Your search keyword '"Montangero S"' showing total 34 results

1. Entanglement generation in (1+1) D QED scattering processes

Author

Rigobello, M., Notarnicola, S., Magnifico, G., and Montangero, S.

Published

2021

2. Amplification of the parametric dynamical Casimir effect via optimal control

Author

Hoeb, F, Angaroni, F, Zoller, J, Calarco, T, Strini, G, Montangero, S, Benenti, G, Hoeb F., Angaroni F., Zoller J., Calarco T., Strini G., Montangero S., Benenti G., Hoeb, F, Angaroni, F, Zoller, J, Calarco, T, Strini, G, Montangero, S, Benenti, G, Hoeb F., Angaroni F., Zoller J., Calarco T., Strini G., Montangero S., and Benenti G.

Abstract

We introduce different strategies to enhance photon generation in a cavity within the Rabi model in the ultrastrong coupling regime. We show that a bang-bang strategy allows one to enhance the effect up to 1 order of magnitude with respect to simply driving the system in resonance for a fixed time. Moreover, up to about another order of magnitude can be gained by exploiting quantum optimal control strategies. Finally, we show that such optimized protocols are robust with respect to systematic errors and noise, paving the way to future experimental implementations of such strategies.

Published

2017

3. Real-Time Dynamics in U(1) Lattice Gauge Theories with Tensor Networks

Author

Química física, Kimika fisikoa, Pichler, T., Dalmonte, M., Rico Ortega, Enrique, Zoller, P., Montangero, S., Química física, Kimika fisikoa, Pichler, T., Dalmonte, M., Rico Ortega, Enrique, Zoller, P., and Montangero, S.

Abstract

Tensor network algorithms provide a suitable route for tackling real-time-dependent problems in lattice gauge theories, enabling the investigation of out-of-equilibrium dynamics. We analyze a U(1) lattice gauge theory in (1 + 1) dimensions in the presence of dynamical matter for different mass and electric-field couplings, a theory akin to quantum electrodynamics in one dimension, which displays string breaking: The confining string between charges can spontaneously break during quench experiments, giving rise to charge-anticharge pairs according to the Schwinger mechanism. We study the real-time spreading of excitations in the system by means of electric-field and particle fluctuations. We determine a dynamical state diagram for string breaking and quantitatively evaluate the time scales for mass production. We also show that the time evolution of the quantum correlations can be detected via bipartite von Neumann entropies, thus demonstrating that the Schwinger mechanism is tightly linked to entanglement spreading. To present a variety of possible applications of this simulation platform, we show how one could follow the real-time scattering processes between mesons and the creation of entanglement during scattering processes. Finally, we test the quality of quantum simulations of these dynamics, quantifying the role of possible imperfections in cold atoms, trapped ions, and superconducting circuit systems. Our results demonstrate how entanglement properties can be used to deepen our understanding of basic phenomena in the real-time dynamics of gauge theories such as string breaking and collisions.

Published

2016

4. Robust optimal gates for Josephson charge qubits

Author

Montangero, S., Calarco, T., and Fazio, R.

Subjects

Physics, ddc:530

Published

2007

5. Complexity of controlling quantum many-body dynamics

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, Caneva, T., Silva, A., Fazio, R., Calarco, T., Montangero, S., Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, Caneva, T., Silva, A., Fazio, R., Calarco, T., and Montangero, S.

Abstract

We demonstrate that arbitrary time evolutions of many-body quantum systems can be reversed even in cases when only part of the Hamiltonian can be controlled. The reversed dynamics obtained via optimal control—contrary to standard time-reversal procedures—is extremely robust to external sources of noise. We provide a lower bound on the control complexity of a many-body quantum dynamics in terms of the dimension of the manifold supporting it, elucidating the role played by integrability in this context., European Union (SIQS, & PICC, SOLID), German Research Foundation (SFB/TRR21), National Science Foundation (U.S.) (Grant No. NSF PHY11-25915)

Published

2014

6. Information Theoretical Analysis of Quantum Optimal Control

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, Montangero, S., Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, and Montangero, S.

Abstract

We study the relations between classical information and the feasibility of accurate manipulation of quantum system dynamics. We show that if an efficient classical representation of the dynamics exists, optimal control problems on many-body quantum systems can be solved efficiently with finite precision. In particular, one-dimensional slightly entangled dynamics can be efficiently controlled. We provide a bound for the minimal time necessary to perform the optimal process given the bandwidth of the control pulse, which is the continuous version of the Solovay-Kitaev theorem. Finally, we quantify how noise affects the presented results., United States. Defense Advanced Research Projects Agency, United States. Air Force Office of Scientific Research, United States. Army Research Office

Published

2014

7. Trap modulation spectroscopy of the Mott-insulator transition in optical lattices

Author

Lignier, H., Zenesini, A., Ciampini, D., Morsch, O., Arimondo, E., Montangero, S., Pupillo, G., Fazio, R., Lignier, H., Zenesini, A., Ciampini, D., Morsch, O., Arimondo, E., Montangero, S., Pupillo, G., and Fazio, R.

Abstract

We introduce a new technique to probe the properties of an interacting cold atomic gas that can be viewed as a dynamical compressibility measurement. We apply this technique to the study of the superfluid to Mott insulator quantum phase transition in one and three dimensions for a bosonic gas trapped in an optical lattice. Excitations of the system are detected by time-of-flight measurements. The experimental data for the one-dimensional case are in good agreement with the results of a time-dependent density matrix renormalization group calculation.

Published

2008

8. Information Theoretical Analysis of Quantum Optimal Control.

Author

Lloyd, S. and Montangero, S.

Subjects

*QUANTUM mechanics, *MATHEMATICS theorems, *BANDWIDTHS, *ELECTROMAGNETIC pulses, *INFORMATION processing

Abstract

We study the relations between classical information and the feasibility of accurate manipulation of quantum system dynamics. We show that if an efficient classical representation of the dynamics exists, optimal control problems on many-body quantum systems can be solved efficiently with finite precision. In particular, one-dimensional slightly entangled dynamics can be efficiently controlled. We provide a bound for the minimal time necessary to perform the optimal process given the bandwidth of the control pulse, which is the continuous version of the Solovay-Kitaev theorem. Finally, we quantify how noise affects the presented results. [ABSTRACT FROM AUTHOR]

Published

2014

9. Universal aspects in the behavior of the entanglement spectrum in one dimension: Scaling transition at the factorization point and ordered entangled structures.

Author

Giampaolo, S. M., Montangero, S., Dell’Anno, F., De Siena, S., and Illuminati, F.

Subjects

*QUASIPARTICLES, *QUANTUM theory, *PARTICLES (Nuclear physics), *ISING model, *FERROMAGNETISM

Abstract

We investigate the scaling of the entanglement spectrum and of the Rényi block entropies and determine its universal aspects in the ground state of critical and noncritical one-dimensional quantum spin models. In all cases, the scaling exhibits an oscillatory behavior that terminates at the factorization point and whose frequency is universal. Parity effects in the scaling of the Rényi entropies for gapless models at zero field are thus shown to be a particular case of such universal behavior. Likewise, the absence of oscillations for the Ising chain in transverse field is due to the vanishing value of the factorizing field for this particular model. In general, the transition occurring at the factorizing field between two different scaling regimes of the entanglement spectrum corresponds to a quantum transition to the formation of finite-range, ordered structures of quasidimers, quasitrimers, and quasipolymers. This entanglement-driven transition is superimposed to and independent of the long-range magnetic order in the broken symmetry phase. Therefore, it conforms to recent generalizations that identify and classify the quantum phases of matter according to the structure of ground-state entanglement patterns. We characterize this form of quantum order by a global order parameter of entanglement defined as the integral, over blocks of all lengths, of the Rényi entropy of infinite order. Equivalently, it can be defined as the integral of the bipartite single-copy or geometric entanglement. The global entanglement order parameter remains always finite at fields below the factorization point and vanishes identically above it. [ABSTRACT FROM AUTHOR]

Published

2013

10. Noise-Resistant Optimal Spin Squeezing via Quantum Control

Author

Caneva, T., Montangero, S., Lukin, Mikhail D., and Calarco, Tommaso

Abstract

Entangled atomic states, such as spin squeezed states, represent a promising resource for a new generation of quantum sensors and atomic clocks. We demonstrate that optimal control techniques can be used to substantially enhance the degree of spin squeezing in strongly interacting many-body systems, even in the presence of noise and imperfections. Specifically, we present a time-optimal protocol that yields more than two orders of magnitude improvement with respect to conventional adiabatic preparation. Potential experimental implementations are discussed., Physics

Published

2013

11. Dressing the chopped-random-basis optimization: A bandwidth-limited access to the trap-free landscape.

Author

Rach, N., Calarco, T., Montangero, S., and Müller, M. M.

Subjects

*ALGORITHMS, *MATHEMATICAL optimization, *LANDSCAPES, *CONSTRAINTS (Physics), *MAGNETIC traps

Abstract

In quantum optimal control theory the success of an optimization algorithm is highly influenced by how the figure of merit to be optimized behaves as a function of the control field, i.e., by the control landscape. Constraints on the control field introduce local minima in the landscape--false traps--which might prevent an efficient solution of the optimal control problem. Rabitz et al. [Science 303, 1998 (2004)] showed that local minima occur only rarely for unconstrained optimization. Here, we extend this result to the case of bandwidth-limited control pulses showing that in this case one can eliminate the false traps arising from the constraint. Based on this theoretical understanding, we modify the chopped-random-basis (CRAB) optimal control algorithm and show that this development exploits the advantages of both (unconstrained) gradient algorithms and of truncated basis methods, allowing one to always follow the gradient of the unconstrained landscape by bandwidth-limited control functions. We study the effects of additional constraints and show that for reasonable constraints the convergence properties are still maintained. Finally, we numerically show that this approach saturates the theoretical bound on the minimal bandwidth of the control needed to optimally drive the system. [ABSTRACT FROM AUTHOR]

Published

2015

12. Entanglement of Formation of Mixed Many-Body Quantum States via Tree Tensor Operators.

Author

Arceci, L., Silvi, P., and Montangero, S.

Subjects

*QUANTUM states, *DENSITY matrices, *TREES, *STATE laws, *ENTROPY

Abstract

We present a numerical strategy to efficiently estimate bipartite entanglement measures, and in particular the entanglement of formation, for many-body quantum systems on a lattice. Our approach exploits the tree tensor operator tensor network Ansatz, a positive loopless representation for density matrices which, as we demonstrate, efficiently encodes information on bipartite entanglement, enabling the upscaling of entanglement estimation. Employing this technique, we observe a finite-size scaling law for the entanglement of formation in 1D critical lattice models at finite temperature for up to 128 spins, extending to mixed states the scaling law for the entanglement entropy. [ABSTRACT FROM AUTHOR]

Published

2022

13. Synthetic helical liquids with ultracold atoms in optical lattices.

Author

Budich, J. C., Laflamme, C., Tschirsich, F., Montangero, S., and Zoller, P.

Subjects

*ULTRACOLD molecules, *OPTICAL lattices, *SPIN polarization, *RENORMALIZATION group, *FERMIONS

Abstract

We discuss a platform for the synthetic realization of key physical properties of helical Tomonaga Luttinger liquids (HTLLs) with ultracold fermionic atoms in one-dimensional optical lattices. The HTLL is a strongly correlated metallic state where spin polarization and propagation direction of the itinerant particles are locked to each other. We propose an unconventional one-dimensional Fermi-Hubbard model which, at quarter filling, resembles the HTLL in the long wavelength limit, as we demonstrate with a combination of analytical (bosonization) and numerical (density matrix renormalization group) methods. An experimentally feasible scheme is provided for the realization of this model with ultracold fermionic atoms in optical lattices. Finally, we discuss how the robustness of the HTLL against backscattering and imperfections, well known from its realization at the edge of two-dimensional topological insulators, is reflected in the synthetic one-dimensional scenario proposed here. [ABSTRACT FROM AUTHOR]

Published

2015

14. Unconstrained tree tensor network: An adaptive gauge picture for enhanced performance.

Author

Gerster, M., Silvi, P., Rizzi, M., Fazio, R., Calarco, T., and Montangero, S.

Subjects

*MANY-body perturbation calculations, *TENSOR algebra, *ALGORITHMS, *BOUNDARY value problems, *BILINEAR forms, *BIQUADRATIC equations, *FERROMAGNETISM

Abstract

We introduce a variational algorithm to simulate quantum many-body states based on a tree tensor network ansatz which releases the isometry constraint usually imposed by the real-space renormalization coarse graining. This additional numerical freedom, combined with the loop-free topology of the tree network, allows one to maximally exploit the internal gauge invariance of tensor networks, ultimately leading to a computationally flexible and efficient algorithm able to treat open and periodic boundary conditions on the same footing. We benchmark the novel approach against the 1D Ising model in transverse field with periodic boundary conditions and discuss the strategy to cope with the broken translational invariance generated by the network structure. We then perform investigations on a state-of-the-art problem, namely, the bilinear-biquadratic model in the transition between dimer and ferromagnetic phases. Our results clearly display an exponentially diverging correlation length and thus support the most recent guesses on the peculiarity of the transition. [ABSTRACT FROM AUTHOR]

Published

2014

15. Tensor Networks for Lattice Gauge Theories and Atomic Quantum Simulation.

Author

Rico, E., Pichler, T., Dalmonte, M., Zoller, P., and Montangero, S.

Subjects

*LATTICE gauge theories, *ELECTRIC fields, *QUANTUM phase transitions, *ELECTRIC flux, *OPTICAL lattices

Abstract

We show that gauge invariant quantum link models, Abelian and non-Abelian, can be exactly described in terms of tensor networks states. Quantum link models represent an ideal bridge between high-energy and cold atom physics, as they can be used in cold atoms in optical lattices to study lattice gauge theories. In this framework, we characterize the phase diagram of a (1+1)D quantum link version of the Schwinger model in an external classical background electric field: the quantum phase transition from a charge and parity ordered phase with nonzero electric flux to a disordered one with a net zero electric flux configuration is described by the Ising universality class. [ABSTRACT FROM AUTHOR]

Published

2014

16. Complexity of controlling quantum many-body dynamics.

Author

Caneva, T., Silva, A., Fazio, R., Lloyd, S., Calarco, T., and Montangero, S.

Subjects

*MANY-body problem, *QUANTUM mechanics, *HAMILTONIAN systems, *OPTIMAL control theory, *QUANTUM theory, *QUANTUM perturbations

Abstract

We demonstrate that arbitrary time evolutions of many-body quantum systems can be reversed even in cases when only part of the Hamiltonian can be controlled. The reversed dynamics obtained via optimal control-- contrary to standard time-reversal procedures--is extremely robust to external sources of noise. We provide a lower bound on the control complexity of a many-body quantum dynamics in terms of the dimension of the manifold supporting it, elucidating the role played by integrability in this context. [ABSTRACT FROM AUTHOR]

Published

2014

17. Fast closed-loop optimal control of ultracold atoms in an optical lattice.

Author

Rosi, S., Bernard, A., Fabbri, N., Fallani, L., Fort, C., Inguscio, M., Calarco, T., and Montangero, S.

Subjects

*ATOMS, *QUANTUM theory, *SUPERFLUIDITY, *OPTICAL lattices, *QUANTUM phase transitions, *OPTIMAL control theory, *PHYSICS experiments

Abstract

We present experimental evidence of the successful closed-loop optimization of the dynamics of cold atoms in an optical lattice. We optimize the loading of an ultracold atomic gas minimizing the excitations in an array of one-dimensional (ID) tubes (3D-ID crossover) and we perform an optimal crossing of the quantum phase-transition from a superfluid to a Mott insulator in a 3D lattice. In both cases we enhance the experiment performances with respect to those obtained via adiabatic dynamics, effectively speeding up the process by more than a factor three while improving the quality of the desired transformation. [ABSTRACT FROM AUTHOR]

Published

2013

18. Room-temperature Rydberg single-photon source.

Author

Müller, M. M., Kölle, A., Löw, R., Pfau, T., Calarco, T., and Montangero, S.

Subjects

*TEMPERATURE effect, *RYDBERG states, *PHOTONS, *GAUSSIAN processes, *MATHEMATICAL optimization, *ATOMIC spectra

Abstract

We present an optimal protocol to implement a room-temperature Rydberg single-photon source within an experimental setup based on micro cells filled with thermal vapor. The optimization of a pulsed four wave mixing scheme allows us to double the effective Rydberg blockade radius as compared to a simple Gaussian pulse scheme, releasing some of the constraints on the geometry of the micro cells. The performance of the optimized protocol is improved by about 70% with respect to the standard protocol. [ABSTRACT FROM AUTHOR]

Published

2013

19. Two-Particle Interference with Double Twin-Atom Beams.

Author

Borselli, F., Maiwöger, M., Zhang, T., Haslinger, P., Mukherjee, V., Negretti, A., Montangero, S., Calarco, T., Mazets, I., Bonneau, M., and Schmiedmayer, J.

Subjects

*ATOMIC beams, *DEGREES of freedom, *ATOMS, *PARTICLE emissions

Abstract

We demonstrate a source for correlated pairs of atoms characterized by two opposite momenta and two spatial modes forming a Bell state only involving external degrees of freedom. We characterize the state of the emitted atom beams by observing strong number squeezing up to -10 dB in the correlated two-particle modes of emission. We furthermore demonstrate genuine two-particle interference in the normalized second-order correlation function g(2) relative to the emitted atoms. [ABSTRACT FROM AUTHOR]

Published

2021

20. Fractional quantum Hall effect in the interacting Hofstadter model via tensor networks.

Author

Gerster, M., Rizzi, M., Silvi, P., Dalmonte, M., and Montangero, S.

Subjects

*FRACTIONAL programming, *QUANTUM Hall effect, *TENSOR fields, *GREEN'S functions, *CHERN classes

Abstract

We show via tensor network methods that the Harper-Hofstadter Hamiltonian for hard-core bosons on a square geometry supports a topological phase realizing the ν=1/2 fractional quantum Hall (FQH) effect on the lattice. We address the robustness of the ground-state degeneracy and of the energy gap, measure the many-body Chern number, and characterize the system using Green functions, showing that they decay algebraically at the edges of open geometries, indicating the presence of gapless edge modes. Moreover, we estimate the topological entanglement entropy by taking a combination of lattice bipartitions that reproduces the topological structure of the original proposals by Kitaev and Preskill [Phys. Rev. Lett. 96, 110404 (2006)] and Levin and Wen [Phys. Rev. Lett. 96, 110405 (2006)]. The numerical results show that the topological contribution is compatible with the expected value γ=1/2. Our results provide extensive evidence that FQH states are within reach of state-of-the-art cold-atom experiments. [ABSTRACT FROM AUTHOR]

Published

2017

21. Positive Tensor Network Approach for Simulating Open Quantum Many-Body Systems.

Author

Werner, A. H., Jaschke, D., Silvi, P., Kliesch, M., Calarco, T., Eisert, J., and Montangero, S.

Subjects

*MANY-body problem, *QUANTUM optics, *CONDENSED matter physics

Abstract

Open quantum many-body systems play an important role in quantum optics and condensed matter physics, and capture phenomena like transport, the interplay between Hamiltonian and incoherent dynamics, and topological order generated by dissipation. We introduce a versatile and practical method to numerically simulate one-dimensional open quantum many-body dynamics using tensor networks. It is based on representing mixed quantum states in a locally purified form, which guarantees that positivity is preserved at all times. Moreover, the approximation error is controlled with respect to the trace norm. Hence, this scheme overcomes various obstacles of the known numerical open-system evolution schemes. To exemplify the functioning of the approach, we study both stationary states and transient dissipative behavior, for various open quantum systems ranging from few to many bodies. [ABSTRACT FROM AUTHOR]

Published

2016

22. Optimal preparation of quantum states on an atom-chip device.

Author

Lovecchio, C., Schäfer, F., Cherukattil, S., Khan, M. Alì, Herrera, I., Cataliotti, F. S., Calarco, T., Montangero, S., and Caruso, F.

Subjects

*BOSE-Einstein condensation, *QUANTUM states, *SUPERPOSITION (Optics)

Abstract

Atom chips provide compact and robust platforms towards the implementation of practical quantum technologies. A quick and faithful preparation of arbitrary input states for these devices is crucial but represents a challenging experimental task. This is especially difficult when the dynamical evolution is noisy and unavoidable setup imperfections have to be considered. Here, we experimentally prepare with very high fidelity nontrivial superpositions of internal states of a rubidium Bose-Einstein condensate realized on an atom chip. [ABSTRACT FROM AUTHOR]

Published

2016

23. Strongly Interacting Photons in 2D Waveguide QED.

Author

Tečer M, Di Liberto M, Silvi P, Montangero S, Romanato F, and Calajó G

Abstract

One-dimensional confinement in waveguide quantum electrodynamics (QED) plays a crucial role to enhance light-matter interactions and to induce a strong quantum nonlinear optical response. In two or higher-dimensional settings, this response is reduced since photons can be emitted within a larger phase space, opening the question whether strong photon-photon interaction can be still achieved. In this study, we positively answer this question for the case of a 2D square array of atoms coupled to the light confined into a two-dimensional waveguide. More specifically, we demonstrate the occurrence of long-lived two-photon repulsive and bound states with genuine 2D features. Furthermore, we observe signatures of these effects also in free-space atomic arrays in the form of weakly subradiant in-band scattering resonances. Our findings provide a paradigmatic signature of the presence of strong photon-photon interactions in 2D waveguide QED.

Published

2024

24. Efficient Tensor Network Ansatz for High-Dimensional Quantum Many-Body Problems.

Author

Felser T, Notarnicola S, and Montangero S

Abstract

We introduce a novel tensor network structure augmenting the well-established tree tensor network representation of a quantum many-body wave function. The new structure satisfies the area law in high dimensions remaining efficiently manipulatable and scalable. We benchmark this novel approach against paradigmatic two-dimensional spin models demonstrating unprecedented precision and system sizes. Finally, we compute the ground state phase diagram of two-dimensional lattice Rydberg atoms in optical tweezers observing nontrivial phases and quantum phase transitions, providing realistic benchmarks for current and future two-dimensional quantum simulations.

Published

2021

25. Probabilistic low-rank factorization accelerates tensor network simulations of critical quantum many-body ground states.

Author

Kohn L, Tschirsich F, Keck M, Plenio MB, Tamascelli D, and Montangero S

Abstract

We provide evidence that randomized low-rank factorization is a powerful tool for the determination of the ground-state properties of low-dimensional lattice Hamiltonians through tensor network techniques. In particular, we show that randomized matrix factorization outperforms truncated singular value decomposition based on state-of-the-art deterministic routines in time-evolving block decimation (TEBD)- and density matrix renormalization group (DMRG)-style simulations, even when the system under study gets close to a phase transition: We report linear speedups in the bond or local dimension of up to 24 times in quasi-two-dimensional cylindrical systems.

Published

2018

26. Crossover from Classical to Quantum Kibble-Zurek Scaling.

Author

Silvi P, Morigi G, Calarco T, and Montangero S

Abstract

The Kibble-Zurek (KZ) hypothesis identifies the relevant time scales in out-of-equilibrium dynamics of critical systems employing concepts valid at equilibrium: It predicts the scaling of the defect formation immediately after quenches across classical and quantum phase transitions as a function of the quench speed. Here, we study the crossover between the scaling dictated by a slow quench, which is ruled by the critical properties of the quantum phase transition, and the excitations due to a faster quench, where the dynamics is often well described by the classical model. We estimate the value of the quench rate that separates the two regimes and support our argument using numerical simulations of the out-of-equilibrium many-body dynamics. For the specific case of a ϕ^{4} model we demonstrate that the two regimes exhibit two different power-law scalings, which are in agreement with the KZ theory when applied to the quantum and classical cases. This result contributes to extending the prediction power of the Kibble-Zurek mechanism and to providing insight into recent experimental observations in systems of cold atoms and ions.

Published

2016

27. Optimal control technique for many-body quantum dynamics.

Author

Doria P, Calarco T, and Montangero S

Abstract

We present an efficient strategy for controlling a vast range of nonintegrable quantum many-body one-dimensional systems that can be merged with state-of-the-art tensor network simulation methods such as the density matrix renormalization group. To demonstrate its potential, we employ it to solve a major issue in current optical-lattice physics with ultracold atoms: we show how to reduce by about 2 orders of magnitude the time needed to bring a superfluid gas into a Mott insulator state, while suppressing defects by more than 1 order of magnitude as compared to current experiments [T. Stöferle et al., Phys. Rev. Lett. 92, 130403 (2004)]. Finally, we show that the optimal pulse is robust against atom number fluctuations.

Published

2011

28. Optimal control at the quantum speed limit.

Author

Caneva T, Murphy M, Calarco T, Fazio R, Montangero S, Giovannetti V, and Santoro GE

Abstract

Optimal control theory is a promising candidate for a drastic improvement of the performance of quantum information tasks. We explore its ultimate limit in paradigmatic cases, and demonstrate that it coincides with the maximum speed limit allowed by quantum evolution.

Published

2009

29. Quantum multiscale entanglement renormalization ansatz channels.

Author

Giovannetti V, Montangero S, and Fazio R

Abstract

Tensor network representations of many-body quantum systems can be described in terms of quantum channels. We focus on channels associated with the multiscale entanglement renormalization ansatz tensor network that has been recently introduced to efficiently describe critical systems. Our approach allows us to compute the multiscale entanglement renormalization ansatz correspondent to the thermodynamical limit of a critical system introducing a transfer matrix formalism, and to relate the system critical exponents to the convergence rates of the associated channels.

Published

2008

30. Robust optimal quantum gates for Josephson charge qubits.

Author

Montangero S, Calarco T, and Fazio R

Abstract

Quantum optimal control theory allows us to design accurate quantum gates. We employ it to design high-fidelity two-bit gates for Josephson charge qubits in the presence of both leakage and noise. Our protocol considerably increases the fidelity of the gate and, more important, it is quite robust in the disruptive presence of 1/f noise. The improvement in the gate performances discussed in this work (errors approximately 10(-3)-10(-4) in realistic cases) allows us to cross the fault tolerance threshold.

Published

2007

31. Enhancement of pairwise entanglement via Z2 symmetry breaking.

Author

Osterloh A, Palacios G, and Montangero S

Abstract

We study the effect of symmetry breaking in a quantum phase transition on pairwise entanglement in spin-1/2 models. We give a set of conditions on correlation functions a model has to meet in order to keep the pairwise entanglement unchanged by a parity symmetry breaking. It turns out that all mean-field solvable models do meet this requirement, whereas the presence of strong correlations leads to a violation of this condition. This results in an order-induced enhancement of entanglement, and we report on two examples where this takes place.

Published

2006

32. Phase diagram of spin-1 bosons on one-dimensional lattices.

Author

Rizzi M, Rossini D, De Chiara G, Montangero S, and Fazio R

Abstract

Spinor Bose condensates loaded in optical lattices have a rich phase diagram characterized by different magnetic order. Here we apply the density matrix renormalization group to accurately determine the phase diagram for spin-1 bosons loaded on a one-dimensional lattice. The Mott lobes present an even or odd asymmetry associated to the boson filling. We show that for odd fillings the insulating phase is always in a dimerized state. The results obtained in this work are also relevant for the determination of the ground state phase diagram of the S = 1 Heisenberg model with biquadratic interaction.

Published

2005

33. Dynamics of entanglement in quantum computers with imperfections.

Author

Montangero S, Benenti G, and Fazio R

Abstract

The dynamics of the pairwise entanglement in a qubit lattice in the presence of static imperfections exhibits different regimes. We show that there is a transition from a perturbative region, where the entanglement is stable against imperfections, to the ergodic regime, in which a pair of qubits becomes entangled with the rest of the lattice and the pairwise entanglement drops to zero. The transition is almost independent of the size of the quantum computer. We consider both the case of an initial maximally entangled and separable state. In this last case there is a broad crossover region in which the computer imperfections can be used to create a significant amount of pairwise entanglement.

Published

2003

34. Efficient quantum computing of complex dynamics.

Author

Benenti G, Casati G, Montangero S, and Shepelyansky DL

Abstract

We propose a quantum algorithm which uses the number of qubits in an optimal way and efficiently simulates a physical model with rich and complex dynamics described by the quantum sawtooth map. The numerical study of the effect of static imperfections in the quantum computer hardware shows that the main elements of the phase space structures are accurately reproduced up to a time scale which is polynomial in the number of qubits. The errors generated by these imperfections are more significant than the errors of random noise in gate operations.

Published

2001