI scheme enabling to acquire 10 volumetric images per second. Our results place correlated-photon imaging at a competitive edge and prove its potential in practical applications., Comment: 13 pages, 6 figures

Published

2022

14. Dimensional reduction of the Dirac theory

Author

Angelone, Giuliano, Ercolessi, Elisa, Facchi, Paolo, Lonigro, Davide, Maggi, Rocco, Marmo, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Mathematical Physics

Abstract

We perform a reduction from three to two spatial dimensions of the physics of a spin-1/2 fermion coupled to the electromagnetic field, by applying Hadamard's method of descent. We consider first the free case, in which motion is determined by the Dirac equation, and then the coupling with a dynamical electromagnetic field, governed by the Dirac-Maxwell equations. We find that invariance along one spatial direction splits the free Dirac equation in two decoupled theories. On the other hand, a dimensional reduction in the presence of an electromagnetic field provides a more complicated theory in 2+1 dimensions, in which the method of descent is extended by using the covariant derivative. Equations simplify, but decoupling between different physical sectors occurs only if specific classes of solutions are considered., Comment: 21 pages, 1 figure

Published

2022

15. Comparative analysis of signal-to-noise ratio in correlation plenoptic imaging architectures

Author

Massaro, Gianlorenzo, Scala, Giovanni, D'Angelo, Milena, and Pepe, Francesco V.

Subjects

Physics - Optics, Quantum Physics

Abstract

Correlation plenoptic imaging (CPI) is a scanning-free diffraction-limited 3D optical imaging technique exploiting the peculiar properties of correlated light sources. CPI has been further extended to samples of interest to microscopy, such as fluorescent or scattering objects, in a modified architecture named correlation light-field microscopy (CLM). Interestingly, experiments have shown that the noise performances of CLM are significantly improved over the original CPI scheme, leading to better images and faster acquisition. In this work, we provide a theoretical foundation to such advantage by investigating the properties of both the signal-to-noise and the signal-to-background ratios of CLM and the original CPI setup., Comment: 22 pages, 10 figures

Published

2022

16. Dimensional reduction of electromagnetism

Author

Maggi, Rocco, Ercolessi, Elisa, Facchi, Paolo, Marmo, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Physics - Classical Physics, Quantum Physics

Abstract

We derive one- and two-dimensional models for classical electromagnetism by making use of Hadamard's method of descent. Low-dimensional electromagnetism is conceived as a specialization of the higher dimensional one, in which the fields are uniform along the additional spatial directions. This strategy yields two independent electromagnetisms in two spatial coordinates, and four independent electromagnetisms in one spatial coordinate., Comment: 17 pages, 5 figures

Published

2021

17. Light-field microscopy with correlated beams for extended volumetric imaging at the diffraction limit

Author

Massaro, Gianlorenzo, Giannella, Davide, Scagliola, Alessio, Di Lena, Francesco, Scarcelli, Giuliano, Garuccio, Augusto, Pepe, Francesco V., and D'Angelo, Milena

Subjects

Physics - Optics, Quantum Physics

Abstract

Light-field microscopy represents a promising solution for microscopic volumetric imaging, thanks to its capability to encode information on multiple planes in a single acquisition. This is achieved through its peculiar simultaneous capture of information on light spatial distribution and propagation direction. However, state-of-the-art light-field microscopes suffer from a detrimental loss of spatial resolution compared to standard microscopes. We propose and experimentally demonstrate a light-field microscopy architecture based on light intensity correlation, in which resolution is limited only by diffraction. We demonstrate the effectiveness of our technique in refocusing three-dimensional test targets and biological samples out of the focused plane. We improve the depth of field by a factor 6 with respect to conventional microscopy, at the same resolution, and obtain, from one acquired correlation image, about $130,000$ images, all seen from different perspectives; such multi-perspective images are employed to reconstruct over $40$ planes within a $1 \,\mathrm{mm}^3$ sample with a diffraction-limited resolution voxel of $20 \times 20 \times 30\ \mu\mathrm{m}^3$., Comment: 14 pages, 10 figures

Published

2021

18. Stationary excitation waves and multimerization in arrays of quantum emitters

Author

Lonigro, Davide, Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., and Pomarico, Domenico

Subjects

Quantum Physics

Abstract

We explore the features of an equally-spaced array of two-level quantum emitters, that can be either natural atoms (or molecules) or artificial atoms, coupled to a field with a single continuous degree of freedom (such as an electromagnetic mode propagating in a waveguide). We investigate the existence and characteristics of bound states, in which a single excitation is shared among the emitters and the field. We focus on bound states in the continuum, occurring in correspondence of excitation energies in which a single excited emitter would decay. We characterize such bound states for an arbitrary number of emitters, and obtain two main results, both ascribable to the presence of evanescent fields. First, the excitation profile of the emitter states is a sinusoidal wave. Second, we discuss the emergence of multimers, consisting in subsets of emitters separated by two lattice spacings in which the electromagnetic field is approximately vanishing., Comment: 33 pages, 10 figures

Published

2021

19. Towards quantum 3D imaging devices: the Qu3D project

Author

Abbattista, Cristoforo, Amoruso, Leonardo, Burri, Samuel, Charbon, Edoardo, Di Lena, Francesco, Garuccio, Augusto, Giannella, Davide, Hradil, Zdenek, Iacobellis, Michele, Massaro, Gianlorenzo, Mos, Paul, Motka, Libor, Paur, Martin, Pepe, Francesco V., Peterek, Michal, Petrelli, Isabella, Rehacek, Jaroslav, Santoro, Francesca, Scattarella, Francesco, Ulku, Arin, Vasiukov, Sergii, Wayne, Michael, D'Angelo, Milena, Bruschini, Claudio, Ieronymaki, Maria, and Stoklasa, Bohumil

Subjects

Quantum Physics, Physics - Applied Physics, Physics - Optics

Abstract

We review the advancement of the research toward the design and implementation of quantum plenoptic cameras, radically novel 3D imaging devices that exploit both momentum-position entanglement and photon-number correlations to provide the typical refocusing and ultra-fast, scanning-free, 3D imaging capability of plenoptic devices, along with dramatically enhanced performances, unattainable in standard plenoptic cameras: diffraction-limited resolution, large depth of focus, and ultra-low noise. To further increase the volumetric resolution beyond the Rayleigh diffraction limit, and achieve the quantum limit, we are also developing dedicated protocols based on quantum Fisher information. However, for the quantum advantages of the proposed devices to be effective and appealing to end-users, two main challenges need to be tackled. First, due to the large number of frames required for correlation measurements to provide an acceptable SNR, quantum plenoptic imaging would require, if implemented with commercially available high-resolution cameras, acquisition times ranging from tens of seconds to a few minutes. Second, the elaboration of this large amount of data, in order to retrieve 3D images or refocusing 2D images, requires high-performance and time-consuming computation. To address these challenges, we are developing high-resolution SPAD arrays and high-performance low-level programming of ultra-fast electronics, combined with compressive sensing and quantum tomography algorithms, with the aim to reduce both the acquisition and the elaboration time by two orders of magnitude. Routes toward exploitation of the QPI devices will also be discussed., Comment: 14 pages, 6 figures

Published

2021

20. Photon-emitter dressed states in a closed waveguide

Author

Lonigro, Davide, Facchi, Paolo, Greentree, Andrew D., Pascazio, Saverio, Pepe, Francesco V., and Pomarico, Domenico

Subjects

Quantum Physics

Abstract

We study a system made up of one or two two-level quantum emitters, coupled to a single transverse mode of a closed waveguide, in which photon wavenumbers and frequencies are discretized, and characterize the stable states in which one excitation is steadily shared between the field and the emitters. We unearth finite-size effects in the field-emitter interactions and identify a family of dressed states, that represent the forerunners of bound states in the continuum in the limit of an infinite waveguide. We finally consider the potential interest of such states for applications in the field of quantum information., Comment: 11 pages, 6 figures

Published

2021

21. Distance sensing emerging from second-order interference of thermal light

Author

Pepe, Francesco V., Chilleri, Gabriele, Scala, Giovanni, Triggiani, Danilo, Kim, Yoon-Ho, and Tamma, Vincenzo

Subjects

Quantum Physics

Abstract

We introduce and describe a technique for distance sensing, based on second-order interferometry of thermal light. The method is based on measuring correlation between intensity fluctuations on two detectors, and provides estimates of the distances separating a remote mask from the source and the detector, even when such information cannot be retrieved by first-order intensity measurements. We show how the sensitivity to such distances is intimately connected to the degree of correlation of the measured interference pattern in different experimental scenarios and independently of the spectral properties of light. Remarkably, this protocol can be also used to measure the distance of remote reflective objects in the presence of turbulence. We demonstrate the emergence of new critical parameters which benchmark the degree of second-order correlation, describing the counterintuitive emergence of spatial second-order interference not only in the absence of (first-order) coherence at both detectors but also when first order interference is observed at one of the two detectors., Comment: 6 pages, 3 figures

Published

2020

22. Correlation Plenoptic Imaging between Arbitrary Planes

Author

Di Lena, Francesco, Massaro, Gianlorenzo, Lupo, Alessandro, Garuccio, Augusto, Pepe, Francesco V., and D'Angelo, Milena

Subjects

Physics - Optics, Quantum Physics

Abstract

We propose a novel method to perform plenoptic imaging at the diffraction limit by measuring second-order correlations of light between two reference planes, arbitrarily chosen, within the tridimensional scene of interest. We show that for both chaotic light and entangled-photon illumination, the protocol enables to change the focused planes, in post-processing, and to achieve an unprecedented combination of image resolution and depth of field. In particular, the depth of field results larger by a factor 3 with respect to previous correlation plenoptic imaging protocols, and by an order of magnitude with respect to standard imaging, while the resolution is kept at the diffraction limit. The results lead the way towards the development of compact designs for correlation plenoptic imaging devices based on chaotic light, as well as high-SNR plenoptic imaging devices based on entangled photon illumination, thus contributing to make correlation plenoptic imaging effectively competitive with commercial plenoptic devices., Comment: 12 pages, 6 figures

Published

2020

23. Spontaneous emission in dispersive media without point-dipole approximation

Author

Scala, Giovanni, Pepe, Francesco V., Facchi, Paolo, Pascazio, Saverio, and Słowik, Karolina

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Atomic Physics, Physics - Optics, Quantum Physics

Abstract

We study a two-level quantum system embedded in a dispersive environment and coupled with the electromagnetic field. We expand the theory of light-matter interactions to include the spatial extension of the system, taken into account through its wavefunctions. This is a development beyond the point-dipole approximation. This ingredient enables us to overcome the divergence problem related to the Green tensor propagator. Hence, we can reformulate the expressions for the spontaneous emission rate and the Lamb shift. In particular, the inclusion of the spatial structure of the atomic system clarifies the role of the asymmetry of atomic states with respect to spatial inversion in these quantities., Comment: 22 pages, 8 figures

Published

2020

24. Nonexponential decay of Feshbach molecules

Author

Pepe, Francesco V., Facchi, Paolo, Kordi, Zeinab, and Pascazio, Saverio

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We analyze the temporal behavior of the survival probability of an unstable $^6$Li Feshbach molecule close to the BCS-BEC crossover. We find different instances of nonexponential decay as the magnetic field approaches the resonance value, at which the molecule becomes stable. We observe a transition from an exponential decay towards a regime dominated by a stretched-exponential law., Comment: 10 pages, 7 figures

Published

2019

25. Real Time Dynamics and Confinement in the $\mathbb{Z}_{n}$ Schwinger-Weyl lattice model for 1+1 QED

Author

Magnifico, Giuseppe, Dalmonte, Marcello, Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., and Ercolessi, Elisa

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Lattice, High Energy Physics - Theory

Abstract

We study the out-of-equilibrium properties of $1+1$ dimensional quantum electrodynamics (QED), discretized via the staggered-fermion Schwinger model with an Abelian $\mathbb{Z}_{n}$ gauge group. We look at two relevant phenomena: first, we analyze the stability of the Dirac vacuum with respect to particle/antiparticle pair production, both spontaneous and induced by an external electric field; then, we examine the string breaking mechanism. We observe a strong effect of confinement, which acts by suppressing both spontaneous pair production and string breaking into quark/antiquark pairs, indicating that the system dynamics displays a number of out-of-equilibrium features., Comment: 21 pages, 17 figures

Published

2019

26. Bound states in the continuum for an array of quantum emitters

Author

Facchi, Paolo, Lonigro, Davide, Pascazio, Saverio, Pepe, Francesco V., and Pomarico, Domenico

Subjects

Quantum Physics

Abstract

We study the existence of bound states in the continuum for a system of n two-level quantum emitters, coupled with a one-dimensional boson field, in which a single excitation is shared among different components of the system. The emitters are fixed and equally spaced. We first consider the approximation of distant emitters, in which one can find degenerate eigenspaces of bound states corresponding to resonant values of energy, parametrized by a positive integer. We then consider the full form of the eigenvalue equation, in which the effects of the finite spacing and the field dispersion relation become relevant, yielding also nonperturbative effects. We explicitly solve the cases n=3 and n=4., Comment: 16 pages, 12 figures

Published

2019

27. Experimental investigation of quantum decay at short, intermediate and long times via integrated photonics

Author

Crespi, Andrea, Pepe, Francesco V., Facchi, Paolo, Sciarrino, Fabio, Mataloni, Paolo, Nakazato, Hiromichi, Pascazio, Saverio, and Osellame, Roberto

Subjects

Quantum Physics

Abstract

The decay of an unstable system is usually described by an exponential law. Quantum mechanics predicts strong deviations of the survival probability from the exponential: indeed, the decay is initially quadratic, while at very large times it follows a power law, with superimposed oscillations. The latter regime is particularly elusive and difficult to observe. Here we employ arrays of single-mode optical waveguides, fabricated by femtosecond laser direct inscription, to implement quantum systems where a discrete state is coupled and can decay into a continuum. The optical modes correspond to distinct quantum states of the photon and the temporal evolution of the quantum system is mapped into the spatial propagation coordinate. By injecting coherent light states in the fabricated photonic structures and by measuring light with an unprecedented dynamic range, we are able to experimentally observe not only the exponential decay regime, but also the quadratic Zeno region and the power-law decay at long evolution times.

Published

2019

28. Signal-to-noise properties of correlation plenoptic imaging with chaotic light

Author

Scala, Giovanni, D'Angelo, Milena, Garuccio, Augusto, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Physics - Optics

Abstract

Correlation Plenoptic Imaging (CPI) is a novel imaging technique, that exploits the correlations between the intensity fluctuations of light to perform the typical tasks of plenoptic imaging (namely, refocusing out-of-focus parts of the scene, extending the depth of field, and performing 3D reconstruction), without entailing a loss of spatial resolution. Here, we consider two different CPI schemes based on chaotic light, both employing ghost imaging: the first one to image the object, the second one to image the focusing element. We characterize their noise properties in terms of the signal-to-noise ratio (SNR) and compare their performances. We find that the SNR can be significantly higher and easier to control in the second CPI scheme, involving standard imaging of the object; under adequate conditions, this scheme enables reducing by one order of magnitude the number of frames for achieving the same SNR., Comment: 12 pages, 3 figures

Published

2019

29. Correlated photon emission by two excited atoms in a waveguide

Author

Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., and Pomarico, Domenico

Subjects

Quantum Physics

Abstract

Systems of atoms coupled to a single or few waveguide modes provide a testbed for physically and practically interesting interference effects. We consider the dynamics of a pair of atoms, approximated as two-level quantum emitters, coupled to a linear guided mode. In particular, we analyze the evolution of an initial state in which both atoms are excited, which is expected to decay into an asymptotic two-photon state. We investigate the lifetime of the initial configuration and the properties of the asymptotic photon correlations, and analyze the probability that the two photons are emitted in the same or in opposite directions. We find that the ratio R between parallel and antiparallel emission probabilities is maximal when the interatomic distance is a half-multiple of the half-wavelength of the emitted light. In such a case, R=3 in the small-coupling regime., Comment: 9 pages, 7 figures

Published

2018

30. Exploring plenoptic properties of correlation imaging with chaotic light

Author

Pepe, Francesco V., Vaccarelli, Ornella, Garuccio, Augusto, Scarcelli, Giuliano, and D'Angelo, Milena

Subjects

Physics - Optics, Quantum Physics

Abstract

In a setup illuminated by chaotic light, we consider different schemes that enable to perform imaging by measuring second-order intensity correlations. The most relevant feature of the proposed protocols is the ability to perform plenoptic imaging, namely to reconstruct the geometrical path of light propagating in the system, by imaging both the object and the focusing element. This property allows to encode, in a single data acquisition, both multi-perspective images of the scene and light distribution in different planes between the scene and the focusing element. We unveil the plenoptic property of three different setups, explore their refocusing potentialities and discuss their practical applications., Comment: 9 pages, 4 figures

Published

2017

31. Phase Transitions in $Z_{n}$ Gauge Models: Towards Quantum Simulations of the Schwinger-Weyl QED

Author

Ercolessi, Elisa, Facchi, Paolo, Magnifico, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Lattice, High Energy Physics - Theory

Abstract

We study the ground-state properties of a class of $\mathbb{Z}_n$ lattice gauge theories in 1 + 1 dimensions, in which the gauge fields are coupled to spinless fermionic matter. These models, stemming from discrete representations of the Weyl commutator for the $\mathrm{U}(1)$ group, preserve the unitary character of the minimal coupling, and have therefore the property of formally approximating lattice quantum electrodynamics in one spatial dimension in the large-$n$ limit. The numerical study of such approximated theories is important to determine their effectiveness in reproducing the main features and phenomenology of the target theory, in view of implementations of cold-atom quantum simulators of QED. In this paper we study the cases $n = 2 \div 8$ by means of a DMRG code that exactly implements Gauss' law. We perform a careful scaling analysis, and show that, in absence of a background field, all $\mathbb{Z}_n$ models exhibit a phase transition which falls in the Ising universality class, with spontaneous symmetry breaking of the $CP$ symmetry. We then perform the large-$n$ limit and find that the asymptotic values of the critical parameters approach the ones obtained for the known phase transition the zero-charge sector of the massive Schwinger model, which occurs at negative mass., Comment: 15 pages, 18 figures

Published

2017

32. Long-lived entanglement of two multilevel atoms in a waveguide

Author

Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., and Yuasa, Kazuya

Subjects

Quantum Physics

Abstract

We study the presence of nontrivial bound states of two multilevel quantum emitters and the photons propagating in a linear waveguide. We characterize the conditions for the existence of such states and determine their general properties, focusing in particular on the entanglement between the two emitters, that increases with the number of excitations. We discuss the relevance of the results for entanglement preservation and generation by spontaneous relaxation processes., Comment: 6 pages, 1 figure

Published

2017

33. Plenoptic imaging with second-order correlations of light

Author

Pepe, Francesco V., Scarcelli, Giuliano, Garuccio, Augusto, and D'Angelo, Milena

Subjects

Quantum Physics

Abstract

Plenoptic imaging is a promising optical modality that simultaneously captures the location and the propagation direction of light in order to enable tridimensional imaging in a single shot. We demonstrate that it is possible to implement plenoptic imaging through second-order correlations of chaotic light, thus enabling to overcome the typical limitations of classical plenoptic devices., Comment: 7 pages, 3 figures

Published

2017

34. Diffraction-limited plenoptic imaging with correlated light

Author

Pepe, Francesco V., Di Lena, Francesco, Mazzilli, Aldo, Edrei, Eitan, Garuccio, Augusto, Scarcelli, Giuliano, and D'Angelo, Milena

Subjects

Quantum Physics, Physics - Optics

Abstract

Traditional optical imaging faces an unavoidable trade-off between resolution and depth of field (DOF). To increase resolution, high numerical apertures (NA) are needed, but the associated large angular uncertainty results in a limited range of depths that can be put in sharp focus. Plenoptic imaging was introduced a few years ago to remedy this trade off. To this aim, plenoptic imaging reconstructs the path of light rays from the lens to the sensor. However, the improvement offered by standard plenoptic imaging is practical and not fundamental: the increased DOF leads to a proportional reduction of the resolution well above the diffraction limit imposed by the lens NA. In this paper, we demonstrate that correlation measurements enable pushing plenoptic imaging to its fundamental limits of both resolution and DOF. Namely, we demonstrate to maintain the imaging resolution at the diffraction limit while increasing the depth of field by a factor of 7. Our results represent the theoretical and experimental basis for the effective development of the promising applications of plenoptic imaging., Comment: 10 pages, 10 figures

Published

2017

35. Huygens' principle and Dirac-Weyl equation

Author

Pascazio, Saverio, Pepe, Francesco V., and Pérez-Pardo, Juan Manuel

Subjects

Quantum Physics

Abstract

We investigate the validity of Huygens' principle for forward propagation in the massless Dirac-Weyl equation. The principle holds for odd space dimension n, while it is invalid for even n. We explicitly solve the cases n=1,2 and 3 and discuss generic $n$. We compare with the massless Klein-Gordon equation and comment on possible generalizations and applications., Comment: 7 pages, 1 figure

Published

2017

36. Characterization of two distant double-slits by chaotic light second-order interference

Author

D'Angelo, Milena, Mazzilli, Aldo, Pepe, Francesco V., Garuccio, Augusto, and Tamma, Vincenzo

Subjects

Quantum Physics, Physics - Optics

Abstract

We present the experimental characterization of two distant double-slit masks illuminated by chaotic light, in the absence of first-order imaging and interference. The scheme exploits second-order interference of light propagating through two indistinguishable pairs of {\it disjoint} optical paths passing through the masks of interest. The proposed technique leads to a deeper understanding of biphoton interference and coherence, and opens the way to the development of novel schemes for retrieving information on the relative position and the spatial structure of distant objects, which is of interest in remote sensing, biomedical imaging, as well as monitoring of laser ablation, when first-order imaging and interference are not feasible., Comment: 9 pages, 3 figures

Published

2016

37. Correlation Plenoptic Imaging With Entangled Photons

Author

Pepe, Francesco V., Di Lena, Francesco, Garuccio, Augusto, Scarcelli, Giuliano, and D'Angelo, Milena

Subjects

Quantum Physics, Physics - Optics

Abstract

Plenoptic imaging is a novel optical technique for three-dimensional imaging in a single shot. It is enabled by the simultaneous measurement of both the location and the propagation direction of light in a given scene. In the standard approach, the maximum spatial and angular resolutions are inversely proportional, and so are the resolution and the maximum achievable depth of focus of the 3D image. We have recently proposed a method to overcome such fundamental limits by combining plenoptic imaging with an intriguing correlation remote-imaging technique: ghost imaging. Here, we theoretically demonstrate that correlation plenoptic imaging can be effectively achieved by exploiting the position-momentum entanglement characterizing spontaneous parametric down-conversion (SPDC) photon pairs. As a proof-of-principle demonstration, we shall show that correlation plenoptic imaging with entangled photons may enable the refocusing of an out-of-focus image at the same depth of focus of a standard plenoptic device, but without sacrificing diffraction-limited image resolution., Comment: 12 pages, 5 figures

Published

2016

38. Bound states and entanglement generation in waveguide quantum electrodynamics

Author

Facchi, Paolo, Kim, M. S., Pascazio, Saverio, Pepe, Francesco V., Pomarico, Domenico, and Tufarelli, Tommaso

Subjects

Quantum Physics

Abstract

We investigate the behavior of two quantum emitters (two-level atoms) embedded in a linear waveguide, in a quasi-one-dimensional configuration. Since the atoms can emit, absorb and reflect radiation, the pair can spontaneously relax towards an entangled bound state, under conditions in which a single atom would instead decay. We analyze the properties of these bound states, which occur for resonant values of the interatomic distance, and discuss their relevance with respect to entanglement generation. The stability of such states close to the resonance is studied, as well as the properties of non resonant bound states, whose energy is below the threshold for photon propagation., Comment: 11 pages, 4 figures

Published

2016

39. Correlation plenoptic imaging

Author

D'Angelo, Milena, Pepe, Francesco V., Garuccio, Augusto, and Scarcelli, Giuliano

Subjects

Quantum Physics, Physics - Optics

Abstract

Plenoptic imaging is a promising optical modality that simultaneously captures the location and the propagation direction of light in order to enable three-dimensional imaging in a single shot. However, in classical imaging systems, the maximum spatial and angular resolutions are fundamentally linked; thereby, the maximum achievable depth of field is inversely proportional to the spatial resolution. We propose to take advantage of the second-order correlation properties of light to overcome this fundamental limitation. In this paper, we demonstrate that the momentum/position correlation of chaotic light leads to the enhanced refocusing power of correlation plenoptic imaging with respect to standard plenoptic imaging., Comment: 6 pages, 3 figures

Published

2016

40. Split and overlapped binary solitons in optical lattices

Author

Sekh, Golam Ali, Pepe, Francesco V., Facchi, Paolo, Pascazio, Saverio, and Salerno, Mario

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We analyze the energetic and dynamical properties of bright-bright (BB) soliton pairs in a binary mixture of Bose-Einstein condensates subjected to the action of a combined optical lattice, acting as an external potential for the first species, while modulating the intraspecies coupling constant of the second. In particular, we use a variational approach and direct numerical integrations to investigate the existence and stability of BB solitons in which the two species are either spatially separated (split soliton) or located at the same optical lattice site (overlapped soliton). The dependence of these solitons on the interspecies interaction parameter is explicitly investigated. For repulsive interspecies interaction we show the existence of a series of critical values at which transitions from an initially overlapped soliton to split solitons occur. For attractive interspecies interaction only single direct transitions from split to overlapped BB solitons are found. The possibility to use split solitons for indirect measurements of scattering lengths is also suggested., Comment: 9 pages, 10 figures

Published

2015

41. Discrete Abelian Gauge Theories for Quantum Simulations of QED

Author

Notarnicola, Simone, Ercolessi, Elisa, Facchi, Paolo, Marmo, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics

Abstract

We study a lattice gauge theory in Wilson's Hamiltonian formalism. In view of the realization of a quantum simulator for QED in one dimension, we introduce an Abelian model with a discrete gauge symmetry $\mathbb{Z}_n$, approximating the $U(1)$ theory for large $n$. We analyze the role of the finiteness of the gauge fields and the properties of physical states, that satisfy a generalized Gauss's law. We finally discuss a possible implementation strategy, that involves an effective dynamics in physical space., Comment: 13 pages, 3 figures

Published

2015

42. Quantum Typicality and Initial Conditions

Author

Facchi, Paolo, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

If the state of a quantum system is sampled out of a suitable ensemble, the measurement of some observables will yield (almost) always the same result. This leads us to the notion of quantum typicality: for some quantities the initial conditions are immaterial. We discuss this problem in the framework of Bose-Einstein condensates., Comment: 8 pages

Published

2015

43. Typical observables in a two-mode Bose system

Author

Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., and Sekh, Golam Ali

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

A class of k-particle observables in a two-mode system of Bose particles is characterized by typicality: if the state of the system is sampled out of a suitable ensemble, an experimental measurement of that observable yields (almost) always the same result. We investigate the general features of typical observables, the criteria to determine typicality and finally focus on the case of density correlation functions, which are related to spatial distribution of particles and interference., Comment: 8 pages, 1 figure

Published

2015

44. Phase randomization and typicality in the interference of two condensates

Author

Facchi, Paolo, Nakazato, Hiromichi, Pascazio, Saverio, Pepe, Francesco V., Sekh, Golam Ali, and Yuasa, Kazuya

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

Interference is observed when two independent Bose-Einstein condensates expand and overlap. This phenomenon is typical, in the sense that the overwhelming majority of wave functions of the condensates, uniformly sampled out of a suitable portion of the total Hilbert space, display interference with maximal visibility. We focus here on the phases of the condensates and their (pseudo) randomization, which naturally emerges when two-body scattering processes are considered. Relationship to typicality is discussed and analyzed., Comment: 14 pages, 2 figures

Published

2014

45. Multipartite entanglement and few-body Hamiltonians

Author

Pepe, Francesco V.

Subjects

Quantum Physics

Abstract

We investigate the possibility to obtain higly multipartite-entangled states as nondegenerate eigenstates of Hamiltonians that involve only short-range and few-body interactions. We study small-size systems (with a number of qubits ranging from three to five) and search for Hamiltonians with a Maximally Multipartite Entangled State (MMES) as a nondegenerate eigenstate. We then find conditions, including bounds on the number of coupled qubits, to build a Hamiltonian with a Greenberger-Horne-Zeilinger (GHZ) state as a nondegenerate eigenstate. We finally comment on possible applications., Comment: 15 pages, 3 figures. Proceedings of IQIS 2013 to appear on IJQI

Published

2014

46. Unearthing wave-function renormalization effects in the time evolution of a Bose-Einstein condensate

Author

Facchi, Paolo, Pascazio, Saverio, Pepe, Francesco V., Arimondo, Ennio, Ciampini, Donatella, and Morsch, Oliver

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

We study the time evolution of a Bose-Einstein condensate in an accelerated optical lattice. When the condensate has a narrow quasimomentum distribution and the optical lattice is shallow, the survival probability in the ground band exhibits a steplike structure. In this regime we establish a connection between the wave-function renormalization parameter $Z$ and the phenomenon of resonantly enhanced tunneling., Comment: 12 pages, 3 figures. arXiv admin note: substantial text overlap with arXiv:1201.6286

Published

2012

47. Domain wall suppression in trapped mixtures of Bose-Einstein condensates

Author

Pepe, Francesco V., Facchi, Paolo, Florio, Giuseppe, and Pascazio, S.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

The ground state energy of a binary mixture of Bose-Einstein condensates can be estimated for large atomic samples by making use of suitably regularized Thomas-Fermi density profiles. By exploiting a variational method on the trial densities the energy can be computed by explicitly taking into account the normalization condition. This yields analytical results and provides the basis for further improvement of the approximation. As a case study, we consider a binary mixture of $^{87}$Rb atoms in two different hyperfine states in a double well potential and discuss the energy crossing between density profiles with different numbers of domain walls, as the number of particles and the inter-species interaction vary., Comment: 9 pages

Published

2012

48. Greenberger-Horne-Zeilinger states and few-body Hamiltonians

Author

Facchi, Paolo, Florio, Giuseppe, Pascazio, Saverio, and Pepe, Francesco V.

Subjects

Quantum Physics

Abstract

The generation of Greenberger-Horne-Zeilinger (GHZ) states is a crucial problem in quantum information. We derive general conditions for obtaining GHZ states as eigenstates of a Hamiltonian. In general, degeneracy cannot be avoided if the Hamiltonian contains m-body interaction terms with m<=2 and a number of qubits strictly larger than 4. As an application, we explicitly construct a two-body 4-qubit Hamiltonian and a three-body 5-qubit Hamiltonian that exhibit a GHZ as a nondegenerate eigenstate., Comment: 4 pages

Published

2011

49. Dimensional reduction of the Dirac equation in arbitrary spatial dimensions

Author

Davide Lonigro, Rocco Maggi, Giuliano Angelone, Elisa Ercolessi, Paolo Facchi, Giuseppe Marmo, Saverio Pascazio, and Francesco V. Pepe

Subjects

Fluid Flow and Transfer Processes, Quantum Physics, General Physics and Astronomy, FOS: Physical sciences, Mathematical Physics (math-ph), Quantum Physics (quant-ph), Mathematical Physics

Abstract

We investigate the general properties of the dimensional reduction of the Dirac theory, formulated in a Minkowski spacetime with an arbitrary number of spatial dimensions. This is done by applying Hadamard's method of descent, which consists in conceiving low-dimensional theories as a specialization of high-dimensional ones that are uniform along the additional space coordinate. We show that the Dirac equation reduces to either a single Dirac equation or two decoupled Dirac equations, depending on whether the higher-dimensional manifold has even or odd spatial dimensions, respectively. Furthermore, we construct and discuss an explicit hierarchy of representations in which this procedure becomes manifest and can easily be iterated., 22 pages, several figures

Published

2022

50. Quantum imaging at 10 volumetric images per second

Author

Massaro, Gianlorenzo, Mos, Paul, Vasiukov, Sergii, Di Lena, Francesco, Scattarella, Francesco, Pepe, Francesco V., Ulku, Arin, Giannella, Davide, Charbon, Edoardo, Bruschini, Claudio, and D'Angelo, Milena

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Optics

Abstract

The correlation properties of light provide an outstanding tool to overcome the limitations of traditional imaging techniques. A relevant case is represented by correlation plenoptic imaging (CPI), a quantum imaging protocol employing spatio-temporal correlations to address the main limitations of conventional light-field imaging, namely, the poor spatial resolution and the reduced change of perspective for 3D imaging. However, the application potential of high-resolution quantum imaging is limited, in practice, by the need to collect a large number of frames to retrieve correlations. This creates a gap, unacceptable for many relevant tasks, between the time performance of quantum imaging and that of traditional imaging methods. In this article, we address this issue by exploiting the photon number correlations intrinsic in chaotic light, in combination with a cutting-edge ultrafast sensor made of a large array of single-photon avalanche diodes (SPADs). A novel single-lens CPI scheme is employed to demonstrate quantum imaging at an acquisition speed of 10 volumetric images per second. Our results place quantum imaging at a competitive edge and prove its potential in practical applications., 15 pages, 6 figures

Published

2022