Your search keyword '"Lorenzo, Salvatore"' showing total 44 results

1. State estimation with quantum extreme learning machines beyond the scrambling time

Author

Vetrano, Marco, Monaco, Gabriele Lo, Innocenti, Luca, Lorenzo, Salvatore, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

Quantum extreme learning machines (QELMs) leverage untrained quantum dynamics to efficiently process information encoded in input quantum states, avoiding the high computational cost of training more complicated nonlinear models. On the other hand, quantum information scrambling (QIS) quantifies how the spread of quantum information into correlations makes it irretrievable from local measurements. Here, we explore the tight relation between QIS and the predictive power of QELMs. In particular, we show efficient state estimation is possible even beyond the scrambling time, for many different types of dynamics -- in fact, we show that in all the cases we studied, the reconstruction efficiency at long interaction times matches the optimal one offered by random global unitary dynamics. These results offer promising venues for robust experimental QELM-based state estimation protocols, as well as providing novel insights into the nature of QIS from a state estimation perspective.

Published

2024

2. Quantum Extreme Learning of molecular potential energy surfaces and force fields

Author

Monaco, Gabriele Lo, Bertini, Marco, Lorenzo, Salvatore, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

Quantum machine learning algorithms are expected to play a pivotal role in quantum chemistry simulations in the immediate future. One such key application is the training of a quantum neural network to learn the potential energy surface and force field of molecular systems. We address this task by using the quantum extreme learning machine paradigm. This particular supervised learning routine allows for resource-efficient training, consisting of a simple linear regression performed on a classical computer. We have tested a setup that can be used to study molecules of any dimension and is optimized for immediate use on NISQ devices with a limited number of native gates. We have applied this setup to three case studies: lithium hydride, water, and formamide, carrying out both noiseless simulations and actual implementation on IBM quantum hardware. Compared to other supervised learning routines, the proposed setup requires minimal quantum resources, making it feasible for direct implementation on quantum platforms, while still achieving a high level of predictive accuracy compared to simulations. Our encouraging results pave the way towards the future application to more complex molecules, being the proposed setup scalable., Comment: 14 pages, 7 figures. Accepted on Machine Learning: Science and Technology

Published

2024

3. Distribution of Fidelity in Quantum State Transfer Protocols

Author

Lorenzo, Salvatore, Plastina, Francesco, Apollaro, Tony J. G., Consiglio, Mirko, and Życzkowski, Karol

Subjects

Quantum Physics

Abstract

Quantum state transfer protocols are a major toolkit in many quantum information processing tasks, from quantum key distribution to quantum computation. To assess performance of a such a protocol, one often relies on the average fidelity between the input and the output states. Going beyond this scheme, we analyze the entire probability distribution of fidelity, providing a general framework to derive it for the transfer of single- and two-qubit states. Starting from the delta-like shape of the fidelity distribution, characteristic to perfect transfer, we analyze its broadening and deformation due to realistic features of the process, including non-perfect read-out timing. Different models of quantum transfer, sharing the same value of the average fidelity, display different distributions of fidelity, providing thus additional information on the protocol, including the minimum fidelity., Comment: 9 pages, 6 figures

Published

2024

4. An operational definition of quantum information scrambling

Author

Monaco, Gabriele Lo, Innocenti, Luca, Cilluffo, Dario, Chisholm, Diana A., Lorenzo, Salvatore, and Palma, G. Massimo

Subjects

Quantum Physics, High Energy Physics - Theory

Abstract

Quantum information scrambling (QIS) is a characteristic feature of several quantum systems, ranging from black holes to quantum communication networks. While accurately quantifying QIS is crucial to understanding many such phenomena, common approaches based on the tripartite information have limitations due to the accessibility issues of quantum mutual information, and do not always properly take into consideration the dependence on the encoding input basis. To address these issues, we propose a novel and computationally efficient QIS quantifier, based on a formulation of QIS in terms of quantum state discrimination. We show that the optimal guessing probability, which reflects the degree of QIS induced by an isometric quantum evolution, is directly connected to the accessible min-information, a generalized channel capacity based on conditional min-entropy, which can be cast as a convex program and thus computed efficiently. By applying our proposal to a range of examples with increasing complexity, we illustrate its ability to capture the multifaceted nature of QIS in all its intricacy., Comment: 7 pages, 4 figures. Comments are welcome!

Published

2023

5. Heating and cooling processes via phaseonium-driven dynamics of cascade systems

Author

Amato, Federico, Pellitteri, Claudio, Palma, G. Massimo, Lorenzo, Salvatore, and Franco, Rosario Lo

Subjects

Quantum Physics

Abstract

The search for strategies to harness the temperature of quantum systems is one of the main goals in quantum thermodynamics. Here we study the dynamics of a system made of a pair of quantum harmonic oscillators, represented by single-mode cavity fields, interacting with a thermally excited beam of phaseonium atoms, which act as ancillas. The two cavities are arranged in a cascade configuration, so that the second cavity interacts with phaseonium atoms only after their interaction with the first one. We provide exact closed dynamics of the first cavity for arbitrarily long interaction times. We highlight the role played by the characteristic coherence phase of phaseonium atoms in determining the steady states of the cavity fields as well as that of the ancillas. Also, we show how the second cavity follows a non-Markovian evolution due to interactions with the "used" ancillary atoms, that enables information exchange with the first cavity. Adjusting the parameters of the phaseonium atoms, we can determine the final stable temperature reached by the cavities. In this way, the cavities can be heated up as well as cooled down. These results provide useful insights towards the use of different types of ancillas for thermodynamic cycles in cavity QED scenarios., Comment: 10 pages, 6 figures

Published

2023

6. Experimental property-reconstruction in a photonic quantum extreme learning machine

Author

Suprano, Alessia, Zia, Danilo, Innocenti, Luca, Lorenzo, Salvatore, Cimini, Valeria, Giordani, Taira, Palmisano, Ivan, Polino, Emanuele, Spagnolo, Nicolò, Sciarrino, Fabio, Palma, G. Massimo, Ferraro, Alessandro, and Paternostro, Mauro

Subjects

Quantum Physics

Abstract

Recent developments have led to the possibility of embedding machine learning tools into experimental platforms to address key problems, including the characterization of the properties of quantum states. Leveraging on this, we implement a quantum extreme learning machine in a photonic platform to achieve resource-efficient and accurate characterization of the polarization state of a photon. The underlying reservoir dynamics through which such input state evolves is implemented using the coined quantum walk of high-dimensional photonic orbital angular momentum, and performing projective measurements over a fixed basis. We demonstrate how the reconstruction of an unknown polarization state does not need a careful characterization of the measurement apparatus and is robust to experimental imperfections, thus representing a promising route for resource-economic state characterisation.

Published

2023

7. Quantum scrambling via accessible tripartite information

Author

Monaco, Gabriele Lo, Innocenti, Luca, Cilluffo, Dario, Chisholm, Diana A, Lorenzo, Salvatore, and Palma, G Massimo

Subjects

Quantum Physics

Abstract

Quantum information scrambling (QIS), from the perspective of quantum information theory, is generally understood as local non-retrievability of information evolved through some dynamical process, and is often quantified via entropic quantities such as the tripartite information. We argue that this approach comes with a number of issues, in large part due to its reliance on quantum mutual informations, which do not faithfully quantify correlations directly retrievable via measurements, and in part due to the specific methodology used to compute tripartite informations of the studied dynamics. We show that these issues can be overcome by using accessible mutual informations, defining corresponding ``accessible tripartite informations'', and provide explicit examples of dynamics whose scrambling properties are not properly quantified by the standard tripartite information. Our results lay the groundwork for a more profound understanding of what QIS represents, and reveal a number of promising, as of yet unexplored, venues for futher research., Comment: 11 pages, 6 figures, comments welcome

Published

2023

8. Variational Gibbs State Preparation on NISQ devices

Author

Consiglio, Mirko, Settino, Jacopo, Giordano, Andrea, Mastroianni, Carlo, Plastina, Francesco, Lorenzo, Salvatore, Maniscalco, Sabrina, Goold, John, and Apollaro, Tony J. G.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

The preparation of an equilibrium thermal state of a quantum many-body system on noisy intermediate-scale quantum (NISQ) devices is an important task in order to extend the range of applications of quantum computation. Faithful Gibbs state preparation would pave the way to investigate protocols such as thermalization and out-of-equilibrium thermodynamics, as well as providing useful resources for quantum algorithms, where sampling from Gibbs states constitutes a key subroutine. We propose a variational quantum algorithm (VQA) to prepare Gibbs states of a quantum many-body system. The novelty of our VQA consists in implementing a parameterized quantum circuit acting on two distinct, yet connected (via CNOT gates), quantum registers. The VQA evaluates the Helmholtz free energy, where the von Neumann entropy is obtained via post-processing of computational basis measurements on one register, while the Gibbs state is prepared on the other register, via a unitary rotation in the energy basis. Finally, we benchmark our VQA by preparing Gibbs states of the transverse field Ising and Heisenberg XXZ models and achieve remarkably high fidelities across a broad range of temperatures in statevector simulations. We also assess the performance of the VQA on IBM quantum computers, showcasing its feasibility on current NISQ devices., Comment: 15 pages, 13 figures

Published

2023

9. Temperature gradient and asymmetric steady state correlations in dissipatively coupled cascaded optomechanical systems

Author

Pellitteri, Claudio, Palma, G. Massimo, and Lorenzo, Salvatore

Subjects

Quantum Physics

Abstract

The interaction between a light mode and a mechanical oscillator via radiation pressure in optomechanical systems is an excellent platform for a multitude of applications in quantum technologies. In this work we study the dynamics of a pair of optomechanical systems interacting dissipatively with a wave guide in a unidirectional way. Focusing on the regime where the cavity modes can be adiabatically eliminated we derive an effective coupling between the two mechanical modes and we explore both classical and quantum correlations established between the modes in both in the transient and in the stationary regime, highlighting their asymmmetrical nature due to the unidirectional coupling, and we find that a constant amount of steady correlations can exist at long times. Furthermore we show that this unidirectional coupling establishes a temperature gradient between the mirrors, depending on the frequencies' detuning. We additionally analyze the power spectrum of the output guide field and we show how, thanks to the chiral coupling, from such spectrum it is possible to reconstruct the spectra of each single mirror., Comment: 27 pages, 10 figures

Published

2023

10. Shadow tomography on general measurement frames

Author

Innocenti, Luca, Lorenzo, Salvatore, Palmisano, Ivan, Albarelli, Francesco, Ferraro, Alessandro, Paternostro, Mauro, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

We provide a new perspective on shadow tomography by demonstrating its deep connections with the general theory of measurement frames. By showing that the formalism of measurement frames offers a natural framework for shadow tomography -- in which ``classical shadows'' correspond to unbiased estimators derived from a suitable dual frame associated with the given measurement -- we highlight the intrinsic connection between standard state tomography and shadow tomography. Such perspective allows us to examine the interplay between measurements, reconstructed observables, and the estimators used to process measurement outcomes, while paving the way to assess the influence of the input state and the dimension of the underlying space on estimation errors. Our approach generalizes the method described in [H.-Y. Huang {\it et al.}, Nat. Phys. 16, 1050 (2020)], whose results are recovered in the special case of covariant measurement frames. As an application, we demonstrate that a sought-after target of shadow tomography can be achieved for the entire class of tight rank-1 measurement frames -- namely, that it is possible to accurately estimate a finite set of generic rank-1 bounded observables while avoiding the growth of the number of the required samples with the state dimension., Comment: Comments welcom

Published

2023

11. Entangled States are Harder to Transfer than Product States

Author

Apollaro, Tony J. G., Lorenzo, Salvatore, Plastina, Francesco, Consiglio, Mirko, and Życzkowski, Karol

Subjects

Quantum Physics

Abstract

The distribution of entangled states is a key task of utmost importance for many quantum information processing protocols. A commonly adopted setup for distributing quantum states envisages the creation of the state in one location, which is then sent to (possibly different) distant receivers through some quantum channels. While it is undoubted and, perhaps, intuitively expected that the distribution of entangled quantum states is less efficient than that of product states, a thorough quantification of this inefficiency (namely, of the difference between the quantum-state transfer fidelity for entangled and factorized states) has not been performed. To this end, in this work, we consider $n$-independent amplitude-damping channels, acting in parallel, i.e., each, locally, on one part of an $n$-qubit state. We derive exact analytical results for the fidelity decrease, with respect to the case of product states, in the presence of entanglement in the initial state, for up to four qubits. Interestingly, we find that genuine multipartite entanglement has a more detrimental effect on the fidelity than two-qubit entanglement. Our results hint at the fact that, for larger $n$-qubit states, the difference in the average fidelity between product and entangled states increases with increasing single-qubit fidelity, thus making the latter a less trustworthy figure of merit., Comment: Contribution to the Entropy Special Issue of IQIS22 (Italian Quantum Information Science) conference, Palermo (Italy) 12-16 September 2022

Published

2023

12. Potential and limitations of quantum extreme learning machines

Author

Innocenti, Luca, Lorenzo, Salvatore, Palmisano, Ivan, Ferraro, Alessandro, Paternostro, Mauro, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

Quantum reservoir computers (QRC) and quantum extreme learning machines (QELM) aim to efficiently post-process the outcome of fixed -- generally uncalibrated -- quantum devices to solve tasks such as the estimation of the properties of quantum states. The characterisation of their potential and limitations, which is currently lacking, will enable the full deployment of such approaches to problems of system identification, device performance optimization, and state or process reconstruction. We present a framework to model QRCs and QELMs, showing that they can be concisely described via single effective measurements, and provide an explicit characterisation of the information exactly retrievable with such protocols. We furthermore find a close analogy between the training process of QELMs and that of reconstructing the effective measurement characterising the given device. Our analysis paves the way to a more thorough understanding of the capabilities and limitations of both QELMs and QRCs, and has the potential to become a powerful measurement paradigm for quantum state estimation that is more resilient to noise and imperfections., Comment: 12 pages, 7 figures, comments welcome

Published

2022

13. Quantum transfer of interacting qubits

Author

Apollaro, Tony J. G., Lorenzo, Salvatore, Plastina, Francesco, Consiglio, Mirko, and Życzkowski, Karol

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

The transfer of quantum information between different locations is key to many quantum information processing tasks. Whereas, the transfer of a single qubit state has been extensively investigated, the transfer of a many-body system configuration has insofar remained elusive. We address the problem of transferring the state of n interacting qubits. Both the exponentially increasing Hilbert space dimension, and the presence of interactions significantly scale-up the complexity of achieving high-fidelity transfer. By employing tools from random matrix theory and using the formalism of quantum dynamical maps, we derive a general expression for the average and the variance of the fidelity of an arbitrary quantum state transfer protocol for n interacting qubits. Finally, by adopting a weak-coupling scheme in a spin chain, we obtain the explicit conditions for high-fidelity transfer of 3 and 4 interacting qubits., Comment: 24 pages, comments welcome

Published

2022

14. Quantum synchronisation and clustering in chiral networks

Author

Lorenzo, Salvatore, Militello, Benedetto, Napoli, Anna, Zambrini, Roberta, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

We study the emergence of synchronisation in a chiral network of harmonic oscillators. The network consists of a set of locally incoherently pumped harmonic oscillators coupled pairwise in cascade with travelling field modes. Such cascaded coupling leads to feedback-less dissipative interaction between the harmonic oscillators of the pair which can be described in terms of an effective pairwise hamiltonian a collective pairwise decay. The network is described mathematically in terms of a directed graph. By analysing geometries of increasing complexity we show how the onset of synchronisation depends strongly on the network topology, with the emergence of synchronised communities in the case of complex networks. The quantum nature of the non local correlation between network nodes is assessed., Comment: 11 pages, 8 figures

Published

2021

15. Exotic interactions mediated by a non-Hermitian photonic bath

Author

Roccati, Federico, Lorenzo, Salvatore, Calajò, Giuseppe, Palma, G. Massimo, Carollo, Angelo, and Ciccarello, Francesco

Subjects

Quantum Physics

Abstract

Photon-mediated interactions between quantum emitters in engineered photonic baths is an emerging area of quantum optics. At the same time, non-Hermitian (NH) physics is currently thriving, spurred by the exciting possibility to access new physics in systems ruled by non-trivial NH Hamiltonians - in particular photonic lattices - which can challenge longstanding tenets such as the Bloch theory of bands. Here, we combine these two fields and study the exotic interaction between emitters mediated by the photonic modes of a lossy photonic lattice described by a NH Hamiltonian. We show in a paradigmatic case study that structured losses in the field can seed exotic emission properties. Photons can mediate dissipative, fully non-reciprocal, interactions between the emitters with range critically dependent on the loss rate. When this loss rate corresponds to a bare-lattice exceptional point, the effective couplings are exactly nearest-neighbour, implementing a dissipative, fully non-reciprocal, Hatano-Nelson model. Counter-intuitively, this occurs irrespective of the lattice boundary conditions. Thus photons can mediate an effective emitters' Hamiltonian which is translationally-invariant despite the fact that the field is not. We interpret these effects in terms of metastable atom-photon dressed states, which can be exactly localized on only two lattice cells or extended across the entire lattice. These findings introduce a new paradigm of light-mediated interactions with unprecedented features such as non-reciprocity, non-trivial dependence on the field boundary conditions and range tunability via a loss rate., Comment: 8+7 pages, 8 figures. Close to published version

Published

2021

16. Quantum collision models: open system dynamics from repeated interactions

Author

Ciccarello, Francesco, Lorenzo, Salvatore, Giovannetti, Vittorio, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

We present an extensive introduction to quantum collision models (CMs), also known as repeated interactions schemes: a class of microscopic system-bath models for investigating open quantum systems dynamics whose use is currently spreading in a number of research areas. Through dedicated sections and a pedagogical approach, we discuss the CMs definition and general properties, their use for the derivation of master equations, their connection with quantum trajectories, their application in non-equilibrium quantum thermodynamics, their non-Markovian generalizations, their emergence from conventional system-bath microscopic models and link to the input-output formalism. The state of the art of each involved research area is reviewed through dedicated sections. The article is supported by several complementary appendices, which review standard concepts/tools of open quantum systems used in the main text with the goal of making the material accessible even to readers possessing only a basic background in quantum mechanics. The paper could also be seen itself as a friendly, physically intuitive, introduction to fundamentals of open quantum systems theory since most main concepts of this are treated such as quantum maps, Lindblad master equation, steady states, POVMs, quantum trajectories and stochastic Schrodinger equation., Comment: 159 pages, 20 figures. Extensive pedagogical review on quantum collision models (aka repeated interactions schemes)

Published

2021

17. Microscopic biasing of discrete-time quantum trajectories

Author

Cilluffo, Dario, Lesanovsky, Igor, Buonaiuto, Giuseppe, Carollo, Angelo, Lorenzo, Salvatore, Palma, G. Massimo, Ciccarello, Francesco, and Carollo, Federico

Subjects

Quantum Physics

Abstract

We develop a microscopic theory for biasing the quantum trajectories of an open quantum system, which renders rare trajectories typical. To this end we consider a discrete-time quantum dynamics, where the open system collides sequentially with qubit probes which are then measured. A theoretical framework is built in terms of thermodynamic functionals in order to characterize its quantum trajectories (each embodied by a sequence of measurement outcomes). We show that the desired biasing is achieved by suitably modifying the Kraus operators describing the discrete open dynamics. From a microscopical viewpoint and for short collision times, this corresponds to adding extra collisions which enforce the system to follow a desired rare trajectory. The above extends the theory of biased quantum trajectories from Lindblad-like dynamics to sequences of arbitrary dynamical maps, providing at once a transparent physical interpretation., Comment: 7+3 pages, 4 figures

Published

2020

18. Collisional picture of quantum optics with giant emitters

Author

Cilluffo, Dario, Carollo, Angelo, Lorenzo, Salvatore, Gross, Jonathan A., Palma, G. Massimo, and Ciccarello, Francesco

Subjects

Quantum Physics

Abstract

The effective description of the weak interaction between an emitter and a bosonic field as a sequence of two-body collisions provides a simple intuitive picture compared to traditional quantum optics methods as well as an effective calculation tool of the joint emitter-field dynamics. Here, this collisional approach is extended to many emitters (atoms or resonators), each generally interacting with the field at many coupling points ("giant" emitter). In the regime of negligible delays, the unitary describing each collision in particular features a contribution of a chiral origin resulting in an effective Hamiltonian. The picture is applied to derive a Lindblad master equation (ME) of a set of giant atoms coupled to a (generally chiral) waveguide field in an arbitrary white-noise Gaussian state, which condenses into a single equation and extends a variety of quantum optics and waveguide-QED MEs. The effective Hamiltonian and jump operators corresponding to a selected photodetection scheme are also worked out., Comment: 21 pages, 7 figures

Published

2020

19. Intermittent decoherence blockade in a chiral ring environment

Author

Lorenzo, Salvatore, Longhi, Stefano, Cabot, Albert, Zambrini, Roberta, and Giorgi, Gian Luca

Subjects

Quantum Physics

Abstract

It has long been recognized that emission of radiation from atoms is not an intrinsic property of individual atoms themselves, but it is largely affected by the characteristics of the photonic environment and by the collective interaction among the atoms. A general belief is that preventing full decay and/or decoherence requires the existence of dark states, i.e., dressed light-atom states that do not decay despite the dissipative environment. Here, we show that, contrary to such a common wisdom, decoherence suppression can be intermittently achieved on a limited time scale, without the need for any dark state, when the atom is coupled to a chiral ring environment, leading to a highly non-exponential staircase decay. This effect, that we refer to as intermittent decoherence blockade, arises from periodic destructive interference between light emitted in the present and light emitted in the past, i.e., from delayed coherent quantum feedback., Comment: 12 pages, 4 figures

Published

2020

20. Quantum correlations in $\mathcal{PT}$-symmetric systems

Author

Roccati, Federico, Lorenzo, Salvatore, Palma, G. Massimo, Landi, Gabriel T., Brunelli, Matteo, and Ciccarello, Francesco

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mathematical Physics

Abstract

We study the dynamics of correlations in a paradigmatic setup to observe $\mathcal{PT}$-symmetric physics: a pair of coupled oscillators, one subject to a gain one to a loss. Starting from a coherent state, quantum correlations (QCs) are created, despite the system being driven only incoherently, and can survive indefinitely. $\mathcal{PT}$ symmetry breaking is accompanied by non-zero stationary QCs. We link $\mathcal{PT}$ symmetry breaking to the long-time behavior of both total and QCs, which display different scalings in the $\mathcal{PT}$-broken/unbroken phase and at the exceptional point (EP). This is analytically shown and quantitatively explained in terms of entropy balance. The EP in particular stands out as the most classical configuration.

Published

2020

21. Topological Protection and Control of Quantum Markovianity

Author

Giorgi, Gian Luca, Lorenzo, Salvatore, and Longhi, Stefano

Subjects

Quantum Physics

Abstract

Under the Born--Markov approximation, a qubit system, such as a two-level atom, is known to undergo a memoryless decay of quantum coherence or excitation when weakly coupled to a featureless environment. Recently, it has been shown that unavoidable disorder in the environment is responsible for non-Markovian effects and information backflow from the environment into the system owing to Anderson localization. This~turns disorder into a resource for enhancing non-Markovianity in the system--environment dynamics, which could be of relevance in cavity quantum electrodynamics. Here we consider the decoherence dynamics of a qubit weakly coupled to a two-dimensional bath with a nontrivial topological phase, such as a two-level atom embedded in a two-dimensional coupled-cavity array with a synthetic gauge field realizing a quantum-Hall bath, and~show that Markovianity is protected against moderate disorder owing to the robustness of chiral edge modes in the quantum-Hall bath. Interestingly, switching off the gauge field, i.e., flipping the bath into a topological trivial phase, allows one to re-introduce non-Markovian effects. Such a result indicates that changing the topological phase of a bath by a tunable synthetic gauge field can be harnessed to control non-Markovian effects and quantum information backflow in a qubit-environment system., Comment: article for the special issue on Topological Photonics

Published

2020

22. Reading a qubit quantum state with a quantum meter: time unfolding of quantum Darwinism and quantum information flux

Author

Lorenzo, Salvatore, Paternostro, Mauro, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

Quantum non Markovianity and quantum Darwinism are two phenomena linked by a common theme: the flux of quantum information between a quantum system and the quantum environment it interacts with. In this work, making use of a quantum collision model, a formalism initiated by Sudarshan and his school, we will analyse the efficiency with which the information about a single qubit gained by a quantum harmonic oscillator, acting as a meter, is transferred to a bosonic environment. We will show how, in some regimes, such quantum information flux is inefficient, leading to the simultaneous emergence of non Markovian and non darwinistic behaviours, Comment: 8 pages,8 figures

Published

2020

23. Multipartite entanglement transfer in spin chains

Author

Apollaro, Tony J. G., Sanavio, Claudio, Chetcuti, Wayne Jordan, and Lorenzo, Salvatore

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

We investigate the transfer of genuine multipartite entanglement across a spin-1/2 chain with nearest-neighbor XX-type interaction. We focus on the perturbative regime, where a block of spins is weakly coupled at each edge of a quantum wire, embodying the role of a multiqubit sender and receiver, respectively. We find that high-quality multipartite entanglement transfer is achieved at the same time that three excitations are transferred to the opposite edge of the chain. Moreover, we find that both a finite concurrence and tripartite negativity is attained at much shorter time, making GHZ-distillation protocols feasible. Finally, we investigate the robustness of our protocol with respect to non-perturbative couplings and increasing lengths of the quantum wire., Comment: Comments welcome

Published

2020

24. Perturbatively-perfect many-body transfer

Author

Chetcuti, Wayne Jordan, Sanavio, Claudio, Lorenzo, Salvatore, and Apollaro, Tony J. G.

Subjects

Quantum Physics

Abstract

The coherent transfer of excitations between different locations of a quantum many-body system is of primary importance in many research areas, from transport properties in spintronics and atomtronics to quantum state transfer in quantum information processing. We address the transfer of $n>1$ bosonic and fermionic excitations between the edges of a one-dimensional chain modeled by a quadratic hopping Hamiltonian, where the block edges, embodying the sender and the receiver sites, are weakly coupled to the quantum wire. We find that perturbatively perfect coherent transfer is attainable in the weak-coupling limit, for both bosons and fermions, only for certain modular arithmetic equivalence classes of the wire's length. Finally we apply our findings to the transport of spins and the charging of a many-body quantum battery., Comment: 25 pages, 7 figures. Comments welcome

Published

2019

25. Witnessing non-classicality through large deviations in quantum optics

Author

Cilluffo, Dario, Buonaiuto, Giuseppe, Lorenzo, Salvatore, Palma, G. Massimo, Ciccarello, Francesco, Carollo, Federico, and Lesanovsky, Igor

Subjects

Quantum Physics

Abstract

Non-classical correlations in quantum optics as resources for quantum computation are important in the quest for highly-specialized quantum devices. The standard way to investigate such effects relies on either the characterization of the inherent features of sources and circuits or the study of the output radiation of a given optical setup. The latter approach demands an extensive description of the output fields, but often overlooks the dynamics of the sources. Conversely, the former discards most of the information about the single trajectories, which are observed in experimental measurements. In this work we provide a natural link between the two frameworks by exploiting the thermodynamics of quantum trajectories. This procedure enables investigation of the quantum properties of the photon fields from a generic source via the analysis of the fluctuations and correlations of time-integrated quantities associated with the photon counting of the emitted light., Comment: 5 pages, 3 figures

Published

2019

26. (Anti-)Zeno-based dynamical control of the unfolding of quantum Darwinism

Author

Lorenzo, Salvatore, Paternostro, Mauro, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

We combine the collisional picture for open system dynamics and the control of the rate of decoherence provided by the quantum (anti-)Zeno effect to illustrate the temporal unfolding of the redundant encoding of information into a multipartite environment that is at the basis of Quantum Darwinism, and to control it. The rate at which such encoding occurs can be enhanced or suppressed by tuning the dynamical conditions of system-environment interaction in a suitable and remarkably simple manner. This would help the design of a new generation of quantum experiments addressing the elusive phenomenology of Quantum Darwinism and thus its characterization., Comment: 6 pages,5 figures

Published

2019

27. Stationary quantum correlations in a system with mean-field PT symmetry

Author

Roccati, Federico, Lorenzo, Salvatore, Palma, G. Massimo, and Ciccarello, Francesco

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Mathematical Physics

Abstract

A pair of coupled quantum harmonic oscillators, one subject to a gain one to a loss, is a paradigmatic setup to implement PT-symmetric, non-Hermitian Hamiltonians in that one such Hamiltonian governs the mean-field dynamics for equal gain and loss strengths. Through a full quantum description (so as to account for quantum noise) here is shown that when the system starts in any two-mode coherent state, including vacuum, there appear quantum correlations (QCs) without entanglement, as measured by the Gaussian discord. When the loss rate is above a threshold, once generated QCs no more decay. This occurs in a wide region of parameters, significantly larger than that where the full quantum dynamics is stable. For equal gain and loss rates, in particular, QCs decay in the exact phase (including the exceptional point) and are stable in the broken phase., Comment: Preliminary report. 6 pages, 3 figures

Published

2019

28. Quantum jump statistics with a shifted jump operator in a chiral waveguide

Author

Cilluffo, Dario, Lorenzo, Salvatore, Palma, G. Massimo, and Ciccarello, Francesco

Subjects

Quantum Physics

Abstract

Resonance fluorescence, consisting of light emission from an atom driven by a classical oscillating field, is well-known to yield a sub-Poissonian photon counting statistics. This occurs when only emitted light is detected, which corresponds to a master equation (ME) unraveling in terms of the canonical jump operator describing spontaneous decay. Formally, an alternative ME unraveling is possible in terms of a shifted jump operator. We show that this shift can result in sub-Poissonian, Poissonian or super-Poissonian quantum jump statistics. This is shown in terms of the Mandel Q parameter in the limit of long counting times, which is computed through large deviation theory. We present a waveguide-QED setup, comprising a chiral waveguide coupled to a driven atom, where photon counting is described by the considered class of shifted jump operators., Comment: 11 pages, 2 figures, Special Issue: New Trends in Nonequilibrium Statistical Mechanics: Classical and Quantum Systems - nesmcq18

Published

2019

29. The role of information back-flow in the emergence of quantum Darwinism

Author

Milazzo, Nadia, Lorenzo, Salvatore, Paternostro, Mauro, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

Quantum Darwinism attempts to explain the emergence of objective reality of the state of a quantum system in terms of redundant information about the system acquired by independent non interacting fragments of the environment. The consideration of interacting environmental elements gives rise to a rich phenomenology, including the occurrence of non-Markovian features, whose effects on objectification {\it a' la} quantum Darwinism needs to be fully understood. We study a model of local interaction between a simple quantum system and a multi-mode environment that allows for a clear investigation of the interplay between information trapping and propagation in the environment and the emergence of quantum Darwinism. We provide strong evidence of the correlation between non-Markovianity and quantum Darwinism in such a model, thus providing strong evidence of a potential link between such fundamental phenomena., Comment: 7 pages, 9 figures

Published

2019

30. Spin chains for two-qubit teleportation

Author

Apollaro, Tony J. G., Almeida, Guilherme M. A., Lorenzo, Salvatore, Ferraro, Alessandro, and Paganelli, Simone

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

Generating high-quality multi-particle entanglement between communicating parties is the primary resource in quantum teleportation protocols. To this aim, we show that the natural dynamics of a single spin chain is able to sustain the generation of two pairs of Bell states - possibly shared between a sender and a distant receiver - which can in turn enable two-qubit teleportation. In particular, we address a spin-1/2 chain with XX interactions, connecting two pairs of spins located at its boundaries, playing the roles of sender and receiver. In the regime where both end pairs are weakly coupled to the spin chain, it is possible to generate at predefinite times a state that has vanishing infidelity with the product state of two Bell pairs, thereby providing nearly unit fidelity of teleportation. We also derive an effective Hamiltonian via a second-order perturbation approach that faithfully reproduces the dynamics of the full system., Comment: 11 pages, 4 figures. Comments welcome

Published

2018

31. Coexistence of different scaling laws for the entanglement entropy in a periodically driven system

Author

Apollaro, Tony J. G. and Lorenzo, Salvatore

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

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 both 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 transverse 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 subsystem 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., Comment: contribution to the 11th Italian Quantum Information Science conference (IQIS), September 17th-20th, 2018 - Catania, Italy, 4 pages

Published

2018

32. Non-Markovian dynamics from band edge effects and static disorder

Author

Lorenzo, Salvatore, Ciccarello, Francesco, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

It was recently shown [S. Lorenzo et al., Sci. Rep. 7, 42729 (2017)] that the presence of static disorder in a bosonic bath - whose normal modes thus become all Anderson-localised - leads to non-Markovianity in the emission of an atom weakly coupled to it (a process which in absence of disorder is fully Markovian). Here, we extend the above analysis beyond the weak-coupling regime for a finite-band bath so as to account for band edge effects. We study the interplay of these with static disorder in the emergence of non-Markovian behaviour in terms of a suitable non-Markovianity measure., Comment: 5 pages, 1 figures, accepted to "International Journal of Quantum Information" as a contribution to the upcoming special issue

Published

2017

33. Quantum non-Markovian piecewise dynamics from collision models

Author

Lorenzo, Salvatore, Ciccarello, Francesco, Palma, G. Massimo, and Vacchini, Bassano

Subjects

Quantum Physics

Abstract

Recently, a large class of quantum non-Markovian piecewise dynamics for an open quantum system obeying closed evolution equations has been introduced [B. Vacchini, Phys. Rev. Lett. 117, 230401 (2016)]. These dynamics have been defined in terms of a waiting-time distribution between quantum jumps, along with quantum maps describing the effect of jumps and the system's evolution between them. Here, we present a quantum collision model with memory, whose reduced dynamics in the continuous-time limit reproduces the above class of non-Markovian piecewise dynamics, thus providing an explicit microscopic realization., Comment: 18 pages, 1 figures. Submitted to "Open Systems and Information Dynamics" as a contribution to the upcoming special issue titled "40 years of the GKLS equation"

Published

2017

34. Composite quantum collision models

Author

Lorenzo, Salvatore, Ciccarello, Francesco, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

A collision model (CM) is a framework to describe open quantum dynamics. In its {\it memoryless} version, it models the reservoir $\mathcal R$ as consisting of a large collection of elementary ancillas: the dynamics of the open system $\mathcal{S}$ results from successive "collisions" of $\mathcal{S}$ with the ancillas of $\mathcal R$. Here, we present a general formulation of memoryless {\it composite} CMs, where $\mathcal S$ is partitioned into the very open system under study $S$ coupled to one or more auxiliary systems $\{S_i\}$. Their composite dynamics occurs through internal $S$-$\{S_i\}$ collisions interspersed with external ones involving $\{S_i\}$ and the reservoir $\mathcal R$. We show that important known instances of quantum {\it non-Markovian} dynamics of $S$ -- such as the emission of an atom into a reservoir featuring a Lorentzian, or multi-Lorentzian, spectral density or a qubit subject to random telegraph noise -- can be mapped on to such {\it memoryless} composite CMs., Comment: 12 pages, 4 figures

Published

2017

35. Quantum Critical Scaling under Periodic Driving

Author

Lorenzo, Salvatore, Marino, Jamir, Plastina, Francesco, Palma, G. Massimo, and Apollaro, Tony J. G.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

Universality is key to the theory of phase transition stating that the equilibrium properties of observables near a phase transition can be classified according to few critical exponents. These exponents rule an universal scaling behaviour that witnesses the irrelevance of the model's microscopic details at criticality. Here we discuss the persistence of such a scaling in a one-dimensional quantum Ising model under sinusoidal modulation in time of its transverse magnetic field. We show that scaling of various quantities (concurrence, entanglement entropy, magnetic and fidelity susceptibility) endures up to a stroboscopic time $\tau_{bd}$, proportional to the size of the system. This behaviour is explained by noticing that the low-energy modes, responsible for the scaling properties, are resilient to the absorption of energy. Our results suggest that relevant features of the universality do hold also when the system is brought out-of-equilibrium by a periodic driving., Comment: 11 pages, 7 figures

Published

2016

36. Quantum state transfer with ultracold atoms in optical lattices

Author

Lorenzo, Salvatore, Apollaro, Tony J. G., Trombettoni, Andrea, and Paganelli, Simone

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Ultracold atoms can be used to perform quantum simulations of a variety of condensed matter systems, including spin systems. These progresses point to the implementation of the manipulation of quantum states and to observe and exploit the effect of quantum correlations. A natural direction along this line is provided by the possibility to perform quantum state transfer (QST). After presenting a brief discussion of the simulation of quantum spin chains with ultracold gases and reminding the basic facts of QST, we discuss how to potentially use the tools of present-day ultracold technology to implement the QST between two regions of the atomic system (the sender and the receiver). The fidelity and the typical timescale of the QST are discussed, together with possible limitations and applications of the presented results.

Published

2016

37. Quantum non-Markovianity induced by Anderson localization

Author

Lorenzo, Salvatore, Lombardo, Federico, Ciccarello, Francesco, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

As discovered by P. W. Anderson, excitations do not propagate freely in a disordered lattice, but, due to destructive interference, they localise. As a consequence when an atom interacts with a disordered lattice one indeed observes, a non-trivial excitation exchange between atom and lattice. Such non-trivial atomic dynamics will in general be characterised also by a non-trivial quantum information backflow, a clear signature of non-Markovian dynamics. To investigate the above scenario we consider a quantum emitter, or atom, weakly coupled to a uniform coupled-cavity array (CCA). If initially excited, in the absence of disorder, the emitter undergoes a Markovian spontaneous emission by releasing all its excitation into the CCA (initially in its vacuum state). By introducing static disorder in the CCA the field normal modes become Anderson-localized, giving rise to a non-Markovian atomic dynamics. We show the existence of a functional relationship between a rigorous measure of quantum non-Markovianity and the CCA localization. We furthermore show that the average non-Markovianity of the atomic dynamics is well-described by a phenomenological model in which the atom is coupled, at the same time, to a single mode and to a standard - Markovian - dissipative bath., Comment: 11 pages, 4 figures

Published

2016

38. Class of exact memory-kernel master equations

Author

Lorenzo, Salvatore, Ciccarello, Francesco, and Palma, G. Massimo

Subjects

Quantum Physics

Abstract

A well-known situation in which a non-Markovian dynamics of an open quantum system $S$ arises is when this is coherently coupled to an auxiliary system $M$ in contact with a Markovian bath. In such cases, while the joint dynamics of $S$-$M$ is Markovian and obeys a standard (bipartite) Lindblad-type master equation (ME), this is in general not true for the reduced dynamics of $S$. Furthermore, there are several instances (\eg the dissipative Jaynes-Cummings model) in which a {\it closed} ME for the $S$'s state {\it cannot} even be worked out. Here, we find a class of bipartite Lindblad-type MEs such that the reduced ME of $S$ can be derived exactly and in a closed form for any initial product state of $S$-$M$. We provide a detailed microscopic derivation of our result in terms of a mapping between two collision models, Comment: 9 pages, 1 figure

Published

2016

39. Heat flux dynamics in dissipative cascaded systems

Author

Lorenzo, Salvatore, Farace, Alessandro, Ciccarello, Francesco, Palma, G. Massimo, and Giovannetti, Vittorio

Subjects

Quantum Physics

Abstract

We study the dynamics of heat flux in the thermalization process of a pair of identical quantum system that interact dissipatively with a reservoir in a {\it cascaded} fashion. Despite the open dynamics of the bipartite system S is globally Lindbladian, one of the subsystems "sees" the reservoir in a state modified by the interaction with the other subsystem and hence it undergoes a non-Markovian dynamics. As a consequence, the heat flow exhibits a non-exponential time behaviour which can greatly deviate from the case where each party is independently coupled to the reservoir. We investigate both thermal and correlated initial states of $S$ and show that the presence of correlations at the beginning can considerably affect the heat flux rate. We carry out our study in two paradigmatic cases -- a pair of harmonic oscillators with a reservoir of bosonic modes and two qubits with a reservoir of fermionic modes -- and compare the corresponding behaviours. In the case of qubits and for initial thermal states, we find that the trace distance discord is at any time interpretable as the correlated contribution to the total heat flux., Comment: Final accepted version

Published

2014

40. Competition between memory-keeping and memory-erasing decoherence channels

Author

Apollaro, Tony J. G., Lorenzo, Salvatore, Di Franco, Carlo, Plastina, Francesco, and Paternostro, Mauro

Subjects

Quantum Physics

Abstract

We study the competing effects of simultaneous Markovian and non-Markovian decoherence mechanisms acting on a single spin. We show the existence of a threshold in the relative strength of such mechanisms above which the spin dynamics becomes fully Markovian, as revealed by the use of several non-Markovianity measures. We identify a measure-dependent nested structure of such thresholds, hinting at a causality relationship amongst the various non-Markovianity witnesses used in our analysis. Our considerations are then used to argue the unavoidably non-Markovian evolution of a single-electron quantum dot exposed to both intrinsic and Markovian technical noise, the latter of arbitrary strength.

Published

2013

41. Routing quantum information in spin chains

Author

Paganelli, Simone, Lorenzo, Salvatore, Apollaro, Tony J. G., Plastina, Francesco, and Giorgi, Gian Luca

Subjects

Quantum Physics

Abstract

Two different models for performing efficiently routing of a quantum state are presented. Both cases involve an XX spin chain working as data bus and additional spins that play the role of sender and receivers, one of which is selected to be the target of the quantum state transmission protocol via a coherent quantum coupling mechanism making use of local/global magnetic fields. Quantum routing is achieved, in the first of the models considered, by weakly coupling the sender and the receiver to the data bus. In the second model, strong magnetic fields acting on additional spins located between the sender/receiver and the data bus allow us to perform high fidelity routing., Comment: added references in v2

Published

2013

42. Transport of Quantum Correlations across a spin chain

Author

Apollaro, Tony J. G., Lorenzo, Salvatore, and Plastina, Francesco

Subjects

Quantum Physics

Abstract

Some of the recent developments concerning the propagation of quantum correlations across spin channels are reviewed. In particular, we focus on the improvement of the transport efficiency obtained by the manipulation of few energy parameters (either end-bond strengths or local magnetic fields) near the sending and receiving sites. We give a physically insightful description of various such schemes and discuss the transfer of both entanglement and of quantum discord., Comment: Review submitted to Int. J. Mod. Phys. B, special issue "Classical Vs Quantum correlations in composite systems", edited by L. Amico, S. Bose, V. Korepin and V. Vedral

Published

2012

43. Tuning non-Markovianity by spin-dynamics control

Author

Lorenzo, Salvatore, Plastina, Francesco, and Paternostro, Mauro

Subjects

Quantum Physics

Abstract

We study the interplay between forgetful and memory-keeping evolution enforced on a two-level system by a multi-spin environment whose elements are coupled to local bosonic baths. Contrarily to the expectation that any non-Markovian effect would be buried by the forgetful mechanism induced by the spin-bath coupling, one can actually induce a full Markovian-to-non-Markovian transition of the two-level system's dynamics, controllable by parameters such as the mismatch between the energy of the two-level system and of the spin environment. For a symmetric coupling, the amount of non-Markovianity surprisingly grows with the number of decoherence channels., Comment: 7 pages, 6 figures, PRA version

Published

2012

44. The role of environmental correlations in the non-Markovian dynamics of a spin system

Author

Lorenzo, Salvatore, Plastina, Francesco, and Paternostro, Mauro

Subjects

Quantum Physics

Abstract

We put forward a framework to study the dynamics of a chain of interacting quantum particles affected by individual or collective multi-mode environment, focussing on the role played by the environmental quantum correlations over the evolution of the chain. The presence of entanglement in the state of the environmental system magnifies the non-Markovian nature of the chain's dynamics, giving rise to structures in figures of merit such as entanglement and purity that are not observed under a separable multi-mode environment. Our analysis can be relevant to problems tackling the open-system dynamics of biological complexes of strong current interest., Comment: 9 pages, 12 figures

Published

2011