Next Issue
Volume 13, ICNFP 2018
Previous Issue
Volume 11, CA16112 - Luxemburg 2019
 
 
proceedings-logo

Journal Browser

Journal Browser

Proceedings, 2019, IQIS 2018

11th Italian Quantum Information Science Conference

Catania, Italy | 17–20 September 2018

Volume Editors:
G. Falci, Università di Catania, Italy
E. Paladino, Università di Catania, Italy
M. Palma, Università di Palermo, Italy
G. G. N. Angilella, Università di Catania, Italy
A. La Magna, CNR-IMM, Italy
F. M. D. Pellegrino, CNR-IMM, Italy

Number of Papers: 53
  • Issues are regarded as officially published after their release is announced to the table of contents alert mailing list.
  • You may sign up for e-mail alerts to receive table of contents of newly released issues.
  • PDF is the official format for papers published in both, html and pdf forms. To view the papers in pdf format, click on the "PDF Full-text" link, and use the free Adobe Reader to open them.
Cover Story (view full-size image): Since 2008, Italian Quantum Information Science (IQIS) conferences have aimed to bring together researchers in quantum information and related technologies. IQIS 2018 took place in Catania, Italy, at [...] Read more.
Order results
Result details
Select all
Export citation of selected articles as:

Editorial

Jump to: Other

4 pages, 5085 KiB  
Editorial
Quantum Information Science in Italy (IQIS 2018 Editorial)
by G. Falci, E. Paladino, G. M. Palma, G. G. N. Angilella, A. La Magna and F. M. D. Pellegrino
Proceedings 2019, 12(1), 1; https://doi.org/10.3390/proceedings2019012001 - 21 Jun 2019
Viewed by 2134
Abstract
The 11th Italian Quantum Information Science conference (IQIS 2018) took place in Catania, Italy, at the Monastero dei Benedettini, from September 17 to 20, 2018. IQIS 2018 was organized by the Department of Physics and Astronomy “E. Majorana” of the University of Catania, [...] Read more.
The 11th Italian Quantum Information Science conference (IQIS 2018) took place in Catania, Italy, at the Monastero dei Benedettini, from September 17 to 20, 2018. IQIS 2018 was organized by the Department of Physics and Astronomy “E. Majorana” of the University of Catania, and by IMM-CNR, Catania. The conference also hosted an event dedicated to the FET-Flagship 2018/28 on Quantum Technologies. These proceedings collect papers contributed by the participants, which extend presentations delivered at the conference, and were subjected to peer-reviewing. They provide a snapshot of the contributions (mainly, but only) by the Italian scientific community to the developing field of quantum information and related subjects. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

Other

Jump to: Editorial

4 pages, 270 KiB  
Proceeding Paper
Preserving Nonclassicality in Noisy Communication Channels
by Alessia Allevi and Maria Bondani
Proceedings 2019, 12(1), 3; https://doi.org/10.3390/proceedings2019012003 - 25 Jun 2019
Cited by 1 | Viewed by 1226
Abstract
Nowadays, the transmission of quantum information, especially for the distribution of cryptographic keys, is required on a global scale. The main obstacle to overcome in free-space communication is the presence of turbulence, which causes both spatial and temporal deformations of the light signals [...] Read more.
Nowadays, the transmission of quantum information, especially for the distribution of cryptographic keys, is required on a global scale. The main obstacle to overcome in free-space communication is the presence of turbulence, which causes both spatial and temporal deformations of the light signals that code information. Here we investigate the extent at which the transmission of mesoscopic twin-beam states through asymmetric noisy channels degrades the nonclassical nature of the photon-number correlations between signal and idler. We consider three nonclassicality criteria, all written in terms of measurable quantities, and demonstrate, both theoretically and experimentally, that the asymmetry introduced by losses affects the three criteria in different ways. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 403 KiB  
Proceeding Paper
Hilbert Space Structure Induced by Quantum Probes
by Go Kato, Masaki Owari and Koji Maruyama
Proceedings 2019, 12(1), 4; https://doi.org/10.3390/proceedings2019012004 - 25 Jun 2019
Viewed by 1246
Abstract
It is unrealistic to control all of the degrees of freedom of a high-dimensional quantum system. Here, we consider a scenario where our direct access is restricted to a small subsystem S that is constantly interacting with the rest of the system E [...] Read more.
It is unrealistic to control all of the degrees of freedom of a high-dimensional quantum system. Here, we consider a scenario where our direct access is restricted to a small subsystem S that is constantly interacting with the rest of the system E. What we investigate is the fundamental structures of the Hilbert space and the algebra of hamiltonians that are caused solely by the restrictedness of the direct control. One key finding is that hamiltonians form a Jordan algebra, and this leads to a significant observation that there is a sharp distinction between the cases of dimHS3 and dimHS = 2 in terms of the nature of possible operations in E. Since our analysis is totally free from specific properties of any physical systems, it would form a solid basis for obtaining deeper insights into quantum control related issues, such as controllability and observability. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 216 KiB  
Proceeding Paper
Entropy Area Law in Quantum Field Theories and Spin Systems
by Salvatore Mancani
Proceedings 2019, 12(1), 5; https://doi.org/10.3390/proceedings2019012005 - 3 Jun 2019
Viewed by 1582
Abstract
The entanglement entropy measures quantum correlations and it can be seen as the uncertainty on a quantum state. In one spatial dimension, the entanglement entropy scales as the boundary that divides two subsystems, so an area law has been proposed. However, the entanglement [...] Read more.
The entanglement entropy measures quantum correlations and it can be seen as the uncertainty on a quantum state. In one spatial dimension, the entanglement entropy scales as the boundary that divides two subsystems, so an area law has been proposed. However, the entanglement entropy diverges logarithmically at conformally invariant critical points, so the area law does not hold. The purpose of the work is to find a way to get more information about a critical state. The ground state of the Heisenberg XXZ model at criticality is analyzed by means of critical Ising eigenstates. Two ways of analysis are followed: a basis made of Ising eigenstates is built up and used to represent the XXZ ground state, then the Shannon entropy in the new basis is computed; the adiabatic evolution from the Ising ground state to the XXZ ground state. The result is that the Shannon entropy in the Ising basis scales linearly with the length of the system, while a phase transition is encountered during the adiabatic evolution. The conclusion is that there is no net gain in information after the procedure and possibly it is related to the fact the two systems stand in different phases. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 490 KiB  
Proceeding Paper
Coexistence of Different Scaling Laws for the Entanglement Entropy in a Periodically Driven System
by Tony J. G. Apollaro and Salvatore Lorenzo
Proceedings 2019, 12(1), 6; https://doi.org/10.3390/proceedings2019012006 - 25 Jun 2019
Viewed by 1168
Abstract
The out-of-equilibrium dynamics of many body systems has recently received a burst of interest, also due to experimental implementations. The dynamics of observables, such as magnetization and susceptibilities, and quantum information related quantities, such as concurrence and entanglement entropy, have been investigated under [...] Read more.
The out-of-equilibrium dynamics of many body systems has recently received a burst of interest, also due to experimental implementations. The dynamics of observables, such as magnetization and susceptibilities, and quantum information related quantities, such as concurrence and entanglement entropy, have been investigated under different protocols bringing the system out of equilibrium. In this paper we focus on the entanglement entropy dynamics under a sinusoidal drive of the tranverse magnetic field in the 1D quantum Ising model. We find that the area and the volume law of the entanglement entropy coexist under periodic drive for an initial non-critical ground state. Furthermore, starting from a critical ground state, the entanglement entropy exhibits finite size scaling even under such a periodic drive. This critical-like behaviour of the out-of-equilibrium driven state can persist for arbitrarily long time, provided that the entanglement entropy is evaluated on increasingly subsytem sizes, whereas for smaller sizes a volume law holds. Finally, we give an interpretation of the simultaneous occurrence of critical and non-critical behaviour in terms of the propagation of Floquet quasi-particles. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 287 KiB  
Proceeding Paper
Continuous Variable Entanglement in Non-Zero Orbital Angular Momentum States
by Adriana Pecoraro, Filippo Cardano, Lorenzo Marrucci and Alberto Porzio
Proceedings 2019, 12(1), 7; https://doi.org/10.3390/proceedings2019012007 - 11 Oct 2019
Cited by 1 | Viewed by 1234
Abstract
Orbital angular momentum is a discrete degree of freedom that can access an infinite dimensional Hilbert space, thus enhancing the information capacity of a single optical beam. Continuous variables field quadratures allow achieving some quantum tasks in a more advantageous way with respect [...] Read more.
Orbital angular momentum is a discrete degree of freedom that can access an infinite dimensional Hilbert space, thus enhancing the information capacity of a single optical beam. Continuous variables field quadratures allow achieving some quantum tasks in a more advantageous way with respect to the use of photon-number states. Here, we use a hybrid approach realizing bipartite continuous-variable Gaussian entangled state made up of two electromagnetic modes carrying orbital angular momentum. A q-plate is used for endowing a pair of entangled beams with such a degree of freedom. This quantum state is then completely characterized thanks to a novel design of a homodyne detector in which also the local oscillator is an orbital angular momentum-carrying beams so allowing the direct detection of vortex modes quadratures. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1823 KiB  
Proceeding Paper
Manipulating Quantum Many-Body Systems in the Presence of Controllable Dissipation
by Davide Rossini
Proceedings 2019, 12(1), 8; https://doi.org/10.3390/proceedings2019012008 - 25 Jun 2019
Viewed by 1264
Abstract
We discuss two quantum simulation schemes in which the coupling to an external bath may give rise to novel and interesting many-body physics. Namely, we first address the effect of local Markovian baths on the quantum annealing dynamics of an Ising-like chain: deviations [...] Read more.
We discuss two quantum simulation schemes in which the coupling to an external bath may give rise to novel and interesting many-body physics. Namely, we first address the effect of local Markovian baths on the quantum annealing dynamics of an Ising-like chain: deviations from adiabaticity may display a nonmonotonic trend as a function of the annealing time, as a result of the competition between nonadiabatic effects and dissipative processes. Secondly, we provide a framework to induce persistent currents through the coupling with a structured reservoir which generates nonreciprocity, without the need of any applied gauge field. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 957 KiB  
Proceeding Paper
Experimental Investigation of Quantum Decay via Integrated Photonics
by Andrea Crespi, Francesco V. Pepe, Paolo Facchi, Fabio Sciarrino, Paolo Mataloni, Hiromichi Nakazato, Saveri Pascazio and Roberto Osellame
Proceedings 2019, 12(1), 9; https://doi.org/10.3390/proceedings2019012009 - 11 Jun 2019
Cited by 1 | Viewed by 1404
Abstract
Whereas classical physics generally predicts an exponential trend for the temporal decay of an unstable state, quantum mechanics provides a rather different description. The decay is initially quadratic, while at very large times it follows a power-law. Actually, the latter regime has never [...] Read more.
Whereas classical physics generally predicts an exponential trend for the temporal decay of an unstable state, quantum mechanics provides a rather different description. The decay is initially quadratic, while at very large times it follows a power-law. Actually, the latter regime has never been observed experimentally. Here we employ arrays of femtosecond-laser-written optical waveguides to optically realize quantum systems where a discrete state is coupled to and can decay into a continuum. The transverse optical modes represent distinct quantum states of the photon and the temporal evolution of the system is mapped into the longitudinal propagation coordinate. By injecting laser light in the fabricated structures, and by imaging with high dynamic range the scattered light from above, we are able to observe experimentally different decay regimes, including the power-law tail. This process can be viewed as the quantum simulation of a quantum decay phenomenon. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 233 KiB  
Proceeding Paper
Two-Qubits in a Large-S Environment
by Eliana Fiorelli, Alessandro Cuccoli and Paola Verrucchi
Proceedings 2019, 12(1), 10; https://doi.org/10.3390/proceedings2019012010 - 13 Jun 2019
Cited by 1 | Viewed by 1549
Abstract
We analytically express the loss of entanglement between the components of a quantum device due to the generation of quantum correlations with its environment, and show that such loss diminishes when the latter is macroscopic and displays a semi-classical behaviour. We model the [...] Read more.
We analytically express the loss of entanglement between the components of a quantum device due to the generation of quantum correlations with its environment, and show that such loss diminishes when the latter is macroscopic and displays a semi-classical behaviour. We model the problem as a device made of a couple of qubits with a magnetic environment: this choice allows us to implement the above condition of semi-classical macroscopicity in terms of a large-S condition, according to the well known equivalence between classical and S limit. A possible strategy for protecting internal entanglement exploiting the mechanism of domain-formation typical of critical dynamics is also suggested. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

6 pages, 735 KiB  
Proceeding Paper
Advances in Sequential Measurement and Control of Open Quantum Systems
by Stefano Gherardini, Andrea Smirne, Matthias M. Müller and Filippo Caruso
Proceedings 2019, 12(1), 11; https://doi.org/10.3390/proceedings2019012011 - 24 Jun 2019
Cited by 5 | Viewed by 1410
Abstract
Novel concepts, perspectives and challenges in measuring and controlling an open quantum system via sequential schemes are shown. We discuss how similar protocols, relying both on repeated quantum measurements and dynamical decoupling control pulses, can allow to: (i) Confine and protect quantum dynamics [...] Read more.
Novel concepts, perspectives and challenges in measuring and controlling an open quantum system via sequential schemes are shown. We discuss how similar protocols, relying both on repeated quantum measurements and dynamical decoupling control pulses, can allow to: (i) Confine and protect quantum dynamics from decoherence in accordance with the Zeno physics. (ii) Analytically predict the probability that a quantum system is transferred into a target quantum state by means of stochastic sequential measurements. (iii) Optimally reconstruct the spectral density of environmental noise sources by orthogonalizing in the frequency domain the filter functions driving the designed quantum-sensor. The achievement of these tasks will enhance our capability to observe and manipulate open quantum systems, thus bringing advances to quantum science and technologies. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
5 pages, 280 KiB  
Proceeding Paper
Dynamical Casimir Effect and State Transfer in the Ultrastrong Coupling Regime
by Giuliano Benenti, Michele Stramacchia and Giuliano Strini
Proceedings 2019, 12(1), 12; https://doi.org/10.3390/proceedings2019012012 - 20 Jun 2019
Cited by 1 | Viewed by 1479
Abstract
The dynamical Casimir effect (DCE) manifests itself in the ultrastrong matter-field coupling (USC) regime, as a consequence of the nonadiabatic change of some parameters of a system. We show that the DCE is a fundamental limitation for standard quantum protocols based on quantum [...] Read more.
The dynamical Casimir effect (DCE) manifests itself in the ultrastrong matter-field coupling (USC) regime, as a consequence of the nonadiabatic change of some parameters of a system. We show that the DCE is a fundamental limitation for standard quantum protocols based on quantum Rabi oscillations, implying that new schemes are required to implement high-fidelity ultrafast quantum gates. Our results are illustrated by means of a paradigmatic quantum communication protocol, i.e., quantum state transfer. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 250 KiB  
Proceeding Paper
Privacy in Quantum Estimation
by Milajiguli Rexiti and Stefano Mancini
Proceedings 2019, 12(1), 13; https://doi.org/10.3390/proceedings2019012013 - 25 Jun 2019
Viewed by 1267
Abstract
We introduce the notion of privacy in quantum estimation by considering an one-parameter family of isometries taking one input into two output systems. It stems on the separate and adversarial control of the two output systems as well as on the local minimization [...] Read more.
We introduce the notion of privacy in quantum estimation by considering an one-parameter family of isometries taking one input into two output systems. It stems on the separate and adversarial control of the two output systems as well as on the local minimization of the mean square error. Applications to two-qubit unitaries (with one qubit in a fixed input state) are presented. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 255 KiB  
Proceeding Paper
Quantum Enhanced Optical Measurements: From Ultra-High Sensitivity in Absorption Measurements to Ghost Microscopy
by Elena Losero, Ivano Ruo-Berchera, Alessio Avella, Alice Meda and Marco Genovese
Proceedings 2019, 12(1), 14; https://doi.org/10.3390/proceedings2019012014 - 25 Jul 2019
Viewed by 1383
Abstract
Quantum enhanced optical measurement protocols aim at reducing the uncertainty in the estimation of some physical quantities of a system below the shot-noise limit, classically unavoidable. In particular when small number of photons is used the shot noise can be the main source [...] Read more.
Quantum enhanced optical measurement protocols aim at reducing the uncertainty in the estimation of some physical quantities of a system below the shot-noise limit, classically unavoidable. In particular when small number of photons is used the shot noise can be the main source of uncertainty, in these cases the use of quantum light is of great interest. Note that there are several situations where the number of photons in the probe can not be increased arbitrarily, as when fragile biological samples are under investigation. Two different imaging protocols are discussed in the following. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 296 KiB  
Proceeding Paper
Continuous and Pulsed Quantum Control
by Giovanni Gramegna, Daniel Burgarth, Paolo Facchi and Saverio Pascazio
Proceedings 2019, 12(1), 15; https://doi.org/10.3390/proceedings2019012015 - 24 Jun 2019
Cited by 1 | Viewed by 1405
Abstract
We consider two alternative procedures which can be used to control the evolution of a generic finite-dimensional quantum system, one hinging upon a strong continuous coupling with a control potential and the other based on the application of frequently repeated pulses onto the [...] Read more.
We consider two alternative procedures which can be used to control the evolution of a generic finite-dimensional quantum system, one hinging upon a strong continuous coupling with a control potential and the other based on the application of frequently repeated pulses onto the system. Despite the practical and conceptual difference between them, they lead to the same dynamics, characterised by a partitioning of the Hilbert space into sectors among which transitions are inhibited by dynamical superselection rules. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 268 KiB  
Proceeding Paper
Ferromagnetic Josephson Junctions for High Performance Computation
by Roberta Caruso, Davide Massarotti, Alessandro Miano, Vitaly V. Bolginov, Aymen Ben Hamida, Liubov N. Karelina, Igor V. Vernik, Valery V. Ryazanov, Oleg A. Mukhanov, Giovanni Piero Pepe and Francesco Tafuri
Proceedings 2019, 12(1), 16; https://doi.org/10.3390/proceedings2019012016 - 25 Jun 2019
Viewed by 1664
Abstract
Josephson junctions drive the operation of superconducting qubits and they are the key for the coupling and the interfacing of superconducting qubit components with other quantum platforms. They are the only means to introduce non linearity in a superconducting circuit and offer direct [...] Read more.
Josephson junctions drive the operation of superconducting qubits and they are the key for the coupling and the interfacing of superconducting qubit components with other quantum platforms. They are the only means to introduce non linearity in a superconducting circuit and offer direct solutions to tune the properties of a superconducting qubit, thus enlarging the possible qubit layouts. Junctions performances and tunability can take advantage of using a large variety of barriers and their special functionalities. We mention pertinent results on the advances in understanding the properties of ferromagnetic junctions, which makepossible the use of these devices either as memory elements and as core circuit elements. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 279 KiB  
Proceeding Paper
The Friedrichs-Lee Model and Its Singular Coupling Limit
by Davide Lonigro, Paolo Facchi and Marilena Ligabò
Proceedings 2019, 12(1), 17; https://doi.org/10.3390/proceedings2019012017 - 24 Jun 2019
Cited by 3 | Viewed by 1617
Abstract
Lee’s field-theoretical model describes the interaction between a qubit and a structured bosonic field. We study the mathematical properties of the Hamiltonian of the single-excitation sector of the theory, including a possibly “singular” qubit-field coupling (i.e., mediated by a non-square integrable form factor). [...] Read more.
Lee’s field-theoretical model describes the interaction between a qubit and a structured bosonic field. We study the mathematical properties of the Hamiltonian of the single-excitation sector of the theory, including a possibly “singular” qubit-field coupling (i.e., mediated by a non-square integrable form factor). This result allows for a rigorous description of qubit-field interactions in many physically interesting systems and may be extended to higher-excitation sectors of the theory. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 190 KiB  
Proceeding Paper
Exciting Dressed BICs Via Photon Scattering and Delayed Quantum Feedback
by Giuseppe Calajó, Yao-Lung L. Fang, Harold U. Baranger and Francesco Ciccarello
Proceedings 2019, 12(1), 18; https://doi.org/10.3390/proceedings2019012018 - 2 Jul 2019
Viewed by 1622
Abstract
We consider a semi-infinite waveguide with linear dispersion coupled to a qubit, in which a dressed bound state in the continuum (BIC) is known to exist. We predict that this BIC can be excited with significant probability via multi-photon scattering in the non-Markovian [...] Read more.
We consider a semi-infinite waveguide with linear dispersion coupled to a qubit, in which a dressed bound state in the continuum (BIC) is known to exist. We predict that this BIC can be excited with significant probability via multi-photon scattering in the non-Markovian regime where the photon delay time (corresponding to the qubit-mirror distance) is of the order of the qubit’s decay time. A similar process excites the BIC existing in an infinite waveguide coupled to a pair of qubits, yielding stationary entanglement between them. This shows, in particular, that photon trapping via scattering can occur without band-edge effects or cavities, the essential resource being instead the delayed quantum feedback due to the mirror. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
5 pages, 202 KiB  
Proceeding Paper
Slow Dynamics and Thermodynamics of Open Quantum Systems
by Vasco Cavina, Andrea Mari and Vittorio Giovannetti
Proceedings 2019, 12(1), 19; https://doi.org/10.3390/proceedings2019012019 - 10 Jul 2019
Cited by 1 | Viewed by 1249
Abstract
We develop a perturbation theory to estimate the finite time corrections around a quasi static trajectory, in which a quantum system is able to equilibrate at each instant with its environment. The results are then applied to non equilibrium thermodynamics, in which context [...] Read more.
We develop a perturbation theory to estimate the finite time corrections around a quasi static trajectory, in which a quantum system is able to equilibrate at each instant with its environment. The results are then applied to non equilibrium thermodynamics, in which context we are able to provide a connection between the irreversible contributions and the microscopic details of the dynamical map generating the evolution. Turning the attention to finite time Carnot engines, we found a universal connection between the spectral density esponent of the hot/cold thermal baths and the efficiency at maximum power, giving also a new interpretation to already known results such as the Curzon-Ahborn and the Schmiedl-Seifert efficiencies. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
5 pages, 258 KiB  
Proceeding Paper
Grassmannization of the 3D Ising Model
by E. Martello, G. G. N. Angilella and L. Pollet
Proceedings 2019, 12(1), 20; https://doi.org/10.3390/proceedings2019012020 - 6 Jun 2019
Viewed by 1392
Abstract
The application of Feynman’s diagrammatic technique to classical link models with local constraints seems impossible due to (i) the absence of a free Gaussian theory on top of which the perturbative expansion can be constructed, and (ii) Dyson’s collapse argument, rendering the perturbative [...] Read more.
The application of Feynman’s diagrammatic technique to classical link models with local constraints seems impossible due to (i) the absence of a free Gaussian theory on top of which the perturbative expansion can be constructed, and (ii) Dyson’s collapse argument, rendering the perturbative expansion divergent. However, we show for the classical 3D Ising model how both problems can be circumvented using a Grassmann representation. This makes it possible to obtain an expansion of the spin correlation function and the magnetic susceptibility in terms of the inverse temperature in the thermodynamic limit, through which the values for the critical temperature and critical index g are evaluated within 1.6% and 5.4% of their accepted values, respectively. Our work is a straightforward adaptation of the theory previously developed in an earlier paper. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

3 pages, 193 KiB  
Proceeding Paper
Supervised Quantum State Discrimination
by Marco Fanizza, Andrea Mari and Vittorio Giovannetti
Proceedings 2019, 12(1), 21; https://doi.org/10.3390/proceedings2019012021 - 19 Jul 2019
Cited by 1 | Viewed by 1097
Abstract
Combining machine learning and quantum information. [...] Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
4 pages, 262 KiB  
Proceeding Paper
Extraction of Work via a Thermalization Protocol
by Nicolò Piccione, Benedetto Militello, Anna Napoli and Bruno Bellomo
Proceedings 2019, 12(1), 22; https://doi.org/10.3390/proceedings2019012022 - 4 Jul 2019
Cited by 1 | Viewed by 1539
Abstract
This extended abstract contains an outline of the work reported at the conference IQIS2018. We show that it is possible to exploit a thermalization process to extract work from a resource system R to a bipartite system S. To do this, we [...] Read more.
This extended abstract contains an outline of the work reported at the conference IQIS2018. We show that it is possible to exploit a thermalization process to extract work from a resource system R to a bipartite system S. To do this, we propose a simple protocol in a general setting in the presence of a single bath at temperature T and then examine it when S is described by the quantum Rabi model at T = 0 . We find the theoretical bounds of the protocol in the general case and we show that when applied to the Rabi model it gives rise to a satisfactory extraction of work and efficiency. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 1025 KiB  
Proceeding Paper
Effects of Indistinguishability in a System of Three Identical Qubits
by Alessia Castellini, Rosario Lo Franco and Giuseppe Compagno
Proceedings 2019, 12(1), 23; https://doi.org/10.3390/proceedings2019012023 - 22 Jul 2019
Cited by 1 | Viewed by 1484
Abstract
Quantum correlations of identical particles are important for quantum-enhanced technologies. The recently introduced non-standard approach to treat identical particles is here exploited to show the effect of particle indistinguishability on the characterization of entanglement of three identical qubits. We show that, by spatially [...] Read more.
Quantum correlations of identical particles are important for quantum-enhanced technologies. The recently introduced non-standard approach to treat identical particles is here exploited to show the effect of particle indistinguishability on the characterization of entanglement of three identical qubits. We show that, by spatially localized measurements in separated regions, three independently-prepared separated qubits in a pure elementary state behave as distinguishable ones, as expected. On the other hand, delocalized measurements make it emerge a measurement-induced entanglement. We then find that three independently-prepared boson qubits under complete spatial overlap exhibit genuine three-partite entanglement. These results evidence the effect of spatial overlap on identical particle entanglement and show that the latter depends on both the quantum state and the type of measurement. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

6 pages, 451 KiB  
Proceeding Paper
Digital Quantum Simulations of Spin Models on Hybrid Platform and Near-Term Quantum Processors
by Francesco Tacchino, Alessandro Chiesa, Matthew D. LaHaye, Ivano Tavernelli, Stefano Carretta and Dario Gerace
Proceedings 2019, 12(1), 24; https://doi.org/10.3390/proceedings2019012024 - 9 Jul 2019
Viewed by 1255
Abstract
Digital quantum simulators are among the most appealing applications. [...] Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1542 KiB  
Proceeding Paper
Dissipative Synthesis of Mechanical Fock-Like States
by Matteo Brunelli and Oussama Houhou
Proceedings 2019, 12(1), 25; https://doi.org/10.3390/proceedings2019012025 - 19 Jul 2019
Viewed by 1386
Abstract
The observation of genuine quantum features of nano-mechanical motion is a key goal for both fundamental and applied quantum science. To this end, a promising approach is the stabilization of nonclassical features in the presence of dissipation, by means of the tunable coupling [...] Read more.
The observation of genuine quantum features of nano-mechanical motion is a key goal for both fundamental and applied quantum science. To this end, a promising approach is the stabilization of nonclassical features in the presence of dissipation, by means of the tunable coupling with a photonic environment. Here we present a scheme that combines dissipative squeezing with a mechanical nonlinearity to stabilize arbitrary approximations of (displaced) mechanical Fock state of any number. We consider an optomechanical system driven by three control lasers---at the cavity resonance and at the two mechanical sidebands---that couple the amplitude of the cavity field to the resonator's position and position squared. When the amplitude of the resonant drive is tuned to some specific values, the mechanical steady state is found in a (displaced) superposition of a finite number of Fock states, which for large enough squeezing achieves near-unit fidelity with a (displaced) Fock state of any desired number. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 497 KiB  
Proceeding Paper
May a Dissipative Environment Be Beneficial for Quantum Annealing?
by Gianluca Passarelli, Giulio De Filippis, Vittorio Cataudella and Procolo Lucignano
Proceedings 2019, 12(1), 26; https://doi.org/10.3390/proceedings2019012026 - 9 Jul 2019
Viewed by 1246
Abstract
We discuss the quantum annealing of the fully-connected ferromagnetic p-spin model in a dissipative environment at low temperature. This model, in the large p limit, encodes in its ground state the solution to the Grover’s problem of searching in unsorted databases. In [...] Read more.
We discuss the quantum annealing of the fully-connected ferromagnetic p-spin model in a dissipative environment at low temperature. This model, in the large p limit, encodes in its ground state the solution to the Grover’s problem of searching in unsorted databases. In the framework of the quantum circuit model, a quantum algorithm is known for this task, providing a quadratic speed-up with respect to its best classical counterpart. This improvement is not recovered in adiabatic quantum computation for an isolated quantum processor. We analyze the same problem in the presence of a low-temperature reservoir, using a Markovian quantum master equation in Lindblad form, and we show that a thermal enhancement is achieved in the presence of a zero temperature environment moderately coupled to the quantum annealer. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

7 pages, 538 KiB  
Proceeding Paper
Experimental Connection between the Instrumental and Bell Inequalities
by Iris Agresti, Gonzalo Carvacho, Davide Poderini, Leandro Aolita, Rafael Chaves and Fabio Sciarrino
Proceedings 2019, 12(1), 27; https://doi.org/10.3390/proceedings2019012027 - 18 Jul 2019
Cited by 5 | Viewed by 1609
Abstract
An investigated process can be studied in terms of the causal relations among the involved variables, representing it as a causal model. Some causal models are particularly relevant, since they can be tested through mathematical constraints between the joint probability distributions of the [...] Read more.
An investigated process can be studied in terms of the causal relations among the involved variables, representing it as a causal model. Some causal models are particularly relevant, since they can be tested through mathematical constraints between the joint probability distributions of the observables. This is a valuable tool because, if some data violates the constraints of a causal model, the implication is that the observed statistics is not compatible with that causal structure. Strikingly, when non-classical correlations come to play, a discrepancy between classical and quantum causal predictions can arise, producing a quantum violation of the classical causal constraints. The simplest
scenario admitting such quantum violation is given by the instrumental causal processes. Here, we experimentally violate an instrumental test on a photonic platform and show how the quantum correlations violating the CHSH inequality can be mapped into correlations violating an instrumental test, despite the different forms of non-locality they display. Indeed, starting from a Bell-like scenario, we recover the violation of the instrumental scenario through a map between the two behaviours, which includes a post-selection of data and then we test an alternative way to violate the CHSH inequality, adopting the instrumental process platform. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1003 KiB  
Proceeding Paper
Machine Learning for Quantum Metrology
by Nicolò Spagnolo, Alessandro Lumino, Emanuele Polino, Adil S. Rab, Nathan Wiebe and Fabio Sciarrino
Proceedings 2019, 12(1), 28; https://doi.org/10.3390/proceedings2019012028 - 23 Aug 2019
Cited by 1 | Viewed by 2178
Abstract
Phase estimation represents a significant example to test the application of quantum theory for enhanced measurements of unknown physical parameters. Several recipes have been developed, allowing to define strategies to reach the ultimate bounds in the asymptotic limit of a large number of [...] Read more.
Phase estimation represents a significant example to test the application of quantum theory for enhanced measurements of unknown physical parameters. Several recipes have been developed, allowing to define strategies to reach the ultimate bounds in the asymptotic limit of a large number of trials. However, in certain applications it is crucial to reach such bound when only a small number of probes is employed. Here, we discuss an asymptotically optimal, machine learning based, adaptive single-photon phase estimation protocol that allows us to reach the standard quantum limit when a very limited number of photons is employed. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

8 pages, 293 KiB  
Proceeding Paper
Quantum Sensing 1/f Noise via Pulsed Control of a Two-Qubit Gate
by Antonio D’Arrigo, Giuseppe Falci and Elisabetta Paladino
Proceedings 2019, 12(1), 29; https://doi.org/10.3390/proceedings2019012029 - 25 Jul 2019
Cited by 1 | Viewed by 1175
Abstract
Dynamical decoupling sequences are a convenient tool to reduce decoherence due to intrinsic fluctuations with 1 / f power spectrum hindering quantum circuits. We study the possibility to achieve an efficient universal two-qubit gate in the presence of 1 / f noise by [...] Read more.
Dynamical decoupling sequences are a convenient tool to reduce decoherence due to intrinsic fluctuations with 1 / f power spectrum hindering quantum circuits. We study the possibility to achieve an efficient universal two-qubit gate in the presence of 1 / f noise by periodic and Carr-Purcell dynamical decoupling. The high degree of selectivity achieved by these protocols also provides a valuable tool to infer noise characteristics, as the high-frequency cut off and the noise variance. Different scalings of the gate error with noise variance signal the contribution of different noise statistical properties to the gate error. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
6 pages, 228 KiB  
Proceeding Paper
Kick and Fix: The Roots of Quantum Control
by Paolo Facchi and Saverio Pascazio
Proceedings 2019, 12(1), 30; https://doi.org/10.3390/proceedings2019012030 - 19 Jul 2019
Cited by 3 | Viewed by 1281
Abstract
When two operators A and B do not commute, the calculation of the exponential operator e A + B is a difficult and crucial problem. The applications are vast and diversified: to name but a few examples, quantum evolutions, product formulas, quantum control, [...] Read more.
When two operators A and B do not commute, the calculation of the exponential operator e A + B is a difficult and crucial problem. The applications are vast and diversified: to name but a few examples, quantum evolutions, product formulas, quantum control, Zeno effect. The latter are of great interest in quantum applications and quantum technologies. We present here a historical survey of results and techniques, and discuss differences and similarities. We also highlight the link with the strong coupling regime, via the adiabatic theorem, and contend that the “pulsed” and “continuous” formulations differ only in the order by which two limits are taken, and are but two faces of the same coin. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
3 pages, 294 KiB  
Proceeding Paper
Reciprocal Quantum Channels
by Vittorio Giovannetti and Matteo Rosati
Proceedings 2019, 12(1), 31; https://doi.org/10.3390/proceedings2019012031 - 19 Jul 2019
Viewed by 1180
Abstract
We report the presence of an asymmetry that arises when considering the performances of quantum communication channels whose outputs are connected via a rigid, distance-preserving, yet not completely-positive, transformation. From a classical perspective these transmission lines should exhibit the same communication efficiency which [...] Read more.
We report the presence of an asymmetry that arises when considering the performances of quantum communication channels whose outputs are connected via a rigid, distance-preserving, yet not completely-positive, transformation. From a classical perspective these transmission lines should exhibit the same communication efficiency which is lost in the quantum setting. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

6 pages, 2538 KiB  
Proceeding Paper
Tailoring Active Defect Centers During the Growth of Group IV Crystals
by Michele Cascio, Ioannis Deretzis, Giuseppe Fisicaro, Giuseppe Falci, Giovanni Mannino and Antonino La Magna
Proceedings 2019, 12(1), 32; https://doi.org/10.3390/proceedings2019012032 - 19 Dec 2019
Viewed by 1058
Abstract
Defects, e.g., Vacancies (Vs) and Defect-impurity centers, e.g., Nitrogen-Vacancy complexes (NVs), in group IV materials (diamond, SiC, graphene) are unique systems for Quantum Technologies (QT). The control of their positioning is a key issue for any realistic QT application and their tailored inclusion [...] Read more.
Defects, e.g., Vacancies (Vs) and Defect-impurity centers, e.g., Nitrogen-Vacancy complexes (NVs), in group IV materials (diamond, SiC, graphene) are unique systems for Quantum Technologies (QT). The control of their positioning is a key issue for any realistic QT application and their tailored inclusion during controlled crystal-growth processes could overcome the limitations of other incorporation methods (e.g., ion implantation causing strong lattice damage). To date, the atomistic evolution regarding the growth of group IV crystals is barely known and this missing knowledge often results in a lack of process control in terms of mesoscopic crystal quality, mainly concerning the eventual generation of local or extended defects and their space distribution. We have developed Kinetic Monte Carlo models to study the growth kinetics of materials characterized by sp 3 bonding symmetries with an atomic-level accuracy. The models can be also coupled to the continuum simulation of the gas-phase status generated in the equipment to estimate the deposition rate and reproduce a variety of growth techniques (e.g., Chemical and Physical Vapour deposition, sublimation, etc.). Evolution is characterized by nucleation and growth of ideal or defective structures and their balance depends critically on process-related parameters. Quantitative predictions of the process evolution can be obtained and readily compared with the structural characterization of the processed samples. In particular, we can describe the surface state of the crystal and the defect generation/evolution (for both point and extended defects, e.g., stacking faults) as a function of the initial substrate conditions and the process parameters (e.g., temperature, pressure, gas flow). Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

6 pages, 373 KiB  
Proceeding Paper
Graphene Josephson Junction Quantum Circuits for Noise Detection
by Francesco Maria Dimitri Pellegrino, Giuseppe Falci and Elisabetta Paladino
Proceedings 2019, 12(1), 33; https://doi.org/10.3390/proceedings2019012033 - 24 Jul 2019
Cited by 4 | Viewed by 1668
Abstract
Graphene Josephson Junctions (GJJ) in the regime of ballistic transport where current is carried by discrete energy states of Andreev-reflected coherent electron-hole pairs have been recently demonstrated in graphene heterostructures. Due to the non-linear current-phase relation, GJJ can be used as a sensitive [...] Read more.
Graphene Josephson Junctions (GJJ) in the regime of ballistic transport where current is carried by discrete energy states of Andreev-reflected coherent electron-hole pairs have been recently demonstrated in graphene heterostructures. Due to the non-linear current-phase relation, GJJ can be used as a sensitive probe of underlying microscopic noise sources. Here, we find an analytic expression for the supercurrent-phase relation in the finite low doping regime, and we sketch how a GJJ quantum circuit can play the role of noise quantum sensor. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

7 pages, 249 KiB  
Proceeding Paper
Incompatibility in Multi-Parameter Quantum Metrology with Fermionic Gaussian States
by Angelo Carollo, Bernardo Spagnolo and Davide Valenti
Proceedings 2019, 12(1), 34; https://doi.org/10.3390/proceedings2019012034 - 31 Jul 2019
Viewed by 1641
Abstract
In this article we derive a closed form expression for the incompatibility condition in multi-parameter quantum metrology when the reference states are Fermionic Gaussian states. Together with the quantum Fisher information, the knowledge of the compatibility condition provides a way of designing optimal [...] Read more.
In this article we derive a closed form expression for the incompatibility condition in multi-parameter quantum metrology when the reference states are Fermionic Gaussian states. Together with the quantum Fisher information, the knowledge of the compatibility condition provides a way of designing optimal measurement strategies for multi-parameter quantum estimation. Applications range from quantum metrology with thermal states to non-equilibrium steady states with Fermionic and spin systems. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
5 pages, 813 KiB  
Proceeding Paper
Speedup of Adiabatic Multiqubit State-Transfer by Ultrastrong Coupling of Matter and Radiation
by Michele Stramacchia, Alessandro Ridolfo, Giuliano Benenti, Elisabetta Paladino, Francesco Maria Dimitri Pellegrino, Daniele Maccarrone and Giuseppe Falci
Proceedings 2019, 12(1), 35; https://doi.org/10.3390/proceedings2019012035 - 23 Jul 2019
Cited by 2 | Viewed by 1401
Abstract
Ultrastrongly coupled quantum hardware may increase the speed of quantum state processing in distributed architectures, allowing to approach fault-tolerant threshold. We show that circuit QED architectures in the ultrastrong coupling regime, which has been recently demonstrated with superconductors, may show substantial speedup for [...] Read more.
Ultrastrongly coupled quantum hardware may increase the speed of quantum state processing in distributed architectures, allowing to approach fault-tolerant threshold. We show that circuit QED architectures in the ultrastrong coupling regime, which has been recently demonstrated with superconductors, may show substantial speedup for a class of adiabatic protocols resilient to the main source of errors, namely the interplay of dynamical Casimir effect and cavity losses. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1792 KiB  
Proceeding Paper
Entanglement Assisted Transport of Two Walkers in Noisy Quantum Networks
by Maja Colautti and Filippo Caruso
Proceedings 2019, 12(1), 36; https://doi.org/10.3390/proceedings2019012036 - 25 Oct 2019
Viewed by 1101
Abstract
Understanding the transport mechanisms and properties of complex networks is fundamental for the comprehension of a vast class of phenomena, from state transfer on a spin network to light-harvesting in photosynthetic complexes. It has been theoretically and experimentally demonstrated that noise can enhance [...] Read more.
Understanding the transport mechanisms and properties of complex networks is fundamental for the comprehension of a vast class of phenomena, from state transfer on a spin network to light-harvesting in photosynthetic complexes. It has been theoretically and experimentally demonstrated that noise can enhance transport when the system parameters are properly tuned, an effect known as noise-assisted transport (NAT). In this work we investigate the role of initial entanglement in the transfer efficiency of two walkers in a noisy network. By using the formalism of quantum walks, we define a range of small dephasing noise where initial site-entanglement provides transport enhancement and outperforms the NAT effect. Furthermore, we show two specific scenarios where entanglement-assisted transport can open faster channels for slow walkers and avoid a broken link in a communication line. These findings may be of potential interest for quantum technologies. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

6 pages, 4380 KiB  
Proceeding Paper
Generation of Photon Pairs in the Light-Matter Ultrastrong Coupling Regime: From Casimir Radiation to Stimulated Raman Adiabatic Passage
by Alessandro Ridolfo
Proceedings 2019, 12(1), 37; https://doi.org/10.3390/proceedings2019012037 - 23 Jul 2019
Viewed by 1243
Abstract
The ultrastrong coupling regime of light-matter interaction is achieved when the coupling strength is a significant fraction of the natural frequencies of the noninteracting parts. Physics in this regime has recently attracted great interest, both theoretically and experimentally being a fruitful platform to [...] Read more.
The ultrastrong coupling regime of light-matter interaction is achieved when the coupling strength is a significant fraction of the natural frequencies of the noninteracting parts. Physics in this regime has recently attracted great interest, both theoretically and experimentally being a fruitful platform to test fundamental quantum mechanics in a new non-perturbative regime, and for applications to quantum technologies.Here we discuss the generation of photon-pair states, which is a distinctive feature of this new regime, and interesting new dynamicsl effects both in optomechanics and in circuit-QED architectures. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 220 KiB  
Proceeding Paper
Efficiently Compressible Density Operators via Entropy Maximization
by Serena Di Giorgio and Paulo Mateus
Proceedings 2019, 12(1), 39; https://doi.org/10.3390/proceedings2019012039 - 2 Aug 2019
Cited by 1 | Viewed by 1370
Abstract
We address the problem of efficiently and effectively compress density operators (DOs), by providing an efficient procedure for learning the most likely DO, given a chosen set of partial information. We explore, in the context of quantum information theory, the generalisation of [...] Read more.
We address the problem of efficiently and effectively compress density operators (DOs), by providing an efficient procedure for learning the most likely DO, given a chosen set of partial information. We explore, in the context of quantum information theory, the generalisation of the maximum entropy estimator for DOs, when the direct dependencies between the subsystems are provided. As a preliminary analysis, we restrict the problem to tripartite systems when two marginals are known. When the marginals are compatible with the existence of a quantum Markov chain (QMC) we show that there exists a recovery procedure for the maximum entropy estimator, and moreover, that for these states many well-known classical results follow. Furthermore, we notice that, contrary to the classical case, two marginals, compatible with some tripartite state, might not be compatible with a QMC. Finally, we provide a new characterisation of quantum conditional independence in light of maximum entropy updating. At this level, all the Hilbert spaces are considered finite dimensional. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
5 pages, 584 KiB  
Proceeding Paper
Degradation and Protection of Entanglement in Open Quantum Systems
by Antonella De Pasquale
Proceedings 2019, 12(1), 40; https://doi.org/10.3390/proceedings2019012040 - 23 Jul 2019
Viewed by 1259
Abstract
The distribution of entangled quantum systems among the nodes of a network is a key task at the basis of the development of quantum technologies, e.g., quantum communication, quantum computation, etc. Many efforts have been devoted to identify strategies, based on pre- and [...] Read more.
The distribution of entangled quantum systems among the nodes of a network is a key task at the basis of the development of quantum technologies, e.g., quantum communication, quantum computation, etc. Many efforts have been devoted to identify strategies, based on pre- and post-processing operations or decoherence-free subspaces, to prevent the deterioration of such exotic correlations. However, all these approaches loose their usefulness when the noise level affecting the system surpasses a certain minimal threshold that leads to an entanglement-breaking dynamics. Here we attack this problem in the context of discrete- and continuous-time description of the system dynamics, providing some explicit examples in the context of qubit channels. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1116 KiB  
Proceeding Paper
Observing the Spectral Collapse of Two-Photon Interaction Models
by Simone Felicetti and Alexandre Le Boité
Proceedings 2019, 12(1), 41; https://doi.org/10.3390/proceedings2019012041 - 22 Jul 2019
Viewed by 1377
Abstract
Until very recently, two-photon interaction processes have been considered only as arising from second- or higher-order effects in driven systems, and so limited to extremely small coupling strengths. However, a variety of novel physical phenomena emerges in the strong and ultrastrong coupling regimes. [...] Read more.
Until very recently, two-photon interaction processes have been considered only as arising from second- or higher-order effects in driven systems, and so limited to extremely small coupling strengths. However, a variety of novel physical phenomena emerges in the strong and ultrastrong coupling regimes. Strikingly, for a critical value of the coupling strength the discrete spectrum collapses into a continuous band. In this extended abstract, we discuss recent proposals to implement genuine two-photon interactions in an undriven solid-state system, in the framework of circuit QED. In particular, we review counterintuitive spectral features of two-photon interaction models and we show how the onset of the spectral collapse can be observed in feasible scattering experiments. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 205 KiB  
Proceeding Paper
Non-Equilibrium Phenomena in Quantum Systems, Criticality and Metastability
by Angelo Carollo, Bernardo Spagnolo and Davide Valenti
Proceedings 2019, 12(1), 43; https://doi.org/10.3390/proceedings2019012043 - 29 Sep 2019
Viewed by 1167
Abstract
We summarise here some relevant results related to non-equilibrium quantum systems. We characterise quantum phase transitions (QPT) in out-of-equilibrium quantum systems through a novel approach based on geometrical and topological properties of mixed quantum systems. We briefly describe results related to non-perturbative studies [...] Read more.
We summarise here some relevant results related to non-equilibrium quantum systems. We characterise quantum phase transitions (QPT) in out-of-equilibrium quantum systems through a novel approach based on geometrical and topological properties of mixed quantum systems. We briefly describe results related to non-perturbative studies of the bistable dynamics of a quantum particle coupled to an environment. Finally, we shortly summarise recent studies on the generation of solitons in current-biased long Josephson junctions. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
4 pages, 1288 KiB  
Proceeding Paper
Manipulation of Cooper Pair Entanglement in Hybrid Topological Josephson Junctions
by Gianmichele Blasi, Fabio Taddei, Vittorio Giovannetti and Alessandro Braggio
Proceedings 2019, 12(1), 44; https://doi.org/10.3390/proceedings2019012044 - 16 Sep 2019
Viewed by 955
Abstract
The non-local manipulation of spin-entangled states by means of local gating in two parallel 2D topological insulators properly connected to two superconducting electrodes is studied. We calculate analytically the current-phase relationship of the Josephson current making use of the scattering matrix approach and [...] Read more.
The non-local manipulation of spin-entangled states by means of local gating in two parallel 2D topological insulators properly connected to two superconducting electrodes is studied. We calculate analytically the current-phase relationship of the Josephson current making use of the scattering matrix approach and we identify the various local and non-local scattering mechanisms. We show that the Josephson critical current, remarkably, allows a direct quantification of the entanglement manipulation. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 235 KiB  
Proceeding Paper
Continuous Measurements for Advanced Quantum Metrology
by Francesco Albarelli, Matteo A. C. Rossi, Dario Tamascelli and Marco G. Genoni
Proceedings 2019, 12(1), 47; https://doi.org/10.3390/proceedings2019012047 - 4 Dec 2019
Viewed by 1617
Abstract
We review some recent results regarding the use of time-continuous measurements for quantum-enhanced metrology. First, we present the underlying quantum estimation framework and elucidate the correct figures of merit to employ. We then report results from two previous works where the system of [...] Read more.
We review some recent results regarding the use of time-continuous measurements for quantum-enhanced metrology. First, we present the underlying quantum estimation framework and elucidate the correct figures of merit to employ. We then report results from two previous works where the system of interest is an ensemble of two-level atoms (qubits) and the quantity to estimate is a magnetic field along a known direction (a frequency). In the first case, we show that, by continuously monitoring the collective spin observable transversal to the encoding Hamiltonian, we get Heisenberg scaling for the achievable precision (i.e., 1 / N for N atoms); this is obtained for an uncorrelated initial state. In the second case, we consider independent noises acting separately on each qubit and we show that the continuous monitoring of all the environmental modes responsible for the noise allows us to restore the Heisenberg scaling of the precision, given an initially entangled GHZ state. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
4 pages, 353 KiB  
Proceeding Paper
Measuring Nonclassicality of Mesoscopic Twin-Beam States with Silicon Photomultipliers
by Giovanni Chesi, Luca Malinverno, Alessia Allevi, Romualdo Santoro, Massimo Caccia and Maria Bondani
Proceedings 2019, 12(1), 48; https://doi.org/10.3390/proceedings2019012048 - 19 Nov 2019
Viewed by 1146
Abstract
The study of nonclassical properties of quantum states is a relevant topic for fundamental Quantum Optics and Quantum Information applications. In the mesoscopic domain, promising results have been obtained using photon-number-resolving detectors. Here we show recent results achieved with the class of Silicon [...] Read more.
The study of nonclassical properties of quantum states is a relevant topic for fundamental Quantum Optics and Quantum Information applications. In the mesoscopic domain, promising results have been obtained using photon-number-resolving detectors. Here we show recent results achieved with the class of Silicon Photomultipliers: by a proper analysis of the output signal, the nonclassicality of twin-beam states can be detected and exploited. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 196 KiB  
Proceeding Paper
Two-Level Systems with Broken Inversion Symmetry
by Giovanni Scala
Proceedings 2019, 12(1), 49; https://doi.org/10.3390/proceedings2019012049 - 20 Nov 2019
Viewed by 1030
Abstract
This research analyzes the impact of the asymmetry of the quantum system and the range of control possibilities offered by dispersive media and the nanostructures. I investigated the asymmetric behavior of a two level system in the Jaynes-Cummings model (JC) and in the [...] Read more.
This research analyzes the impact of the asymmetry of the quantum system and the range of control possibilities offered by dispersive media and the nanostructures. I investigated the asymmetric behavior of a two level system in the Jaynes-Cummings model (JC) and in the spontaneous emission process discussing respectively the presence of a non trivial emission at the Rabi frequency and the correction at a much more basic level, i.e., in the lifetime of the excited state, and also affect the value of the Lamb shift with broken symmetry in the diagonal terms of dipole moment. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
4 pages, 514 KiB  
Proceeding Paper
Dissipative Frustration in a One Dimensional Josephson Junction Chain
by Dominik Maile, Sabine Andergassen, Wolfgang Belzig and Gianluca Rastelli
Proceedings 2019, 12(1), 51; https://doi.org/10.3390/proceedings2019012051 - 19 Nov 2019
Viewed by 1267
Abstract
We study the influence of dissipative frustration on the one dimensional Josephson junction chain. In particular we analyze the dissipative quantum phase transition between the chain being superconducting or insulating, the purity as a measure of quantum—environment correlation and the logarithmic negativity as [...] Read more.
We study the influence of dissipative frustration on the one dimensional Josephson junction chain. In particular we analyze the dissipative quantum phase transition between the chain being superconducting or insulating, the purity as a measure of quantum—environment correlation and the logarithmic negativity as an entanglement measure. The dissipative frustration is provided by coupling two non-commuting operators to the environment. A possible realization of these environmental couplings are shunt resistances between the superconducting islands and resistances to the ground. Using a self-consistent harmonic approximation we determine the critical line separating superconducting and insulating phases and find a nonmonotonic behavior as a function of the dissipative strength. The interplay between both environmental couplings is also reflected in the purity and the logarithmic negativity. We find a change in their behavior depending whether a second bath is present or not. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 303 KiB  
Proceeding Paper
Non-Ideal X-Gate and Z-Gate in Semiconducting Spin Qubit Implementations
by Elena Ferraro, Marco Fanciulli and Marco De Michielis
Proceedings 2019, 12(1), 53; https://doi.org/10.3390/proceedings2019012053 - 19 Nov 2019
Viewed by 1316
Abstract
Several spin qubit architectures have been proposed, theoretically investigated and realized at least on the scale of single devices in view of quantum computation and simulation applications. We focus our study on five qubit types: quantum dot spin qubit, double quantum dot singlet-triplet [...] Read more.
Several spin qubit architectures have been proposed, theoretically investigated and realized at least on the scale of single devices in view of quantum computation and simulation applications. We focus our study on five qubit types: quantum dot spin qubit, double quantum dot singlet-triplet qubit, double quantum dot hybrid qubit, donor qubit, quantum dot spin-donor qubit and for each one we derived a compact effective Hamiltonian. Single qubit gate fidelities when time interval error is included are compared. A realistic set of values for the error parameters of amplitude controls linked to the z and x contribution appearing in the Hamiltonian models has been used. This study provides a ranking of the gate fidelities for the different qubit architectures highlighting which one is the most robust with respect to the considered control noises. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 1790 KiB  
Proceeding Paper
Multimode Cavity Optomechanics
by Paolo Piergentili, Letizia Catalini, Mateusz Bawaj, Stefano Zippili, Nicola Malossi, Riccardo Natali, David Vitali and Giovanni Di Giuseppe
Proceedings 2019, 12(1), 54; https://doi.org/10.3390/proceedings2019012054 - 12 Nov 2019
Cited by 2 | Viewed by 1310
Abstract
We study theoretically and experimentally the behavior of an optomechanical system where two vibrating dielectric membranes are placed inside a driven Fabry-Pérot cavity. We prove that multi–element systems of mechanical resonators are suitable for enhancing optomechanical performances, and we report a ∼2.47 gain [...] Read more.
We study theoretically and experimentally the behavior of an optomechanical system where two vibrating dielectric membranes are placed inside a driven Fabry-Pérot cavity. We prove that multi–element systems of mechanical resonators are suitable for enhancing optomechanical performances, and we report a ∼2.47 gain in the optomechanical coupling strength of the membrane relative motion with respect to the single membrane case. With this configuration it is possible to enable cavity optomechanics in the strong single-photon coupling regime. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 668 KiB  
Proceeding Paper
Multiparameter Approach to Dynamic Quantum Phase Estimation
by Valeria Cimini, Ludovica Ruggiero, Ilaria Gianani, Marco Sbroscia, Tecla Gasperi, Emanuele Roccia, Luca Mancino, Marco G. Genoni, Daniela Tofani, Fabio Bruni, Maria Antonietta Ricci and Marco Barbieri
Proceedings 2019, 12(1), 55; https://doi.org/10.3390/proceedings2019012055 - 4 Dec 2019
Viewed by 1107
Abstract
We have applied techniques of quantum phase estimation to the dynamical tracking of the optical activity of a solution of sucrose undergoing acid hydrolysis. We adopt a multiparameter approach that makes the estimation reliable and robust against setup instabilities. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 707 KiB  
Proceeding Paper
Implementation of POVMs by Projective Measurements and Postselection:Optimal Strategies and Applications to Unambiguous State Discrimination
by Filip B. Maciejewski and Michał Oszmaniec
Proceedings 2019, 12(1), 56; https://doi.org/10.3390/proceedings2019012056 - 19 Nov 2019
Viewed by 1338
Abstract
We present new results concerning simulation of general quantum measurements (POVMs) by projective measurements (PMs) for the task of Unambiguous State Discrimination (USD). We formulate a problem of finding optimal strategy of simulation for given quantum measurement. The problem can be solved for [...] Read more.
We present new results concerning simulation of general quantum measurements (POVMs) by projective measurements (PMs) for the task of Unambiguous State Discrimination (USD). We formulate a problem of finding optimal strategy of simulation for given quantum measurement. The problem can be solved for qubit and qutrits measurements by Semi-Definite Programming (SDP) methods. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 227 KiB  
Proceeding Paper
Entropic Analysis of the Quantum Oscillator with a Minimal Length
by David Puertas-Centeno and Mariela Portesi
Proceedings 2019, 12(1), 57; https://doi.org/10.3390/proceedings2019012057 - 19 Nov 2019
Viewed by 1068
Abstract
The well-known Heisenberg–Robertson uncertainty relation for a pair of noncommuting observables, is expressed in terms of the product of variances and the commutator among the operators, computed for the quantum state of a system. Different modified commutation relations have been considered in the [...] Read more.
The well-known Heisenberg–Robertson uncertainty relation for a pair of noncommuting observables, is expressed in terms of the product of variances and the commutator among the operators, computed for the quantum state of a system. Different modified commutation relations have been considered in the last years with the purpose of taking into account the effect of quantum gravity. Indeed it can be seen that letting [ X , P ] = i ( 1 + β P 2 ) implies the existence of a minimal length proportional to β . The Bialynicki-Birula–Mycielski entropic uncertainty relation in terms of Shannon entropies is also seen to be deformed in the presence of a minimal length, corresponding to a strictly positive deformation parameter β . Generalized entropies can be implemented. Indeed, results for the sum of position and (auxiliary) momentum Rényi entropies with conjugated indices have been provided recently for the ground and first excited state. We present numerical findings for conjugated pairs of entropic indices, for the lowest lying levels of the deformed harmonic oscillator system in 1D, taking into account the position distribution for the wavefunction and the actual momentum. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
4 pages, 1749 KiB  
Proceeding Paper
Squeezing-Enhanced Phase-Shift-Keyed Binary Communication in Noisy Channels
by Giovanni Chesi, Stefano Olivares and Matteo G. A. Paris
Proceedings 2019, 12(1), 58; https://doi.org/10.3390/proceedings2019012058 - 25 Nov 2019
Cited by 1 | Viewed by 988
Abstract
We address the use of squeezing in binary phase-shift-keyed (PSK) channels at fixed energy. In particular, we assess homodyne receivers against the Helstrom bound in the presence of phase noise. We also take into account possible imperfections in the generation of squeezing and [...] Read more.
We address the use of squeezing in binary phase-shift-keyed (PSK) channels at fixed energy. In particular, we assess homodyne receivers against the Helstrom bound in the presence of phase noise. We also take into account possible imperfections in the generation of squeezing and the effect of losses during propagation. We find that squeezing is a useful resource if its amplitude is below a given threshold depending on the energy of the signals and on the properties of the channel. Squeezing enhancement is present also when phase-noise becomes large. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

4 pages, 315 KiB  
Proceeding Paper
A Numerically Exact Method for Dissipative Dynamics of Qubits
by L. M. Cangemi, G. Passarelli, V. Cataudella, P. Lucignano and G. De Filippis
Proceedings 2019, 12(1), 59; https://doi.org/10.3390/proceedings2019012059 - 4 Dec 2019
Viewed by 1143
Abstract
We propose a numerical technique suitable for simulating the dynamics of reduced density matrix of a qubit interacting with its environment. Our approach, based on a combination of short-iterative Lanczos method (SIL) and a flexible truncation scheme, allows to include in the physical [...] Read more.
We propose a numerical technique suitable for simulating the dynamics of reduced density matrix of a qubit interacting with its environment. Our approach, based on a combination of short-iterative Lanczos method (SIL) and a flexible truncation scheme, allows to include in the physical description multiple-excitation processes, beyond weak coupling and Markov approximations. We perform numerical simulations of two different model Hamiltonians, that are relevant in the field of adiabatic quantum computation (AQC), and we show that our technique is able to recover the correct thermodynamic behavior of the qubit-bath system, from weak to intermediate coupling regime. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

5 pages, 341 KiB  
Proceeding Paper
Charger-Mediated Quantum Batteries
by Gian Marcello Andolina, Donato Farina, Andrea Mari, Marco Polini and Vittorio Giovannetti
Proceedings 2019, 12(1), 60; https://doi.org/10.3390/proceedings2019012060 - 6 Jul 2021
Viewed by 1888
Abstract
We study energy-transfer processes from a given quantum system, termed charger, to another one, i.e., the proper battery both in a closed and in an open quantum setting. We quantify the fraction EB(τ) of energy stored in the [...] Read more.
We study energy-transfer processes from a given quantum system, termed charger, to another one, i.e., the proper battery both in a closed and in an open quantum setting. We quantify the fraction EB(τ) of energy stored in the battery that can be extracted in order to perform thermodynamic work. We show that there can be a substantial gap between the average energy and the extractable work due to correlations created by charger–battery interactions. Full article
(This article belongs to the Proceedings of 11th Italian Quantum Information Science conference (IQIS2018))
Show Figures

Figure 1

Back to TopTop