Your search keyword '"Hamma, A."' showing total 30 results

1. Random quantum batteries

Author

Francesco Caravelli, Ghislaine Coulter-De Wit, Luis Pedro García-Pintos, and Alioscia Hamma

Subjects

Physics, QC1-999

Abstract

Quantum nanodevices are fundamental systems in quantum thermodynamics that have been the subject of profound interest in recent years. Among these, quantum batteries play a very important role. In this paper we lay down a theory of random quantum batteries and provide a systematic way of computing the average work and work fluctuations in such devices by investigating their typical behavior. We show that the performance of random quantum batteries exhibits typicality and depends only on the spectral properties of the time evolving operator, the initial state, and the measuring Hamiltonian. At given revival times a random quantum battery features a quantum advantage over classical random batteries. Our method is particularly apt to be used both for exactly solvable models like the Jaynes-Cummings model or in perturbation theory, e.g., systems subject to harmonic perturbations. We also study the setting of quantum adiabatic random batteries.

Published

2020

2. Toric-boson model: Toward a topological quantum memory at finite temperature

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Hamma, Alioscia, Castelnovo, Claudio, Chamon, Claudio, Massachusetts Institute of Technology. Research Laboratory of Electronics, Hamma, Alioscia, Castelnovo, Claudio, and Chamon, Claudio

Abstract

We discuss the existence of stable topological quantum memory at finite temperature. At stake here is the fundamental question of whether it is, in principle, possible to store quantum information for macroscopic times without the intervention from the external world, that is, without error correction. We study the toric code in two dimensions with an additional bosonic field that couples to the defects, in the presence of a generic environment at finite temperature: the toric-boson model. Although the coupling constants for the bare model are not finite in the thermodynamic limit, the model has a finite spectrum. We show that in the topological phase, there is a finite temperature below which open strings are confined and therefore the lifetime of the memory can be made arbitrarily (polynomially) long in system size. The interaction with the bosonic field yields a long-range attractive force between the end points of open strings but leaves closed strings and topological order intact.

Published

2010

3. Quantum Bose-Hubbard model with an evolving graph as a toy model for emergent spacetime

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, Hamma, Alioscia, Markopoulou, Fotini, Caravelli, Francesco, Severini, Simone, Markström, Klas, Massachusetts Institute of Technology. Department of Mechanical Engineering, Lloyd, Seth, Hamma, Alioscia, Markopoulou, Fotini, Caravelli, Francesco, Severini, Simone, and Markström, Klas

Abstract

We present a toy model for interacting matter and geometry that explores quantum dynamics in a spin system as a precursor to a quantum theory of gravity. The model has no a priori geometric properties; instead, locality is inferred from the more fundamental notion of interaction between the matter degrees of freedom. The interaction terms are themselves quantum degrees of freedom so that the structure of interactions and hence the resulting local and causal structures are dynamical. The system is a Hubbard model where the graph of the interactions is a set of quantum evolving variables. We show entanglement between spatial and matter degrees of freedom. We study numerically the quantum system and analyze its entanglement dynamics. We analyze the asymptotic behavior of the classical model. Finally, we discuss analogues of trapped surfaces and gravitational attraction in this simple model., Natural Sciences and Engineering Research Council of Canada, Foundational Questions Institute, W. M. Keck Foundation Center for Extreme Quantum Information Theory

Published

2010

4. Lieb-Robinson Bounds and the Speed of Light from Topological Order

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Hamma, Alioscia, Markopoulou, Fotini, Premont-Schwarz, Isabeau, Severini, Simone, Massachusetts Institute of Technology. Research Laboratory of Electronics, Hamma, Alioscia, Markopoulou, Fotini, Premont-Schwarz, Isabeau, and Severini, Simone

Abstract

We apply the Lieb-Robinson bounds technique to find the maximum speed of interaction in a spin model with topological order whose low-energy effective theory describes light [see X.-G. Wen, Phys. Rev. B 68, 115413 (2003)]. The maximum speed of interactions in two dimensions is bounded from above by less than e times the speed of emerging light, giving a strong indication that light is indeed the maximum speed of interactions. This result does not rely on mean field theoretic methods. In higher spatial dimensions, the Lieb-Robinson speed is conjectured to increase linearly with the dimension itself. The implications for the horizon problem in cosmology are discussed., Foundational Questions Institute

Published

2010

5. Local convertibility of the ground state of the perturbed toric code.

Author

Santra, Siddhartha, Hamma, Alioscia, Cincio, Lukasz, Subasi, Yigit, Zanardi, Paolo, and Amico, Luigi

Subjects

*TORIC varieties, *GROUND state (Quantum mechanics), *QUANTUM perturbations, *HAMILTONIAN mechanics, *CATALYSTS, *TOPOLOGICAL spaces, *NUMERICAL analysis

Abstract

We present analytical and numerical studies of the behavior of the α-Renyi entropies in the toric code in presence of several types of perturbations aimed at studying the simulability of these perturbations to the parent Hamiltonian using local operations and classical communications (LOCC)—a property called local convertibility. In particular, the derivatives, with respect to the perturbation parameter, present different signs for different values of α within the topological phase. From the information-theoretic point of view, this means that such ground states cannot be continuously deformed within the topological phase by means of catalyst assisted local operations and classical communications (LOCC). Such LOCC differential convertibility is on the other hand always possible in the trivial disordered phase. The non-LOCC convertibility is remarkable because it can be computed on a system whose size is independent of correlation length. This method can therefore constitute an experimentally feasible witness of topological order. [ABSTRACT FROM AUTHOR]

Published

2014

6. Emergent Irreversibility and Entanglement Spectrum Statistics.

Author

Chamon, Claudio, Hamma, Alioscia, and Mucciolo, Eduardo R.

Subjects

*QUANTUM chaos, *STOCHASTIC analysis, *HAMILTON'S principle function, *ALGORITHMS, *QUANTUM theory

Abstract

We study the problem of irreversibility when the dynamical evolution of a many-body system is described by a stochastic quantum circuit. Such evolution is more general than a Hamiltonian one, and since energy levels are not well defined, the well-established connection between the statistical fluctuations of the energy spectrum and irreversibility cannot be made. We show that the entanglement spectrum provides a more general connection. Irreversibility is marked by a failure of a disentangling algorithm and is preceded by the appearance of Wigner-Dyson statistical fluctuations in the entanglement spectrum. This analysis can be done at the wave-function level and offers an alternative route to study quantum chaos and quantum integrability. [ABSTRACT FROM AUTHOR]

Published

2014

7. Local Response of Topological Order to an External Perturbation.

Author

Hamma, Alioscia, Cincio, Lukasz, Santra, Siddhartha, Zanardi, Paolo, and Amico, Luigi

Subjects

*RENYI'S entropy, *TORIC varieties, *QUANTUM perturbations, *ENTROPY, *TOPOLOGY, *PHYSICS research

Abstract

We study the behavior of the Renyi entropies for the toric code subject to a variety of different perturbations, by means of 2D density matrix renormalization group and analytical methods. We find that Renyi entropies of different index a display derivatives with opposite sign, as opposed to typical symmetry breaking states, and can be detected on a very small subsystem regardless of the correlation length. This phenomenon is due to the presence in the phase of a point with flat entanglement spectrum, zero correlation length, and area law for the entanglement entropy. We argue that this kind of splitting is common to all the phases with a certain group theoretic structure, including quantum double models, cluster states, and other quantum spin liquids. The fact that the size of the subsystem does not need to scale with the correlation length makes it possible for this effect to be accessed experimentally. [ABSTRACT FROM AUTHOR]

Published

2013

8. Topological Rényi Entropy after a Quantum Quench.

Author

Halász, Gábor B. and Hamma, Alioscia

Subjects

*ENTROPY, *TORIC varieties, *GROUND state (Quantum mechanics), *PERTURBATION theory, *THERMODYNAMICS, *MAGNETIC fields

Abstract

We present an analytical study on the resilience of topological order after a quantum quench. The system is initially prepared in the ground state of the toric-code model, and then quenched by switching on an external magnetic field. During the subsequent time evolution, the variation in topological order is detected via the topological Rényi entropy of order 2. We consider two different quenches: the first one has an exact solution, while the second one requires perturbation theory. In both cases, we find that the long-term time average of the topological Rényi entropy in the thermodynamic limit is the same as its initial value. Based on our results, we argue that topological order is resilient against a wide range of quenches. [ABSTRACT FROM AUTHOR]

Published

2013

9. Phase diagram and quench dynamics of the cluster-XY spin chain.

Author

Montes, Sebastián and Hamma, Alioscia

Subjects

*PHASE diagrams, *PHASE space, *MOLECULAR dynamics, *CLUSTER analysis (Statistics), *NUCLEAR spin, *MATHEMATICAL models, *QUANTUM theory, *CRITICAL point (Thermodynamics)

Abstract

We study the complete phase space and the quench dynamics of an exactly solvable spin chain, the cluster-AT model. In this chain, the cluster term and the XY couplings compete to give a rich phase diagram. The phase diagram is studied by means of the quantum geometric tensor. We study the time evolution of the system after a critical quantum quench using the Loschmidt echo. The structure of the revivals after critical quantum quenches presents a nontrivial behavior depending on the phase of the initial state and the critical point. [ABSTRACT FROM AUTHOR]

Published

2012

10. Quantum Entanglement in Random Physical States.

Author

Hamma, Alioscia, Santra, Siddhartha, and Zanardi, Paolo

Subjects

*HILBERT space, *QUANTUM theory, *PROOF theory, *STATISTICAL mechanics, *SYSTEMS theory, *LINEAR systems

Abstract

Most states in the Hubert space are maximally entangled. This fact has proven useful to investigate-- among other things--the foundations of statistical mechanics. Unfortunately, most states in the Hilbert space of a quantum many-body system are not physically accessible. We define physical ensembles of states acting on random factorized states by a circuit of length k of random and independent unitaries with local support. We study the typicality of entanglement by means of the purity of the reduced state. We find that for a time k = 0(1), the typical purity obeys the area law. Thus, the upper bounds for area law are actually saturated, on average, with a variance that goes to zero for large systems. Similarly, we prove that by means of local evolution a subsystem of linear dimensions L is typically entangled with a volume law when the time scales with the size of the subsystem. Moreover, we show that for large values of k the reduced state becomes very close to the completely mixed state. [ABSTRACT FROM AUTHOR]

Published

2012

11. García-Pintos, Hamma, and del Campo Reply.

Author

García-Pintos, Luis Pedro, Hamma, Alioscia, and del Campo, Adolfo

Subjects

*EVIDENCE, *STORAGE batteries

Abstract

We acknowledge that a derivation reported in Phys. Rev. Lett. 125, 040601 (2020) is incorrect as pointed out by Cusumano and Rudnicki. We respond by giving a correct proof of the claim "fluctuations in the free energy operator upper bound the charging power of a quantum battery" that we made in the Letter. [ABSTRACT FROM AUTHOR]

Published

2021

12. Probing topological order with Rnyi entropy.

Author

Halász, Gábor B. and Hamma, Alioscia

Subjects

*QUANTUM phase transitions, *MAGNETIC fields, *QUANTUM perturbations, *RENYI'S entropy, *PHASE equilibrium

Abstract

We present an analytical study of the quantum phase transition between the topologically ordered toric-code-model ground state and the disordered spin-polarized state. The phase transition is induced by applying an external magnetic field, and the variation in topological order is detected via two nonlocal quantities: the Wilson loop and the topological Rényi entropy of order 2. By exploiting an equivalence with the transverse-field Ising model and considering two different variants of the problem, we investigate the field dependence of these quantities by means of an exact treatment in the exactly solvable variant and complementary perturbation theories around the limits of zero and infinite fields in both variants. We find strong evidence that the phase transition point between topological order and disorder is marked by a discontinuity in the topological Rényi entropy and that the two phases around the phase transition point are characterized by its different constant values. Our results therefore indicate that the topological Rényi entropy is a proper topological invariant: its allowed values are discrete and can be used to distinguish between different phases of matter. [ABSTRACT FROM AUTHOR]

Published

2012

13. Ensembles of physical states and random quantum circuits on graphs.

Author

Hamma, Alioscia, Santra, Siddhartha, and Zanardi, Paolo

Subjects

*STATISTICAL ensembles, *GRAPH theory, *QUANTUM theory, *HAMILTONIAN systems, *ENTROPY

Abstract

In this paper we continue and extend the investigations of the ensembles of random physical states introduced in Hamma et al. [Phys. Rev. Lett. 109, 040502 (2012)]. These ensembles are constructed by finite-length random quantum circuits (RQC) acting on the (hyper)edges of an underlying (hyper)graph structure. The latter encodes for the locality structure associated with finite-time quantum evolutions generated by physical, i.e., local, Hamiltonians. Our goal is to analyze physical properties of typical states in these ensembles; in particular here we focus on proxies of quantum entanglement as purity and α-Renyi entropies. The problem is formulated in terms of matrix elements of superoperators which depend on the graph structure, choice of probability measure over the local unitaries, and circuit length. In the α = 2 casethese superoperators act on a restricted multiqubit space generated by permutation operators associated to the subsets of vertices of the graph. For permutationally invariant interactions the dynamics can be further restricted to an exponentially smaller subspace. We consider different families of RQCs and study their typical entanglement properties for finite time as well as their asymptotic behavior. We find that area law holds in average and that the volume law is a typical property (that is, it holds in average and the fluctuations around the average are vanishing for the large system) of physical states. The area law ariseswhen the evolution time is O(1) with respect to the size L of the system, while the volume law arises as is typical when the evolution time scales like O(L). [ABSTRACT FROM AUTHOR]

Published

2012

14. Trapped surfaces and emergent curved space in the Bose-Hubbard model.

Author

Caravelli, Francesco, Hamma, Alioscia, Markopoulou, Fotini, and Riera, Arnau

Subjects

*LATTICE field theory, *GRAPH theory, *GRAVITATIONAL fields, *SPACETIME, *MATHEMATICAL models, *DIFFERENTIAL equations, *NUMERICAL analysis

Abstract

A Bose-Hubbard model on a dynamical lattice was introduced in previous work as a spin system analogue of emergent geometry and gravity. Graphs with regions of high connectivity in the lattice were identified as candidate analogues of spacetime geometries that contain trapped surfaces. We carry out a detailed study of these systems and show explicitly that the highly connected subgraphs trap matter. We do this by solving the model in the limit of no back-reaction of the matter on the lattice, and for states with certain symmetries that are natural for our problem. We find that in this case the problem reduces to a one-dimensional Hubbard model on a lattice with variable vertex degree and multiple edges between the same two vertices. In addition, we obtain a (discrete) differential equation for the evolution of the probability density of particles which is closed in the classical regime. This is a wave equation in which the vertex degree is related to the local speed of propagation of probability. This allows an interpretation of the probability density of particles similar to that in analogue gravity systems: matter inside this analogue system sees a curved spacetime. We verify our analytic results by numerical simulations. Finally, we analyze the dependence of localization on a gradual, rather than abrupt, falloff of the vertex degree on the boundary of the highly connected region and find that matter is localized in and around that region. [ABSTRACT FROM AUTHOR]

Published

2012

15. Fluctuations in Extractable Work Bound the Charging Power of Quantum Batteries.

Author

García-Pintos, Luis Pedro, Hamma, Alioscia, and del Campo, Adolfo

Subjects

*ELECTRIC batteries, *QUANTUM fluctuations, *QUANTUM coherence, *HEAT engines, *BATTERY chargers

Abstract

We study the connection between the charging power of quantum batteries and the fluctuations of the extractable work. We prove that in order to have a nonzero rate of change of the extractable work, the state ρW of the battery cannot be an eigenstate of a "free energy operator," defined by F≡HW+β-1log(ρW), where HW is the Hamiltonian of the battery and β is the inverse temperature of a reference thermal bath with respect to which the extractable work is calculated. We do so by proving that fluctuations in the free energy operator upper bound the charging power of a quantum battery. Our findings also suggest that quantum coherence in the battery enhances the charging process, which we illustrate on a toy model of a heat engine. [ABSTRACT FROM AUTHOR]

Published

2020

16. Entanglement complexity in quantum many-body dynamics, thermalization, and localization.

Author

Zhi-Cheng Yang, Hamma, Alioscia, Giampaolo, Salvatore M., Mucciolo, Eduardo R., and Chamon, Claudio

Subjects

*QUANTUM entanglement, *QUANTUM entropy, *DYNAMICS

Abstract

Entanglement is usually quantified by von Neumann entropy, but its properties are much more complex than what can be expressed with a single number. We show that the three distinct dynamical phases known as thermalization, Anderson localization, and many-body localization are marked by different patterns of the spectrum of the reduced density matrix for a state evolved after a quantum quench. While the entanglement spectrum displays Poisson statistics for the case of Anderson localization, it displays universal Wigner-Dyson statistics for both the cases of many-body localization and thermalization, albeit the universal distribution is asymptotically reached within very different time scales in these two cases. We further show that the complexity of entanglement, revealed by the possibility of disentangling the state through a Metropolis-like algorithm, is signaled by whether the entanglement spectrum level spacing is Poisson or Wigner-Dyson distributed. [ABSTRACT FROM AUTHOR]

Published

2017

17. Area law from loop quantum gravity.

Author

Hamma, Alioscia, Ling-Yan Hung, Marcianò, Antonino, and Mingyi Zhang

Subjects

*QUANTUM entanglement, *QUANTUM gravity, *ENTROPY

Abstract

We explore the constraints following from requiring the area law in the entanglement entropy in the context of loop quantum gravity. We find a unique solution to the single-link wave function in the large j limit, believed to be appropriate in the semiclassical limit. We then generalize our considerations to multilink coherent states, and find that the area law is preserved very generically using our single-link wave function as a building block. Finally, we develop the framework that generates families of multilink states that preserve the area law while avoiding macroscopic entanglement, the space-time analogue of "Schrödinger's cat." We note that these states, defined on a given set of graphs, are the ground states of some local Hamiltonian that can be constructed explicitly. This can potentially shed light on the construction of the appropriate Hamiltonian constraints in the LQG framework. [ABSTRACT FROM AUTHOR]

Published

2018

18. Thermalization of topological entropy after a quantum quench.

Author

Yu Zeng, Hamma, Alioscia, and Heng Fan

Subjects

*THERMAL neutrons, *TOPOLOGICAL entropy, *HAMILTON'S equations, *WAVE functions, *QUANTUM mechanics

Abstract

Topologically ordered quantum phases are robust in the sense that perturbations in the Hamiltonian of the system will not change the topological nature of the ground-state wave function. However, in order to exploit topological order for applications such as self-correcting quantum memories and information processing, these states need to be also robust both dynamically and at finite temperature in the presence of an environment. It is well known that systems like the toric code in two spatial dimensions are fragile in temperature. In this paper, we show a completely analytic treatment of the toric code away from equilibrium, after a quantum quench of the system Hamiltonian. We show that, despite being subject to unitary evolution (and at zero temperature), the long-time behavior of the topological entropy is thermal, therefore vanishing. If the quench preserves a local gauge structure, there is a residual long-lived topological entropy. This also is the thermal behavior in presence of such gauge constraints. The result is obtained by studying the time evolution of the topological 2-Rényi entropy in a fully analytical, exact way. [ABSTRACT FROM AUTHOR]

Published

2016

19. Mutual information and spontaneous symmetry breaking.

Author

Hamma, A., Giampaolo, S. M., and Illuminati, F.

Subjects

*SYMMETRY breaking, *GROUND state (Quantum mechanics), *QUANTUM entropy

Abstract

We show that the metastable, symmetry-breaking ground states of quantum many-body Hamiltonians have vanishing quantum mutual information between macroscopically separated regions and are thus the most classical ones among all possible quantum ground states. This statement is obvious only when the symmetry-breaking ground states are simple product states, e.g., at the factorization point. On the other hand, symmetry-breaking states are in general entangled along the entire ordered phase, and to show that they actually feature the least macroscopic correlations compared to their symmetric superpositions is highly nontrivial. We prove this result in general, by considering the quantum mutual information based on the two-Rényi entanglement entropy and using a locality result stemming from quasiadiabatic continuation. Moreover, in the paradigmatic case of the exactly solvable one-dimensional quantum XY model, we further verify the general result by considering also the quantum mutual information based on the von Neumann entanglement entropy. [ABSTRACT FROM AUTHOR]

Published

2016

20. Two-Component Structure in the Entanglement Spectrum of Highly Excited States.

Author

Zhi-Cheng Yang, Chamon, Claudio, Hamma, Alioscia, and Mucciolo, Eduardo R.

Subjects

*EXCITED states, *ENERGY levels (Quantum mechanics), *EXCITED state energies, *RESONANT states, *QUANTUM theory

Abstract

We study the entanglement spectrum of highly excited eigenstates of two known models that exhibit a many-body localization transition, namely the one-dimensional random-field Heisenberg model and the quantum random energy model. Our results indicate that the entanglement spectrum shows a "two-component" structure: a universal part that is associated with random matrix theory, and a nonuniversal part that is model dependent. The nonuniversal part manifests the deviation of the highly excited eigenstate from a true random state even in the thermalized phase where the eigenstate thermalization hypothesis holds. The fraction of the spectrum containing the universal part decreases as one approaches the critical point and vanishes in the localized phase in the thermodynamic limit. We use the universal part fraction to construct an order parameter for measuring the degree of randomness of a generic highly excited state, which is also a promising candidate for studying the many-body localization transition. Two toy models based on Rokhsar-Kivelson type wave functions are constructed and their entanglement spectra are shown to exhibit the same structure. [ABSTRACT FROM AUTHOR]

Published

2015

21. Optimal Correlations in Many-Body Quantum Systems.

Author

Amico, L., Rossini, D., Hamma, A., and Korepin, V. E.

Subjects

*MANY-body problem, *QUANTUM theory, *PHYSICAL measurements, *PERFORMANCE evaluation, *COHERENCE (Physics), *STATISTICAL correlation

Abstract

Information and correlations in a quantum system are closely related through the process of measurement. We explore such relation in a many-body quantum setting, effectively bridging between quantum metrology and condensed matter physics. To this aim we adopt the information-theory view of correlations and study the amount of correlations after certain classes of positive-operator-valued measurements are locally performed. As many-body systems, we consider a one-dimensional array of interacting two-level systems (a spin chain) at zero temperature, where quantum effects are most pronounced. We demonstrate how the optimal strategy to extract the correlations depends on the quantum phase through a subtle interplay between local interactions and coherence. [ABSTRACT FROM AUTHOR]

Published

2012

22. Stabilizer Rényi Entropy.

Author

Leone, Lorenzo, Oliviero, Salvatore F. E., and Hamma, Alioscia

Subjects

*RENYI'S entropy, *QUANTUM states, *DISTRIBUTION (Probability theory), *STATISTICAL correlation, *MAGIC squares, *QUANTUM information theory

Abstract

We introduce a novel measure for the quantum property of "nonstabilizerness"--commonly known as "magic"--by considering the Rényi entropy of the probability distribution associated to a pure quantum state given by the square of the expectation value of Pauli strings in that state. We show that this is a good measure of nonstabilizerness from the point of view of resource theory and show bounds with other known measures. The stabilizer Rényi entropy has the advantage of being easily computable because it does not need a minimization procedure. We present a protocol for an experimental measurement by randomized measurements. We show that the nonstabilizerness is intimately connected to out-of-time-order correlation functions and that maximal levels of nonstabilizerness are necessary for quantum chaos. [ABSTRACT FROM AUTHOR]

Published

2022

23. Universality and robustness of revivals in the transverse field XY model.

Author

Häppölä, Juho, Halász, Gábor B., and Hamma, Alioscia

Subjects

*MATHEMATICAL models, *ROBUST control, *QUANTUM theory, *MANY-body problem, *MAGNETIZATION, *QUANTUM entanglement, *ENTROPY, *MAXIMAL functions, *QUASIPARTICLES

Abstract

We study the structure of the revivals in an integrable quantum many-body system, the transverse field AT spin chain, after a quantum quench. The time evolutions of the Loschmidt echo, the magnetization, and the single-spin entanglement entropy are calculated. We find that the revival times for all of these observables are given by integer multiples of Trev ≃ L/νmax, where L is the linear size of the system and umax is the maximal group velocity of quasiparticles. This revival structure is universal in the sense that it does not depend on the initial state and the size of the quench. Applying nonintegrable perturbations to the XY model, we observe that the revivals are robust against such perturbations: they are still visible at time scales much larger than the quasiparticle lifetime. We therefore propose a generic connection between the revival structure and the locality of the dynamics, where the quasiparticle speed umax generalizes into the Lieb-Robinson speed νLR [ABSTRACT FROM AUTHOR]

Published

2012

24. Local characterization of one-dimensional topologically ordered states.

Author

Jian Cui, Amico, Luigi, Heng Fan, Gu, Mile, Hamma, Alioscia, and Vedral, Vlatko

Subjects

*HAMILTONIAN systems, *HAMILTONIAN mechanics, *HAMILTON-Jacobi equations, *QUANTUM Hall effect, *ISING model

Abstract

We consider one-dimensional Hamiltonian systems whose ground states display symmetry-protected topological order. We show that ground states within the topological phase cannot be connected with each other through local operations and classical communication between a bipartition of the system. Our claim is demonstrated by analyzing the entanglement spectrum and Rényi entropies of different physical systems that provide examples for symmetry-protected topological phases. Specifically, we consider the spin-1/2 cluster-Ising model and a class of spin-1 models undergoing quantum phase transitions to the Haldane phase. Our results provide a probe for symmetry-protected topological order. Since the picture holds even at the system's local scale, our analysis can serve as a local experimental test for topological order. [ABSTRACT FROM AUTHOR]

Published

2013

25. Unscrambling Quantum Information with Clifford Decoders.

Author

Oliviero SFE, Leone L, Lloyd S, and Hamma A

Abstract

Quantum information scrambling is a unitary process that destroys local correlations and spreads information throughout the system, effectively hiding it in nonlocal degrees of freedom. In principle, unscrambling this information is possible with perfect knowledge of the unitary dynamics [B. Yoshida and A. Kitaev, arXiv:1710.03363.]. However, this Letter demonstrates that even without previous knowledge of the internal dynamics, information can be efficiently decoded from an unknown scrambler by monitoring the outgoing information of a local subsystem. We show that rapidly mixing but not fully chaotic scramblers can be decoded using Clifford decoders. The essential properties of a scrambling unitary can be efficiently recovered, even if the process is exponentially complex. Specifically, we establish that a unitary operator composed of t non-Clifford gates admits a Clifford decoder up to t≤n.

Published

2024

26. Two-Component Structure in the Entanglement Spectrum of Highly Excited States.

Author

Yang ZC, Chamon C, Hamma A, and Mucciolo ER

Abstract

We study the entanglement spectrum of highly excited eigenstates of two known models that exhibit a many-body localization transition, namely the one-dimensional random-field Heisenberg model and the quantum random energy model. Our results indicate that the entanglement spectrum shows a "two-component" structure: a universal part that is associated with random matrix theory, and a nonuniversal part that is model dependent. The nonuniversal part manifests the deviation of the highly excited eigenstate from a true random state even in the thermalized phase where the eigenstate thermalization hypothesis holds. The fraction of the spectrum containing the universal part decreases as one approaches the critical point and vanishes in the localized phase in the thermodynamic limit. We use the universal part fraction to construct an order parameter for measuring the degree of randomness of a generic highly excited state, which is also a promising candidate for studying the many-body localization transition. Two toy models based on Rokhsar-Kivelson type wave functions are constructed and their entanglement spectra are shown to exhibit the same structure.

Published

2015

27. Topological entanglement Rényi entropy and reduced density matrix structure.

Author

Flammia ST, Hamma A, Hughes TL, and Wen XG

Abstract

We generalize the topological entanglement entropy to a family of topological Rényi entropies parametrized by a parameter alpha, in an attempt to find new invariants for distinguishing topologically ordered phases. We show that, surprisingly, all topological Rényi entropies are the same, independent of alpha for all nonchiral topological phases. This independence shows that topologically ordered ground-state wave functions have reduced density matrices with a certain simple structure, and no additional universal information can be extracted from the entanglement spectrum.

Published

2009

28. Quantum adiabatic brachistochrone.

Author

Rezakhani AT, Kuo WJ, Hamma A, Lidar DA, and Zanardi P

Abstract

We formulate a time-optimal approach to adiabatic quantum computation (AQC). A corresponding natural Riemannian metric is also derived, through which AQC can be understood as the problem of finding a geodesic on the manifold of control parameters. This geometrization of AQC is demonstrated through two examples, where we show that it leads to improved performance of AQC, and sheds light on the roles of entanglement and curvature of the control manifold in algorithmic performance.

Published

2009

29. Lieb-Robinson bounds and the speed of light from topological order.

Author

Hamma A, Markopoulou F, Prémont-Schwarz I, and Severini S

Abstract

We apply the Lieb-Robinson bounds technique to find the maximum speed of interaction in a spin model with topological order whose low-energy effective theory describes light [see X.-G. Wen, Phys. Rev. B 68, 115413 (2003)10.1103/PhysRevB.68.115413]. The maximum speed of interactions in two dimensions is bounded from above by less than e times the speed of emerging light, giving a strong indication that light is indeed the maximum speed of interactions. This result does not rely on mean field theoretic methods. In higher spatial dimensions, the Lieb-Robinson speed is conjectured to increase linearly with the dimension itself. The implications for the horizon problem in cosmology are discussed.

Published

2009

30. Adiabatic preparation of topological order.

Author

Hamma A and Lidar DA

Abstract

Topological order characterizes those phases of matter that defy a description in terms of symmetry and cannot be distinguished in terms of local order parameters. Here we show that a system of n spins forming a lattice on a Riemann surface can undergo a second order quantum phase transition between a spin-polarized phase and a string-net condensed phase. This is an example of a quantum phase transition between magnetic and topological order. We furthermore show how to prepare the topologically ordered phase through adiabatic evolution in a time that is upper bounded by O(sqrt[n]). This provides a physically plausible method for constructing and initializing a topological quantum memory.

Published

2008