Your search keyword '"Gullo, N. Lo"' showing total 36 results

1. Memory-Augmented Hybrid Quantum Reservoir Computing

Author

Settino, J., Salatino, L., Mariani, L., Channab, M., Bozzolo, L., Vallisa, S., Barillà, P., Policicchio, A., Gullo, N. Lo, Giordano, A., Mastroianni, C., and Plastina, F.

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter, Mathematical Physics

Abstract

Reservoir computing (RC) is an effective method for predicting chaotic systems by using a high-dimensional dynamic reservoir with fixed internal weights, while keeping the learning phase linear, which simplifies training and reduces computational complexity compared to fully trained recurrent neural networks (RNNs). Quantum reservoir computing (QRC) uses the exponential growth of Hilbert spaces in quantum systems, allowing for greater information processing, memory capacity, and computational power. However, the original QRC proposal requires coherent injection of inputs multiple times, complicating practical implementation. We present a hybrid quantum-classical approach that implements memory through classical post-processing of quantum measurements. This approach avoids the need for multiple coherent input injections and is evaluated on benchmark tasks, including the chaotic Mackey-Glass time series prediction. We tested our model on two physical platforms: a fully connected Ising model and a Rydberg atom array. The optimized model demonstrates promising predictive capabilities, achieving a higher number of steps compared to previously reported approaches., Comment: 8 pages, 7 figures

Published

2024

2. Harnessing Quantum Extreme Learning Machines for image classification

Author

De Lorenzis, A., Casado, M. P., Estarellas, M. P., Gullo, N. Lo, Lux, T., Plastina, F., Riera, A., and Settino, J.

Subjects

Quantum Physics

Abstract

Interest in quantum machine learning is increasingly growing due to its potential to offer more efficient solutions for problems that are difficult to tackle with classical methods. In this context, the research work presented here focuses on the use of quantum machine learning techniques for image classification tasks. We exploit a quantum extreme learning machine by taking advantage of its rich feature map provided by the quantum reservoir substrate. We systematically analyse different phases of the quantum extreme learning machine process, from the dataset preparation to the image final classification. In particular, we have tested different encodings, together with Principal Component Analysis, the use of Auto-Encoders, as well as the dynamics of the model through the use of different Hamiltonians for the quantum reservoir. Our results show that the introduction of a quantum reservoir systematically improves the accuracy of the classifier. Additionally, while different encodings can lead to significantly different performances, Hamiltonians with varying degrees of connectivity exhibit the same discrimination rate, provided they are interacting., Comment: 11 pages, 6 figures

Published

2024

3. Bayesian mitigation of measurement errors in multi-qubit experiments

Author

Cosco, F., Plastina, F., and Gullo, N. Lo

Subjects

Quantum Physics

Abstract

We introduce an implementation of Bayesian measurement error mitigation tailored for multiqubit experiments on near-term quantum devices. Our approach leverages complete information from the readout signal, which is available before any binary state assignment of the qubits. We provide a detailed algorithm workflow, from the calibration of detector response functions to the post-processing of measurement outcomes, offering a computationally efficient solution suitable for the output size typical of current quantum computing devices and quantum algorithms. We benchmark our protocol on actual quantum computers with superconducting qubits, where the readout signal encodes the measurement information in the IQ clouds before qubit state assignment. Finally, we compare the performance of our algorithm against other measurement error mitigation methods, such as iterative Bayesian unfolding and noise matrix inversion., Comment: 11 pages, 6 figures

Published

2024

4. Interacting electrons in a flat-band system within the Generalized Kadanoff-Baym Ansatz

Author

Cosco, F., Tuovinen, R., and Gullo, N. Lo

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Other Condensed Matter, Quantum Physics

Abstract

This work reports the study of the spectral properties of an open interacting system by solving the Generalized Kadanoff-Baym Ansatz (GKBA) master equation for the single-particle density matrix, namely the time-diagonal lesser Green function. To benchmark its validity, the solution obtained within the GKBA is compared with the solution of the Dyson equation at stationarity. In both approaches, the interaction is treated within the self-consistent second-order Born approximation, whereas the GKBA still retains the retarded propagator calculated at the Hartree-Fock and wide-band limit approximation level. The model chosen is that of two leads connected through a central correlated region where particles can interact and utilize the stationary particle current at the boundary of the junction as a probe of the spectral features of the system. The central region is chosen as the simplest model featuring a degenerate ground state with a flat band. The main result is that the solution of the GKBA master equation captures well the spectral feature of such system and specifically the transition from dispersionless to dispersive behavior of the flat-band as the interaction is increased. Therefore the GBKA solution retains the main spectral features of the self-energy used even when the propagator is at the Hartree-Fock level., Comment: 5 Figures

Published

2024

5. Enhancing qubit readout with Bayesian Learning

Author

Cosco, F. and Gullo, N. Lo

Subjects

Quantum Physics, Physics - Data Analysis, Statistics and Probability

Abstract

We introduce an efficient and accurate readout measurement scheme for single and multi-qubit states. Our method uses Bayesian inference to build an assignment probability distribution for each qubit state based on a reference characterization of the detector response functions. This allows us to account for system imperfections and thermal noise within the assignment of the computational basis. We benchmark our protocol on a quantum device with five superconducting qubits, testing initial state preparation for single and two-qubit states and an application of the Bernstein-Vazirani algorithm executed on five qubits. Our method shows a substantial reduction of the readout error and promises advantages for near-term and future quantum devices., Comment: 8 pages, 4 figures

Published

2023

6. A hybrid classical-quantum approach to speed-up Q-learning

Author

Sannia, A., Giordano, A., Gullo, N. Lo, Mastroianni, C., and Plastina, F.

Subjects

Quantum Physics

Abstract

We introduce a classical-quantum hybrid approach to computation, allowing for a quadratic performance improvement in the decision process of a learning agent. In particular, a quantum routine is described, which encodes on a quantum register the probability distributions that drive action choices in a reinforcement learning set-up. This routine can be employed by itself in several other contexts where decisions are driven by probabilities. After introducing the algorithm and formally evaluating its performance, in terms of computational complexity and maximum approximation error, we discuss in detail how to exploit it in the Q-learning context., Comment: comments are welcome

Published

2022

7. A many-body approach to transport in quantum systems: From the transient regime to the stationary state

Author

Ridley, M., Talarico, N. W., Karlsson, D., Gullo, N. Lo, and Tuovinen, R.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Chemical Physics, Quantum Physics

Abstract

We review one of the most versatile theoretical approaches to the study of time-dependent correlated quantum transport in nano-systems: the non-equilibrium Green's function (NEGF) formalism. Within this formalism, one can treat, on the same footing, inter-particle interactions, external drives and/or perturbations, and coupling to baths with a (piece-wise) continuum set of degrees of freedom. After a historical overview on the theory of transport in quantum systems, we present a modern introduction of the NEGF approach to quantum transport. We discuss the inclusion of inter-particle interactions using diagrammatic techniques, and the use of the so-called embedding and inbedding techniques which take the bath couplings into account non-perturbatively. In various limits, such as the non-interacting limit and the steady-state limit, we then show how the NEGF formalism elegantly reduces to well-known formulae in quantum transport as special cases. We then discuss non-equilibrium transport in general, for both particle and energy currents. Under the presence of a time-dependent drive - encompassing pump-probe scenarios as well as driven quantum systems - we discuss the transient as well as asymptotic behavior, and also how to use NEGF to infer information on the out-of-equilibrium system. As illustrative examples, we consider model systems general enough to pave the way to realistic systems. These examples encompass one- and two-dimensional electronic systems, systems with electron-phonon couplings, topological superconductors, and optically responsive molecular junctions where electron-photon couplings are relevant., Comment: Topical review, 97 pages, 15 figures

Published

2022

8. A hybrid classical-quantum approach to speed-up Q-learning

Author

Sannia, A., Giordano, A., Gullo, N. Lo, Mastroianni, C., and Plastina, F.

Published

2023

9. Spectral properties of correlated quantum wires and carbon nanotubes within the Generalized Kadanoff-Baym Ansatz

Author

Cosco, F., Talarico, N. W., Tuovinen, R., and Gullo, N. Lo

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We investigate the spectral properties of an open interacting system by solving the Generalized Kadanoff-Baym Ansatz (GKBA) master equation for the single-particle density matrix, namely the time-diagonal lesser Green's function. To benchmark its validity, we compare the solution obtained within the GKBA with the solution of the Dyson equation (equivalently the full Kadanoff-Baym equations). In both approaches, we treat the interaction within the self-consistent second-order Born approximation, whereas the GKBA still retains the retarded propagator calculated at the Hartree-Fock level. We consider the case of two leads connected through a central correlated region where particles can interact and exploit the stationary particle current at the boundary of the junction as a probe of the spectral features of the system. In this work, as an example, we take the central region to be a one-dimensional quantum wire and a two-dimensional carbon nanotube and show that the solution of the GKBA master equation well captures their spectral features. Our result demonstrates that, even when the propagator used is at the Hartree-Fock level, the GBKA solution retains the main spectral features of the self-energy used., Comment: 10 pages, 6 figures

Published

2020

10. Exact spectral function of a Tonks-Girardeau gas in a lattice

Author

Settino, J., Gullo, N. Lo, Plastina, F., and Minguzzi, A.

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

The single-particle spectral function of a strongly correlated system is an essential ingredient to describe its dynamics and transport properties. We develop a general method to calculate the exact spectral function of a strongly interacting one-dimensional Bose gas in the Tonks-Girardeau regime, valid for any type of confining potential, and apply it to bosons on a lattice to obtain the full spectral function, at all energy and momentum scales. We find that it displays three main singularity lines. The first two can be identified as the analogs of Lieb-I and Lieb-II modes of a uniform fluid; the third one, instead, is specifically due to the presence of the lattice. We show that the spectral function displays a power-law behaviour close to the Lieb-I and Lieb-II singularities, as predicted by the non-linear Luttinger liquid description, and obtain the exact exponents. In particular, the Lieb-II mode shows a divergence in the spectral function, differently from what happens in the dynamical structure factor, thus providing a route to probe it in experiments with ultracold atoms., Comment: 10 pages, 3 figures

Published

2020

11. A Single-Quantum-Dot Heat Valve

Author

Dutta, B., Majidi, D., Talarico, N. W., Gullo, N. Lo, Winkelmann, C. B., and Courtois, H.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We demonstrate gate control of electronic heat flow in a thermally-biased single-quantum-dot junction. Electron temperature maps taken in the immediate vicinity of the junction, as a function of the gate and bias voltages applied to the device, reveal clearly defined Coulomb diamond patterns revealing a maximum heat transfer right at the charge degeneracy point. The non-trivial bias and gate dependence of this heat valve results from both the quantum nature of the dot at the heart of device and its strong coupling to leads., Comment: 11 pages, 11 figures, to appear in Phys. Rev. Lett

Published

2020

12. Study of the energy variation in many-body open quantum systems: role of interactions in the weak and strong coupling regimes

Author

Talarico, N. W., Maniscalco, S., and Gullo, N. Lo

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We derive an expression for the rate of change of the energy of an interacting many-body system connected to macroscopic leads. We show that the energy variation is the sum of contributions from each different lead. Unlike the charge current each of this contribution can differ from the rate of change of the energy of the lead. We demonstrate that the discrepancy between the two is due to the direct exchange of energy among the considered lead and all other leads. We conclude that the microscopic mechanism behind it are virtual processes via the interacting central region. We also speculate on what are the implications of our findings in the calculation of the thermal conductance of an interacting system., Comment: Published version: 11 pages, 4 figures

Published

2019

13. Emergence of anomalous dynamics from the underlying singular continuous spectrum in interacting many-body systems

Author

Settino, J., Talarico, N. W., Cosco, F., Plastina, F., Maniscalco, S., and Gullo, N. Lo

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We investigate the dynamical properties of an interacting many-body system with a non-trivial energy potential landscape that may induce a singular continuous single-particle energy spectrum. Focusing on the Aubry-Andr\'e model, whose anomalous transport properties in presence of interaction has recently been demonstrated experimentally in an ultracold gas setup, we discuss the anomalous slowing down of the dynamics it exhibits and show that it emerges from the singular-continuous nature of the single-particle excitation spectrum. Our study demonstrates that singular-continuous spectra can be found in interacting systems, unlike previously conjectured by treating the interactions in the mean-field approximation. This, in turns, also highlights the importance of the many-body correlations in giving rise to anomalous dynamics, which, in many-body systems, can result from a non-trivial interplay between geometry and interactions., Comment: 8 pages, 6 figures

Published

2018

14. A scalable numerical approach to the solution of the Dyson equation for the non-equilibrium single-particle Green's function

Author

Talarico, N. W., Maniscalco, S., and Gullo, N. Lo

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

In this work we present a numerical method to solve the set of Dyson-like equations arising the context of non-equilibrium Green's functions. The technique is based on the self-consistent solution of the Dyson equations for the interacting single-particle Green's function once a choice for the self-energy, functional of the single-particle Green's function itself, is done. We briefly review the theory of the non-equilibrium Green's functions in order to highlight the main point useful in discussing the proposed technique. We also discuss the relation between our approach and the textbook approach to solve the Kadanoff-Baym equations. We then present and discuss the numerical implementation which is based on the distribution of the elements of the Green's function and self-energies on a grid of processes. We discuss how the structure of the considered self-energy approximations influences the distribution of the matrices in order to minimize the communication time among processes and which should be considered in the case of other approximations. We give an example of the application of our technique to the case of quenches in ultracold gases, also discussing to the convergence features of our scheme., Comment: 12 pages, 6 figures

Published

2018

15. Signatures of the single particle mobility edge in the ground state properties of Tonks-Girardeau and non-interacting Fermi gases in a bichromatic potential

Author

Settino, J., Gullo, N. Lo, Sindona, A., Goold, J., and Plastina, F.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We explore the ground state properties of cold atomic gases, loaded into a bichromatic lattice, focusing on the cases of non-interacting fermions and hard-core (Tonks-Girardeau) bosons, trapped by the combination of two potentials with incommensurate periods. For such systems, two limiting cases have been thoroughly established. In the tight-binding limit, the single-particle states in the lowest occupied band show a localization transition, as the strength of the second potential is increased above a certain threshold. In the continuous limit, when the tight-binding approximation does not hold anymore, a mobility edge is found, whose position in energy depends upon the strength of the second potential. Here, we study how the crossover from the discrete to the continuum behavior occurs, and prove that signatures of the localization transition and mobility edge clearly appear in the generic many-body properties of the systems. Specifically, we evaluate the momentum distribution, which is a routinely measured quantity in experiments with cold atoms, and demonstrate that, even in the presence of strong boson-boson interactions, the single particle mobility edge can be observed in the ground state properties., Comment: 9 pages, 10 figures

Published

2016

16. Dynamics and energy spectra of aperiodic discrete-time quantum walks

Author

Ambarish, C. V., Gullo, N. Lo, Busch, Th., Dell'Anna, L., and Chandrashekar, C. M.

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks

Abstract

Deterministically aperiodic sequences are an intermediary between periodic sequences and completely random sequences. Materials which are translationally periodic have Bloch-like extended states, while random media exhibit Anderson localisation. Materials constructed on the basis of deterministic aperiodic sequences such as Fibonacci, Thue-Morse, and Rudin-Shapiro exhibit different properties, which can be related to their spectrum. Here, by investigating the dynamics of discrete-time quantum walks using different aperiodic sequences of coin operations in position space and time we establish the role of the diffraction spectra in characterizing the spreading of the wavepacket., Comment: 12 pages, 18 figures

Published

2016

17. Local Quench, Majorana Zero Modes, and Disturbance Propagation in the Ising chain

Author

Francica, G., Apollaro, T. J. G., Gullo, N. Lo, and Plastina, F.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We study the generation and propagation of local perturbations in a quantum many-body spin system. In particular, we study the Ising model in transverse field in the presence of a local field defect at one edge. This system possesses a rich phase diagram with different regions characterized by the presence of one or two Majorana zero modes. We show that their localized character {\it i}) enables a characterization of the Ising phase transition through a local-only measurement performed on the edge spin, and {\it ii}) strongly affects the propagation of quasiparticles emitted after the sudden removal of the defect, so that the dynamics of the local magnetization show clear deviations from a ballistic behavior in presence of the Majorana fermions., Comment: comments welcome

Published

2016

18. Self-consistent Keldysh approach to quenches in weakly interacting Bose-Hubbard model

Author

Gullo, N. Lo and Dell'Anna, L.

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

We present a non-equilibrium Green's functional approach to study the dynamics following a quench in weakly interacting Bose Hubbard model (BHM). The technique is based on the self-consistent solution of a set of equations which represents a particular case of the most general set of Hedin's equations for the interacting single-particle Green's function. We use the ladder approximation as a skeleton diagram for the two-particle scattering amplitude useful, through the self-energy in the Dyson equation, for finding the interacting single-particle Green's function. This scheme is then implemented numerically by a parallelized code. We exploit this approach to study the correlation propagation after a quench in the interaction parameter, for one (1D) and two (2D) dimensions. In particular, we show how our approach is able to recover the crossover from ballistic to diffusive regime by increasing the boson-boson interaction. Finally we also discuss the role of a thermal initial state on the dynamics both for 1D and 2D Bose Hubbard models, finding that surprisingly at high temperature a ballistic evolution is restored., Comment: 13 figures

Published

2016

19. Equivalence classes of Fibonacci lattices and their similarity properties

Author

Gullo, N. Lo, Vittadello, L., Bazzan, M., and Dell'Anna, L.

Subjects

Condensed Matter - Other Condensed Matter

Abstract

We investigate, theoretically and experimentally,the properties of diffraction spectra of Fibonacci lattices with arbitrary spacings. We show that, by means of a suitable composition rule, a Fibonacci sequence can be mapped into another one with a different lattice spacing. In this way we are able to define equivalence classes of Fibonacci structures and their generators, namely the Fibonacci sequences from which all the others can be obtained by compostion rule. We show that each class can be characterized by a given diffraction pattern which is essentially the one of the generator, in the sense that the most prominent features of this spectrum are common to all the elements of the class. This theoretical prediction is in good agreement with experimental results., Comment: 10 pages, 10 figures

Published

2016

20. Quantum Otto cycle with inner friction: finite-time and disorder effects

Author

Alecce, A., Galve, F., Gullo, N. Lo, Dell'Anna, L., Plastina, F., and Zambrini, R.

Subjects

Quantum Physics

Abstract

The concept of inner friction, by which a quantum heat engine is unable to follow adiabatically its strokes and thus dissipates useful energy, is illustrated in an exact physical model where the working substance consists of an ensemble of misaligned spins interacting with a magnetic field and performing the Otto cycle. The effect of this static disorder under a finite-time cycle gives a new perspective of the concept of inner friction under realistic settings. We investigate the efficiency and power of this engine and relate its performance to the amount of friction from misalignment and to the temperature difference between heat baths. Finally we propose an alternative experimental implementation of the cycle where the spin is encoded in the degree of polarization of photons., Comment: Published version in the Focus Issue on "Quantum Thermodynamics"

Published

2015

21. Irreversible work and inner friction in quantum thermodynamic processes

Author

Plastina, F., Alecce, A., Apollaro, T. J. G., Falcone, G., Francica, G., Galve, F., Gullo, N. Lo, and Zambrini, R.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

We discuss the thermodynamics of closed quantum systems driven out of equilibrium by a change in a control parameter and undergoing a unitary process. We compare the work actually done on the system with the one that would be performed along ideal adiabatic and isothermal transformations. The comparison with the latter leads to the introduction of irreversible work, while that with the former leads to the introduction of inner friction. We show that these two quantities can be treated on equal footing, as both can be linked with the heat exchanged in thermalization processes and both can be expressed as relative entropies. Furthermore, we show that a specific fluctuation relation for the entropy production associated with the inner friction exists, which allows the inner friction to be written in terms of its cumulants., Comment: improved text, new citations added

Published

2014

22. Non-Markovianity criteria for open system dynamics

Author

Gullo, N. Lo, Sinayskiy, I., Busch, Th., and Petruccione, F.

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics

Abstract

A universal definition of non-Markovianity for open systems dynamics is proposed. It is extended from the classical definition to the quantum realm by showing that a `transition' from the Markov to the non-Markov regime occurs when the correlations between the system and the environment, generated by their joint evolution, can no longer be neglected. The suggested definition is based on the comparison between measured correlation functions and those built by assuming that the system is in a Markov regime thus giving a figure of merit of the error coming from this assumption. It is shown that the knowledge of the dynamical map and initial condition of the system is not enough to fully characterise the non-Markovian dynamics of the reduced system. The example of three exactly solvable models, i.e. decoherence and spontaneous emission of the qubit in a bosonic bath and decoherence of the photon's polarization induced by interaction with its spacial degrees of freedom, reveals that previously proposed Markovianity criteria and measures which are based on dynamical map analysis fail to recognise non-Markov behaviour., Comment: 6 pages (2 Figures) + 10 pages supplementing material (8 Figures)

Published

2014

23. Decoherence in a fermion environment: Non-Markovianity and Orthogonality Catastrophe

Author

Plastina, F., Sindona, A., Goold, J., Gullo, N. Lo, and Lorenzo, S.

Subjects

Quantum Physics

Abstract

We analyze the non-Markovian character of the dynamics of an open two-level atom interacting with a gas of ultra-cold fermions. In particular, we discuss the connection between the phenomena of orthogonality catastrophe and Fermi edge singularity occurring in such a kind of environment and the memory-keeping effects which are displayed in the time evolution of the open system.

Published

2013

24. Statistics of the work distribution for a quenched Fermi gas

Author

Sindona, A., Gullo, N. Lo, Goold, J., and Plastina, F.

Subjects

Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

The local quench of a Fermi gas, giving rise to the Fermi edge singularity and the Anderson orthogonality catastrophe, is a rare example of an analytically tractable out of equilibrium problem in condensed matter. It describes the universal physics which occurs when a localized scattering potential is suddenly introduced in a Fermi sea leading to a brutal disturbance of the quantum state. It has recently been proposed that the effect could be efficiently simulated in a controlled manner using the tunability of ultra-cold atoms. In this work, we analyze the quench problem in a gas of trapped ultra-cold fermions from a thermodynamic perspective using the full statistics of the so called work distribution. The statistics of work are shown to provide an accurate insight into the fundamental physics of the process.

Published

2013

25. Orthogonality catastrophe and decoherence in a trapped-Fermion environment

Author

Sindona, A., Goold, J., Gullo, N. Lo, Lorenzo, S., and Plastina, F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The Fermi edge singularity and the Anderson orthogonality catastrophe describe the universal physics which occurs when a Fermi sea is locally quenched by the sudden switching of a scattering potential, leading to a brutal disturbance of its ground state. We demonstrate that the effect can be seen in the controllable domain of ultracold trapped gases by providing an analytic description of the out-of-equilibrium response to an atomic impurity, both at zero and at finite temperature. Furthermore, we link the transient behavior of the gas to the decoherence of the impurity, and, in particular to the amount of non-markovianity of its dynamics., Comment: substantially rewritten - errors and typos corrected

Published

2012

26. Critical assessment of two-qubit post-Markovian master equations

Author

Campbell, S., Smirne, A., Mazzola, L., Gullo, N. Lo, Vacchini, B., Busch, Th., and Paternostro, M.

Subjects

Quantum Physics

Abstract

A post-Markovian master equation has been recently proposed as a tool to describe the evolution of a system coupled to a memory-keeping environment [A. Shabani and D. A. Lidar, Phys. Rev. A 71, 020101 (R) (2005)]. For a single qubit affected by appropriately chosen environmental conditions, the corresponding dynamics is always legitimate and physical. Here we extend such situation to the case of two qubits, only one of which experiences the environmental effects. We show how, despite the innocence of such an extension, the introduction of the second qubit should be done cum grano salis to avoid consequences such as the breaking of the positivity of the associated dynamical map. This hints at the necessity of using care when adopting phenomenologically derived models for evolutions occurring outside the Markovian framework., Comment: 7 pages, 1 figure, RevTeX4. Close to published version

Published

2012

27. Probing mechanical quantum coherence with an ultracold-atom probe

Author

Gullo, N. Lo, Busch, Th., Palma, G. M., and Paternostro, M.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We propose a scheme to probe quantum coherence in the state of a nano-cantilever based on its magnetic coupling (mediated by a magnetic tip) with a spinor Bose Einstein condensate (BEC). By mapping the BEC into a rotor, its coupling with the cantilever results in a gyroscopic motion whose properties depend on the state of the cantilever: the dynamics of one of the components of the rotor angular momentum turns out to be strictly related to the presence of quantum coherence in the state of the cantilever. We also suggest a detection scheme relying on Faraday rotation, which produces only a very small back-action on the BEC and it is thus suitable for a continuous detection of the cantilever's dynamics., Comment: 7 pages, 4 figures

Published

2011

28. Orthogonality catastrophe as a consequence of qubit embedding in an ultra-cold Fermi gas

Author

Goold, J., Fogarty, T., Gullo, N. Lo, Paternostro, M., and Busch, Th.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

We investigate the behaviour of a single qubit coupled to a low-dimensional, ultra-cold Fermi gas. The scattering between the system and the fermions leads to the loss of any coherence in the initial state of the qubit and we show that the exact dynamics of this process is strongly influenced by the effect of the orthogonality catastrophe within the gas. We highlight the relationship between the Loschmidt echo and the retarded Green's function - typically used to formulate the dynamical theory of the catastrophe - and demonstrate that the effect can be triggered and characterized via local operations on the qubit. We demonstrate how the expected broadening of the spectral function can be observed using Ramsey interferometry on the qubit., Comment: 4 and a bit pages, 3 figures. Updated version

Published

2011

29. Structural change of vortex patterns in anisotropic Bose-Einstein condensates

Author

Gullo, N. Lo, Busch, Th., and Paternostro, M.

Subjects

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

Abstract

We study the changes in the spatial distribution of vortices in a rotating Bose-Einstein condensate due to an increasing anisotropy of the trapping potential. Once the rotational symmetry is broken, we find that the vortex system undergoes a rich variety of structural changes, including the formation of zig-zag and linear configurations. These spatial re-arrangements are well signaled by the change in the behavior of the vortex-pattern eigenmodes against the anisotropy parameter. The existence of such structural changes opens up possibilities for the coherent exploitation of effective many-body systems based on vortex patterns., Comment: 5 pages, 4 figures

Published

2010

30. Vortex entanglement in Bose-Einstein condensates coupled to Laguerre-Gauss beams

Author

Gullo, N. Lo, McEndoo, S., Busch, Th., and Paternostro, M.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We study the establishment of vortex entanglement in remote and weakly interacting Bose Einstein condensates. We consider a two-mode photonic resource entangled in its orbital angular momentum (OAM) degree of freedom and, by exploiting the process of light-to-BEC OAM transfer, demonstrate that such entanglement can be efficiently passed to the matter-like systems. Our proposal thus represents a building block for novel low-dissipation and long-memory communication channels based on OAM. We discuss issues of practical realizability, stressing the feasibility of our scheme and present an operative technique for the indirect inference of the set vortex entanglement., Comment: 10 pages, 7 figures, RevTex4

Published

2009

31. Study of the energy variation in many-body open quantum systems: Role of interactions in the weak and strong coupling regimes

Author

Talarico, N. W., primary, Maniscalco, S., additional, and Gullo, N. Lo, additional

Published

2020

32. Finite-time quantum Stirling heat engine.

Author

Raja, S Hamedani, Maniscalco, S, Paraoanu, G S, Pekola, J P, and Gullo, N Lo

Subjects

HEAT engines, STIRLING engines, THERMODYNAMIC equilibrium, QUANTUM thermodynamics, THERMODYNAMIC cycles, THERMODYNAMICS, METHYLENE blue

Abstract

We study the thermodynamic performance of a finite-time non-regenerative quantum Stirling-like cycle used as a heat engine. We consider specifically the case in which the working substance (WS) is a two-level system (TLS). The Stirling cycle is made of two isochoric transformations separated by a compression and an expansion stroke during which the WS is in contact with a thermal reservoir. To describe these two strokes we derive a non-Markovian master equation which allows to study the real-time dynamics of a driven open quantum system with arbitrary fast driving. Following the real-time dynamics of the WS using this master equation, the endpoints of the isotherms can deviate from the equilibrium thermal states. The role of this deviation in the performance of the heat engine is addressed. We found that the finite-time dynamics and thermodynamics of the cycle depend non-trivially on the different time scales at play. In particular, driving the WS at a time scale comparable to the resonance time of the bath enhances the performance of the cycle and allows for an efficiency higher than the efficiency of the quasistatic cycle, but still below the Carnot bound. However, by adding thermalization of the WS with the baths at the end of compression/expansion processes one recovers the conventional scenario in which efficiency decreases by speeding up the processes. In addition, the performance of the cycle is dependent on the compression/expansion speeds asymmetrically, which suggests new freedom in optimizing quantum heat engines. The maximum output power and the maximum efficiency are obtained almost simultaneously when the real-time endpoints of the compression/expansion processes are considered instead of the equilibrium thermal endpoint states. However, the net extractable work always declines by speeding up the drive. [ABSTRACT FROM AUTHOR]

Published

2021

33. A study of the brightest peaks in the diffraction pattern of Fibonacci gratings

Author

Gullo, N Lo, primary, Vittadello, L, additional, Dell’Anna, L, additional, Merano, M, additional, Rossetto, N, additional, and Bazzan, M, additional

Published

2017

34. Quantum Otto cycle with inner friction: finite-time and disorder effects

Author

Alecce, A, primary, Galve, F, additional, Gullo, N Lo, additional, Dell’Anna, L, additional, Plastina, F, additional, and Zambrini, R, additional

Published

2015

35. Statistics of the work distribution for a quenched Fermi gas.

Author

Sindona, A, Goold, J, Gullo, N Lo, and Plastina, F

Subjects

ELECTRON gas, QUANTUM states, FERMIONS, NONEQUILIBRIUM thermodynamics, CONDENSED matter physics

Abstract

The local quench of a Fermi gas, giving rise to the Fermi edge singularity and the Anderson orthogonality catastrophe, is an analytically tractable out-of-equilibrium problem in condensed matter. It describes the generic physics that occurs when a localized scattering potential is suddenly introduced in a Fermi sea, leading to a brutal disturbance of its quantum state. It has recently been proposed that the effect could be efficiently simulated in a controlled manner using the tunability of ultra-cold atoms. In this work, we analyze the quench problem in a gas of trapped ultra-cold fermions from a thermodynamic perspective using the full statistics of the so-called work distribution. The work statistics are shown to provide an accurate insight into the fundamental physics of the process. [ABSTRACT FROM AUTHOR]

Published

2014

36. Single-Quantum-Dot Heat Valve.

Author

Dutta, B., Majidi, D., Talarico, N. W., Gullo, N. Lo, Courtois, H., and Winkelmann, C. B.

Subjects

*QUANTUM dots, *CHARGE transfer, *HEAT, *ELECTRONIC control, *ELECTRON temperature, *QUANTUM gates

Abstract

We demonstrate gate control of electronic heat flow in a thermally biased single-quantum-dot junction. Electron temperature maps taken in the immediate vicinity of the junction, as a function of the gate and bias voltages applied to the device, reveal clearly defined Coulomb diamond patterns that indicate a maximum heat transfer at the charge degeneracy point. The nontrivial bias and gate dependence of this heat valve results from the quantum nature of the dot at the heart of device and its strong coupling to leads. [ABSTRACT FROM AUTHOR]

Published

2020