Your search keyword '"Calabrese, Pasquale"' showing total 61 results

1. The entanglement entropy of one-dimensional gases

Author

Calabrese, Pasquale, Mintchev, Mihail, Vicari, Ettore, Calabrese, Pasquale, Mintchev, Mihail, and Vicari, Ettore

Abstract

We introduce a systematic framework to calculate the bipartite entanglement entropy of a spatial subsystem in a one-dimensional quantum gas which can be mapped into a noninteracting fermion system. To show the wide range of applicability of the proposed formalism, we use it for the calculation of the entanglement in the eigenstates of periodic systems, in a gas confined by boundaries or external potentials, in junctions of quantum wires and in a time-dependent parabolic potential.

Published

2011

2. Static and dynamic structure factors in three-dimensional randomly diluted Ising models

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We consider the three-dimensional randomly diluted Ising model and study the critical behavior of the static and dynamic spin-spin correlation functions (static and dynamic structure factors) at the paramagnetic-ferromagnetic transition in the high-temperature phase. We consider a purely relaxational dynamics without conservation laws, the so-called model A. We present Monte Carlo simulations and perturbative field-theoretical calculations. While the critical behavior of the static structure factor is quite similar to that occurring in pure Ising systems, the dynamic structure factor shows a substantially different critical behavior. In particular, the dynamic correlation function shows a large-time decay rate which is momentum independent. This effect is not related to the presence of the Griffiths tail, which is expected to be irrelevant in the critical limit, but rather to the breaking of translational invariance, which occurs for any sample and which, at the critical point, is not recovered even after the disorder average.

Published

2008

3. Critical behavior of O(2)xO(N) symmetric models

Author

Calabrese, Pasquale, Parruccini, Pietro, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Parruccini, Pietro, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We investigate the controversial issue of the existence of universality classes describing critical phenomena in three-dimensional statistical systems characterized by a matrix order parameter with symmetry O(2)xO(N) and symmetry-breaking pattern O(2)xO(N) -> O(2)xO(N-2). Physical realizations of these systems are, for example, frustrated spin models with noncollinear order. Starting from the field-theoretical Landau-Ginzburg-Wilson Hamiltonian, we consider the massless critical theory and the minimal-subtraction scheme without epsilon expansion. The three-dimensional analysis of the corresponding five-loop expansions shows the existence of a stable fixed point for N=2 and N=3, confirming recent field-theoretical results based on a six-loop expansion in the alternative zero-momentum renormalization scheme defined in the massive disordered phase. In addition, we report numerical Monte Carlo simulations of a class of three-dimensional O(2)xO(2)-symmetric lattice models. The results provide further support to the existence of the O(2)xO(2) universality class predicted by the field-theoretical analyses.

Published

2004

4. Spin models with random anisotropy and reflection symmetry

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We study the critical behavior of a general class of cubic-symmetric spin systems in which disorder preserves the reflection symmetry $s_a\to -s_a$, $s_b\to s_b$ for $b\not= a$. This includes spin models in the presence of random cubic-symmetric anisotropy with probability distribution vanishing outside the lattice axes. Using nonperturbative arguments we show the existence of a stable fixed point corresponding to the random-exchange Ising universality class. The field-theoretical renormalization-group flow is investigated in the framework of a fixed-dimension expansion in powers of appropriate quartic couplings, computing the corresponding $\beta$-functions to five loops. This analysis shows that the random Ising fixed point is the only stable fixed point that is accessible from the relevant parameter region. Therefore, if the system undergoes a continuous transition, it belongs to the random-exchange Ising universality class. The approach to the asymptotic critical behavior is controlled by scaling corrections with exponent $\Delta = - \alpha_r$, where $\alpha_r\simeq -0.05$ is the specific-heat exponent of the random-exchange Ising model.

Published

2004

5. Crossover behavior in three-dimensional dilute spin systems

Author

Calabrese, Pasquale, Parruccini, Pietro, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Parruccini, Pietro, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We study the crossover behaviors that can be observed in the high-temperature phase of three-dimensional dilute spin systems, using a field-theoretical approach. In particular, for randomly dilute Ising systems we consider the Gaussian-to-random and the pure-Ising-to-random crossover, determining the corresponding crossover functions for the magnetic susceptibility and the correlation length. Moreover, for the physically interesting cases of dilute Ising, XY, and Heisenberg systems, we estimate several universal ratios of scaling-correction amplitudes entering the high-temperature Wegner expansion of the magnetic susceptibility, of the correlation length, and of the zero-momentum quartic couplings.

Published

2004

6. Crossover from random-exchange to random-field critical behavior in Ising models

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We compute the crossover exponent $\phi$ describing the crossover from the random-exchange to the random-field critical behavior in Ising systems. For this purpose, we consider the field-theoretical approach based on the replica method, and perform a six-loop calculation in the framework of a fixed-dimension expansion. The crossover from random-exchange to random-field critical behavior has been observed in dilute anisotropic antiferromagnets, such as Fe$_x$Zn$_{1-x}$F$_2$ and Mn$_x$Zn$_{1-x}$F$_2$, when applying an external magnetic field. Our result $\phi=1.42(2)$ for the crossover exponent is in good agreement with the available experimental estimates.

Published

2003

7. Multicritical phenomena in O(n_1)+O(n_2)-symmetric theories

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We study the multicritical behavior arising from the competition of two distinct types of ordering characterized by O(n) symmetries. For this purpose, we consider the renormalization-group flow for the most general $O(n_1)\oplus O(n_2)$-symmetric Landau-Ginzburg-Wilson Hamiltonian involving two fields $\phi_1$ and $\phi_2$ with $n_1$ and $n_2$ components respectively. In particular, we determine in which cases, approaching the multicritical point, one may observe the asymptotic enlargement of the symmetry to O(N) with N=n_1+n_2. By performing a five-loop $\epsilon$-expansion computation we determine the fixed points and their stability. It turns out that for N=n_1+n_2\ge 3 the O(N)-symmetric fixed point is unstable. For N=3, the multicritical behavior is described by the biconal fixed point with critical exponents that are very close to the Heisenberg ones. For N\ge 4 and any n_1,n_2 the critical behavior is controlled by the tetracritical decoupled fixed point. We discuss the relevance of these results for some physically interesting systems, in particular for anisotropic antiferromagnets in the presence of a magnetic field and for high-T_c superconductors. Concerning the SO(5) theory of superconductivity, we show that the bicritical O(5) fixed point is unstable with a significant crossover exponent, $\phi_{4,4}\approx 0.15$; this implies that the O(5) symmetry is not effectively realized at the point where the antiferromagnetic and superconducting transition lines meet. The multicritical behavior is either governed by the tetracritical decoupled fixed point or is of first-order type if the system is outside its attraction domain.

Published

2003

8. Randomly dilute spin models with cubic symmetry

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We study the combined effect of cubic anisotropy and quenched uncorrelated impurities on multicomponent spin models. For this purpose, we consider the field-theoretical approach based on the Ginzburg-Landau-Wilson $\phi^4$ Hamiltonian with cubic-symmetric quartic interactions and quenched randomness coupled to the local energy density. We compute the renormalization-group functions to six loops in the fixed-dimension (d=3) perturbative scheme. The analysis of such high-order series provides an accurate description of the renormalization-group flow. The results are also used to determine the critical behavior of three-dimensional antiferromagnetic three- and four-state Potts models in the presence of quenched impurities.

Published

2003

9. Critical structure factors of bilinear fields in O(N)-vector models

Author

Calabrese, Pasquale, Pelissetto, Andrea, Vicari, Ettore, Calabrese, Pasquale, Pelissetto, Andrea, and Vicari, Ettore

Abstract

We compute the two-point correlation functions of general quadratic operators in the high-temperature phase of the three-dimensional O(N) vector model by using field-theoretical methods. In particular, we study the small- and large-momentum behavior of the corresponding scaling functions, and give general interpolation formulae based on a dispersive approach. Moreover, we determine the crossover exponent $\phi_T$ associated with the traceless tensorial quadratic field, by computing and analyzing its six-loop perturbative expansion in fixed dimension. We find: $\phi_T=1.184(12)$, $\phi_T=1.271(21)$, and $\phi_T=1.40(4)$ for $N=2,3,5$ respectively.

Published

2002

10. Quantum quench within the gapless phase of the spin-½ Heisenberg XXZ spin chain.

Author

Collura, Mario, Calabrese, Pasquale, and Essler, Fabian H. L.

Subjects

*HEISENBERG model, *PAULI spin operators, *LUTTINGER liquids, *CONDENSED matter, *THERMODYNAMIC functions, *QUANTUM chemistry

Abstract

We consider an interaction quench in the critical spin-½ Heisenberg XXZ chain. We numerically compute the time evolution of the two-point correlation functions of spin operators in the thermodynamic limit and compare the results to predictions obtained in the framework of the Luttinger liquid approximation. We find that the transverse correlation function 〈SxjSxj+ℓ〉 agrees with the Luttinger model prediction to a surprising level of accuracy. The agreement for the longitudinal two-point function 〈SejSej+ℓ〉 is found to be much poorer. We speculate that this difference between transverse and longitudinal correlations has its origin in the locality properties of the respective spin operator with respect to the underlying fermionic modes. [ABSTRACT FROM AUTHOR]

Published

2015

11. Entanglement Negativity in Quantum Field Theory.

Author

Calabrese, Pasquale, Cardy, John, and Tonni, Erik

Subjects

*QUANTUM entanglement, *QUANTUM field theory, *GROUND state (Quantum mechanics), *DIMENSIONAL analysis, *NUMERICAL analysis, *PATH integrals, *DENSITY matrices

Abstract

We develop a systematic method to extract the negativity in the ground state of a 1 + 1 dimensional relativistic quantum field theory, using a path integral formalism to construct the partial transpose ρT2A of the reduced density matrix of a subsystem A = A1 U A2, and introducing a replica approach to obtain its trace norm which gives the logarithmic negativity ε = ln||ρT2A||- This is shown to reproduce standard results for a pure state. We then apply this method to conformai field theories, deriving the result ε ~ (c/4) ln[ℓ1]ℓ2/(ℓ1 + ℓ2)] for the case of two adjacent intervals of lengths ℓ1,ℓ2 in an infinite system, where c is the central charge. For two disjoint intervals it depends only on the harmonic ratio of the four end points and so is manifestly scale invariant. We check our findings against exact numerical results in the harmonic chain. [ABSTRACT FROM AUTHOR]

Published

2012

12. Entanglement spectrum of random-singlet quantum critical points.

Author

Fagotti, Maurizio, Calabrese, Pasquale, and Moore, Joel E.

Subjects

*ERGODIC theory, *EIGENVALUES, *ENTROPY, *QUANTUM entropy, *HEISENBERG uncertainty principle, *HILBERT space

Abstract

The entanglement spectrum (i.e., the full distribution of Schmidt eigenvalues of the reduced density matrix) contains more information than the conventional entanglement entropy and has been studied recently in several many-particle systems. We compute the disorder-averaged entanglement spectrum in the form of the disorder-averaged moments ¯TrρAα of the reduced density matrix ρA for a contiguous block of many spins at the random-singlet quantum critical point in one dimension. The result compares well in the scaling limit with numerical studies on the random XX model and is also expected to describe the (interacting) random Heisenberg model. Our numerical studies on the XX case reveal that the dependence of the entanglement entropy and spectrum on the geometry of the Hilbert space partition is quite different than for conformally invariant critical points. [ABSTRACT FROM AUTHOR]

Published

2011

13. Random matrices and entanglement entropy of trapped Fermi gases.

Author

Calabrese, Pasquale, Le Doussal, Pierre, and Majumdar, Satya N.

Subjects

*RANDOM matrices, *ELECTRON gas, *QUANTUM entanglement, *ENTROPY, *QUANTUM mechanics

Abstract

We exploit and clarify the use of random matrix theory for the calculation of the entanglement entropy of free Fermi gases. We apply this method to obtain analytic predictions for Rényi entanglement entropies of a one-dimensional gas trapped by a harmonic potential in all the relevant scaling regimes. We confirm our findings with accurate numerical calculations obtained by means of an ingenious discretization of the reduced correlation matrix. [ABSTRACT FROM AUTHOR]

Published

2015

14. Quantum Generalized Hydrodynamics.

Author

Ruggiero, Paola, Calabrese, Pasquale, Doyon, Benjamin, and Dubail, Jérôme

Subjects

*HYDRODYNAMICS, *QUANTUM fluctuations, *QUANTUM theory, *EULER equations, *LUTTINGER liquids

Abstract

Physical systems made of many interacting quantum particles can often be described by Euler hydrodynamic equations in the limit of long wavelengths and low frequencies. Recently such a classical hydrodynamic framework, now dubbed generalized hydrodynamics (GHD), was found for quantum integrable models in one spatial dimension. Despite its great predictive power, GHD, like any Euler hydrodynamic equation, misses important quantum effects, such as quantum fluctuations leading to nonzero equal-time correlations between fluid cells at different positions. Focusing on the one-dimensional gas of bosons with delta repulsion, and on states of zero entropy, for which quantum fluctuations are larger, we reconstruct such quantum effects by quantizing GHD. The resulting theory of quantum GHD can be viewed as a multicomponent Luttinger liquid theory, with a small set of effective parameters that are fixed by the thermodynamic Bethe ansatz. It describes quantum fluctuations of truly nonequilibrium systems where conventional Luttinger liquid theory fails. [ABSTRACT FROM AUTHOR]

Published

2020

15. Quench action and Rényi entropies in integrable systems.

Author

Alba, Vincenzo and Calabrese, Pasquale

Subjects

*RENYI'S entropy, *EQUILIBRIUM, *MECHANICS (Physics)

Abstract

Entropy is a fundamental concept in equilibrium statistical mechanics, yet its origin in the nonequilibrium dynamics of isolated quantum systems is not fully understood. A strong consensus is emerging around the idea that the stationary thermodynamic entropy is the von Neumann entanglement entropy of a large subsystem embedded in an infinite system. Also motivated by cold-atom experiments, here we consider the generalization to Rényi entropies. We develop a new technique to calculate the diagonal Rényi entropy in the quench action formalism. In the spirit of the replica treatment for the entanglement entropy, the diagonal Rényi entropies are generalized free energies evaluated over a thermodynamic macrostate which depends on the Rényi index and, in particular, is not the same state describing von Neumann entropy. The technical reason for this perhaps surprising result is that the evaluation of the moments of the diagonal density matrix shifts the saddle point of the quench action. An interesting consequence is that different Rényi entropies encode information about different regions of the spectrum of the postquench Hamiltonian. Our approach provides a very simple proof of the long-standing issue that, for integrable systems, the diagonal entropy is half of the thermodynamic one and it allows us to generalize this result to the case of arbitrary Rényi entropy. [ABSTRACT FROM AUTHOR]

Published

2017

16. Multiparticle Bound-State Formation following a Quantum Quench to the One-Dimensional Bose Gas with Attractive Interactions.

Author

Piroli, Lorenzo, Calabrese, Pasquale, and Essler, Fabian H. L.

Subjects

*BOUND states, *BOSE-Einstein gas, *PARTICLE interactions

Abstract

We consider quantum quenches from an ideal Bose condensate to the Lieb-Liniger model with an arbitrary attractive interaction strength. We focus on the properties of the stationary state reached at late times after the quench. Using recently developed methods based on integrability, we obtain an exact description of the stationary state for a large number of bosons. A distinctive feature of this state is the presence of a hierarchy of multiparticle bound states. We determine the dependence of their densities on interaction strength and obtain an exact expression for the stationary value of the local pair correlation g2. We discuss ramifications of our results for cold atom experiments. [ABSTRACT FROM AUTHOR]

Published

2016

17. Exact dynamics following an interaction quench in a one-dimensional anyonic gas.

Author

Piroli, Lorenzo and Calabrese, Pasquale

Subjects

*DENSITY matrices, *DYNAMICS, *FERMIONS

Abstract

We study the nonequilibrium quench dynamics of a one-dimensional anyonic gas. We focus on the integrable anyonic Lieb-Liniger model and consider the quench from noninteracting to hard-core anyons. We study the dynamics of the local properties of the system. By means of integrability-based methods, we compute analytically the one-body density matrix and the density-density correlation function at all times after the quench and in particular at infinite time. Our results show that the system evolves from an initial state where the local momentum distribution function is nonsymmetric to a steady state where it becomes symmetric. Furthermore, while the initial momentum distribution functions (and the equilibrium ones) explicitly depend on the anyonic parameter, the final ones do not. This is reminiscent of the dynamical fermionization observed in the context of free expansions after release from a confining trap. [ABSTRACT FROM AUTHOR]

Published

2017

18. Local correlations in the attractive one-dimensional Bose gas: From Bethe ansatz to the Gross-Pitaevskii equation.

Author

Piroli, Lorenzo and Calabrese, Pasquale

Subjects

*BOSE-Einstein gas, *GROSS-Pitaevskii equations, *BETHE-ansatz technique, *GROUND state (Quantum mechanics)

Abstract

We consider the ground-state properties of an extended one-dimensional Bose gas with pointwise attractive interactions. We take the limit where the interaction strength goes to zero as the system size increases at fixed particle density. In this limit, the gas exhibits a quantum phase transition. We compute local correlation functions at zero temperature, both at finite and infinite size. We provide analytic formulas for the experimentally relevant one-point functions g2,g3 and analyze their finite-size corrections. Our results are compared to the mean-field approach based on the Gross-Pitaevskii equation which yields the exact results in the infinite system size limit, but not for finite systems. [ABSTRACT FROM AUTHOR]

Published

2016

19. Equilibration of a Tonks-Girardeau Gas Following a Trap Release.

Author

Collura, Mario, Sotiriadis, Spyros, and Calabrese, Pasquale

Subjects

*NONEQUILIBRIUM thermodynamics, *EQUILIBRIUM, *GAS research, *THERMODYNAMIC equilibrium, *DENSITY matrices

Abstract

We study the nonequilibrium dynamics of a Tonks-Girardeau gas released from a parabolic trap to a circle. We present the exact analytic solution of the many body dynamics and prove that, for large times and in a properly defined thermodynamic limit, the reduced density matrix of any finite subsystem converges to a generalized Gibbs ensemble. The equilibration mechanism is expected to be the same for all one-dimensional systems. [ABSTRACT FROM AUTHOR]

Published

2013

20. Analytic results for a quantum quench from free to hard-core one-dimensional bosons.

Author

Kormos, Márton, Collura, Mario, and Calabrese, Pasquale

Subjects

*QUANTUM theory, *BOSONS, *STATIONARY processes, *CANONICAL ensemble, *BOSE-Einstein gas, *NUCLEAR density

Abstract

It is widely believed that the stationary properties after a quantum quench in integrable systems can be described by a generalized Gibbs ensemble (GGE), even if all of the analytical evidence is based on free theories in which the pre- and postquench modes are linearly related. In contrast, we consider the experimentally relevant quench of the one-dimensional Bose gas from zero to infinite interaction, in which the relation between modes is nonlinear, and consequently Wick's theorem does not hold. We provide exact analytical results for the time evolution of the dynamical density-density correlation function at any time after the quench and we prove that its stationary value is described by a GGE in which Wick's theorem is restored. [ABSTRACT FROM AUTHOR]

Published

2014

21. Subsystem Trace Distance in Quantum Field Theory.

Author

Jiaju Zhang, Ruggiero, Paola, and Calabrese, Pasquale

Subjects

*QUANTUM field theory, *OPERATOR product expansions, *DENSITY matrices, *CONFORMAL field theory, *DISTANCES, *INTEGRAL representations

Abstract

We develop a systematic method to calculate the trace distance between two reduced density matrices in 1+1 dimensional quantum field theories. The approach exploits the path integral representation of the reduced density matrices and an ad hoc replica trick. We then extensively apply this method to the calculation of the distance between reduced density matrices of one interval of length l in eigenstates of conformal field theories. When the interval is short, using the operator product expansion of twist operators, we obtain a universal form for the leading order in l of the trace distance. We compute the trace distances among the reduced density matrices of several low lying states in two-dimensional free massless boson and fermion theories. We compare our analytic conformal results with numerical calculations in XX and Ising spin chains finding perfect agreement. [ABSTRACT FROM AUTHOR]

Published

2019

22. Exact Local Correlations and Full Counting Statistics for Arbitrary States of the One-Dimensional Interacting Bose Gas.

Author

Bastianello, Alvise, Piroli, Lorenzo, and Calabrese, Pasquale

Subjects

*BOSE-Einstein gas, *STATISTICS, *QUANTUM mechanics

Abstract

We derive exact analytic expressions for the n-body local correlations in the one-dimensional Bose gas with contact repulsive interactions (Lieb-Liniger model) in the thermodynamic limit. Our results are valid for arbitrary states of the model, including ground and thermal states, stationary states after a quantum quench, and nonequilibrium steady states arising in transport settings. Calculations for these states are explicitly presented and physical consequences are critically discussed. We also show that the n-body local correlations are directly related to the full counting statistics for the particle-number fluctuations in a short interval, for which we provide an explicit analytic result. [ABSTRACT FROM AUTHOR]

Published

2018

23. Universal Broadening of the Light Cone in Low-Temperature Transport.

Author

Bertini, Bruno, Piroli, Lorenzo, and Calabrese, Pasquale

Subjects

*LIGHT cones, *LUTTINGER liquids, *CONFORMAL field theory

Abstract

We consider the low-temperature transport properties of critical one-dimensional systems that can be described, at equilibrium, by a Luttinger liquid. We focus on the prototypical setting where two semi-infinite chains are prepared in two thermal states at small but different temperatures and suddenly joined together. At large distances x and times t, conformal field theory characterizes the energy transport in terms of a single light cone spreading at the sound velocity v. Energy density and current take different constant values inside the light cone, on its left, and on its right, resulting in a three-step form of the corresponding profiles as a function of ζ=x/t. Here, using a nonlinear Luttinger liquid description, we show that for generic observables this picture is spoiled as soon as a nonlinearity in the spectrum is present. In correspondence of the transition points x/t=±v, a novel universal region emerges at infinite times, whose width is proportional to the temperatures on the two sides. In this region, expectation values have a different temperature dependence and show smooth peaks as a function of ζ. We explicitly compute the universal function describing such peaks. In the specific case of interacting integrable models, our predictions are analytically recovered by the generalized hydrodynamic approach. [ABSTRACT FROM AUTHOR]

Published

2018

24. Correlations and diagonal entropy after quantum quenches in XXZ chains.

Author

Piroli, Lorenzo, Vernier, Eric, Calabrese, Pasquale, and Rigol, Marcos

Subjects

*ENTROPY, *HEISENBERG model, *FERROMAGNETIC materials

Abstract

We study quantum quenches in the XXZ spin-1/2 Heisenberg chain from families of ferromagnetic and antiferromagnetic initial states. Using Bethe ansatz techniques, we compute short-range correlators in the complete generalized Gibbs ensemble (GGE), which takes into account all local and quasilocal conservation laws. We compare our results to exact diagonalization and numerical linked cluster expansion calculations for the diagonal ensemble, finding excellent agreement and thus providing a very accurate test for the validity of the complete GGE. Furthermore, we use exact diagonalization to compute the diagonal entropy in the postquench steady state. We show that the Yang-Yang entropy for the complete GGE is consistent with twice the value of the diagonal entropy in the largest chains or the extrapolated result in the thermodynamic limit. Finally, the complete GGE is quantitatively contrasted with the GGE built using only the local conserved charges (local GGE). The predictions of the two ensembles are found to differ significantly in the case of ferromagnetic initial states. Such initial states are better suited than others considered in the literature to experimentally test the validity of the complete GGE and contrast it to the failure of the local GGE. [ABSTRACT FROM AUTHOR]

Published

2017

25. Negativity spectrum of one-dimensional conformal field theories.

Author

Ruggiero, Paola, Alba, Vincenzo, and Calabrese, Pasquale

Subjects

*CONFORMAL field theory, *DENSITY matrices, *SPECTRUM analysis

Abstract

The partial transpose ρAT2 of the reduced density matrix ρA is the key object to quantify the entanglement in mixed states, in particular through the presence of negative eigenvalues in its spectrum. Here we derive analytically the distribution of the eigenvalues of ρAT2, which we dub negativity spectrum, in the ground state of gapless one-dimensional systems described by a conformal field theory (CFT), focusing on the case of two adjacent intervals. We show that the negativity spectrum is universal and depends only on the central charge of the CFT, similarly to the entanglement spectrum. The precise form of the negativity spectrum depends on whether the two intervals are in a pure or mixed state, and in both cases, a dependence on the sign of the eigenvalues is found. This dependence is weak for bulk eigenvalues, whereas it is strong at the spectrum edges. We also investigate the scaling of the smallest (negative) and largest (positive) eigenvalues of ρAT2. We check our results against DMRG simulations for the critical Ising and Heisenberg chains, and against exact results for the harmonic chain, finding good agreement for the spectrum, but showing that the smallest eigenvalue is affected by very large scaling corrections. [ABSTRACT FROM AUTHOR]

Published

2016

26. Exact steady states for quantum quenches in integrable Heisenberg spin chains.

Author

Piroli, Lorenzo, Vernier, Eric, and Calabrese, Pasquale

Subjects

*HEISENBERG model, *NONEQUILIBRIUM thermodynamics, *QUANTUM mechanics

Abstract

The study of quantum quenches in integrable systems has significantly advanced with the introduction of the quench action method, a versatile analytical approach to nonequilibrium dynamics. However, its application is limited to those cases where the overlaps between the initial state and the eigenstates of the Hamiltonian governing the time evolution are known exactly. Conversely, in this work we consider physically interesting initial states for which such overlaps are still unknown. In particular, we focus on different classes of product states in spin-1/2 and spin-1 integrable chains, such as tilted ferromagnets and antiferromagnets. We get around the missing overlaps by following a recent approach based on the knowledge of complete sets of quasilocal charges. This allows us to provide a closed-form analytical characterization of the effective stationary state reached at long times after the quench, through the Bethe ansatz distributions of particles and holes. We compute the asymptotic value of local correlations and check our predictions against numerical data. [ABSTRACT FROM AUTHOR]

Published

2016

27. Entanglement negativity in random spin chains.

Author

Ruggiero, Paola, Alba, Vincenzo, and Calabrese, Pasquale

Subjects

*QUANTUM entanglement, *RENORMALIZATION group, *SPIN-spin interactions

Abstract

We investigate the logarithmic negativity in strongly disordered spin chains in the random-singlet phase. We focus on the spin-½ random Heisenberg chain and the random XX chain. We find that for two arbitrary intervals, the disorder-averaged negativity and the mutual information are proportional to the number of singlets shared between the two intervals. Using the strong-disorder renormalization group (SDRG), we prove that the negativity of two adjacent intervals grows logarithmically with the intervals' length. In particular, the scaling behavior is the same as in conformal field theory, but with a different prefactor. For two disjoint intervals the negativity is given by a universal simple function of the cross ratio, reflecting scale invariance. As a function of the distance of the two intervals, the negativity decays algebraically in contrast with the exponential behavior in clean models. We confirm our predictions using a numerical implementation of the SDRG method. Finally, we also implement density matrix renormalization group simulations for the negativity in open spin chains. The chains accessible in the presence of strong disorder are not sufficiently long to provide a reliable confirmation of the SDRG results. [ABSTRACT FROM AUTHOR]

Published

2016

28. Relaxation after quantum quenches in the spin-½ Heisenberg XXZ chain.

Author

Fagotti, Maurizio, Collura, Mario, Essler, Fabian H. L., and Calabrese, Pasquale

Subjects

*ANISOTROPY, *CRYSTALLOGRAPHY, *PROPERTIES of matter, *HAMILTON'S equations, *EQUATIONS of motion, *HAMILTON'S principle function

Abstract

We consider the time evolution after quantum quenches in the spin- ½ Heisenberg XXZ quantum spin chain with Ising-type anisotropy. The time evolution of short-distance spin-spin correlation functions is studied by numerical tensor network techniques for a variety of initial states, including Néel and Majumdar-Ghosh states and the ground state of the XXZ chain at large values of the anisotropy. The various correlators appear to approach stationary values, which are found to be in good agreement with the results of exact calculations of stationary expectation values in appropriate generalized Gibbs ensembles. In particular, our analysis shows bow symmetries of the post-quench Hamiltonian that are broken by particular initial states are restored at late times. [ABSTRACT FROM AUTHOR]

Published

2014

29. Short-time growth of a Kardar-Parisi-Zhang interface with flat initial conditions.

Author

Gueudré, Thomas, Le Doussal, Pierre, Rosso, Alberto, Henry, Adrien, and Calabrese, Pasquale

Subjects

*INTERFACES (Physical sciences), *PARTITION functions, *POLYMERS, *CUMULANTS, *FIELD theory (Physics), *RANDOM noise theory, *DIFFUSION processes

Abstract

The short-time behavior of the (1 + l)-dimensional Kardar-Parisi-Zhang (KPZ) growth equation with a flat initial condition is obtained from the exact expressions for the moments of the partition function of a directed polymer with one end point free and the other fixed. From these expressions, the short-time expansions of the lowest cumulants of the KPZ height field are exactly derived. The results for these two classes of cumulants are checked in high-precision lattice numerical simulations. The short-time limit considered here is relevant for the study of the interface growth in the large-diffusivity or weak-noise limit and describes the universal crossover between the Edwards-Wilkinson and the KPZ universality classes for an initially flat interface. [ABSTRACT FROM AUTHOR]

Published

2012

30. Mixed-State Entanglement from Local Randomized Measurements.

Author

Elben, Andreas, Kueng, Richard, Hsin-Yuan (Robert) Huang, van Bijnen, Rick, Kokail, Christian, Dalmonte, Marcello, Calabrese, Pasquale, Kraus, Barbara, Preskill, John, Zoller, Peter, and Vermersch, Benoît

Subjects

*DENSITY matrices, *QUBITS, *MEASUREMENT

Abstract

We propose a method for detecting bipartite entanglement in a many-body mixed state based on estimating moments of the partially transposed density matrix. The estimates are obtained by performing local random measurements on the state, followed by postprocessing using the classical shadows framework. Our method can be applied to any quantum system with single-qubit control. We provide a detailed analysis of the required number of experimental runs, and demonstrate the protocol using existing experimental data [Brydges et al., Science 364, 260 (2019)]. [ABSTRACT FROM AUTHOR]

Published

2020

31. Observing the Quantum Mpemba Effect in Quantum Simulations.

Author

Joshi LK, Franke J, Rath A, Ares F, Murciano S, Kranzl F, Blatt R, Zoller P, Vermersch B, Calabrese P, Roos CF, and Joshi MK

Abstract

The nonequilibrium physics of many-body quantum systems harbors various unconventional phenomena. In this Letter, we experimentally investigate one of the most puzzling of these phenomena-the quantum Mpemba effect, where a tilted ferromagnet restores its symmetry more rapidly when it is farther from the symmetric state compared to when it is closer. We present the first experimental evidence of the occurrence of this effect in a trapped-ion quantum simulator. The symmetry breaking and restoration are monitored through entanglement asymmetry, probed via randomized measurements, and postprocessed using the classical shadows technique. Our findings are further substantiated by measuring the Frobenius distance between the experimental state and the stationary thermal symmetric theoretical state, offering direct evidence of subsystem thermalization.

Published

2024

32. Microscopic Origin of the Quantum Mpemba Effect in Integrable Systems.

Author

Rylands C, Klobas K, Ares F, Calabrese P, Murciano S, and Bertini B

Abstract

The highly complicated nature of far from equilibrium systems can lead to a complete breakdown of the physical intuition developed in equilibrium. A famous example of this is the Mpemba effect, which states that nonequilibrium states may relax faster when they are further from equilibrium or, put another way, hot water can freeze faster than warm water. Despite possessing a storied history, the precise criteria and mechanisms underpinning this phenomenon are still not known. Here, we study a quantum version of the Mpemba effect that takes place in closed many-body systems with a U(1) conserved charge: in certain cases a more asymmetric initial configuration relaxes and restores the symmetry faster than a more symmetric one. In contrast to the classical case, we establish the criteria for this to occur in arbitrary integrable quantum systems using the recently introduced entanglement asymmetry. We describe the quantum Mpemba effect in such systems and relate the properties of the initial state, specifically its charge fluctuations, to the criteria for its occurrence. These criteria are expounded using exact analytic and numerical techniques in several examples, a free fermion model, the Rule 54 cellular automaton, and the Lieb-Liniger model.

Published

2024

33. Transport and Entanglement across Integrable Impurities from Generalized Hydrodynamics.

Author

Rylands C and Calabrese P

Abstract

Quantum impurity models (QIMs) are ubiquitous throughout physics. As simplified toy models they provide crucial insights for understanding more complicated strongly correlated systems, while in their own right are accurate descriptions of many experimental platforms. In equilibrium, their physics is well understood and have proven a testing ground for many powerful theoretical tools, both numerical and analytical, in use today. Their nonequilibrium physics is much less studied and understood. However, the recent advancements in nonequilibrium integrable quantum systems through the development of generalized hydrodynamics (GHD) coupled with the fact that many archetypal QIMs are in fact integrable presents an enticing opportunity to enhance our understanding of these systems. We take a step towards this by expanding the framework of GHD to incorporate integrable interacting QIMs. We present a set of Bethe-Boltzmann type equations which incorporate the effects of impurity scattering and discuss the new aspects which include entropy production. These impurity GHD equations are then used to study a bipartioning quench wherein a relevant backscattering impurity is included at the location of the bipartition. The density and current profiles are studied as a function of the impurity strength and expressions for the entanglement entropy and full counting statistics are derived.

Published

2023

34. Nonequilibrium Full Counting Statistics and Symmetry-Resolved Entanglement from Space-Time Duality.

Author

Bertini B, Calabrese P, Collura M, Klobas K, and Rylands C

Abstract

Owing to its probabilistic nature, a measurement process in quantum mechanics produces a distribution of possible outcomes. This distribution-or its Fourier transform known as full counting statistics (FCS)-contains much more information than say the mean value of the measured observable, and accessing it is sometimes the only way to obtain relevant information about the system. In fact, the FCS is the limit of an even more general family of observables-the charged moments-that characterize how quantum entanglement is split in different symmetry sectors in the presence of a global symmetry. Here we consider the evolution of the FCS and of the charged moments of a U(1) charge truncated to a finite region after a global quantum quench. For large scales these quantities take a simple large-deviation form, showing two different regimes as functions of time: while for times much larger than the size of the region they approach a stationary value set by the local equilibrium state, for times shorter than region size they show a nontrivial dependence on time. We show that, whenever the initial state is also U(1) symmetric, the leading order in time of FCS and charged moments in the out-of-equilibrium regime can be determined by means of a space-time duality. Namely, it coincides with the stationary value in the system where the roles of time and space are exchanged. We use this observation to find some general properties of FCS and charged moments out of equilibrium, and to derive an exact expression for these quantities in interacting integrable models. We test this expression against exact results in the Rule 54 quantum cellular automaton and exact numerics in the XXZ spin-1/2 chain.

Published

2023

35. Solution of the BEC to BCS Quench in One Dimension.

Author

Rylands C, Calabrese P, and Bertini B

Abstract

A gas of interacting fermions confined in a quasi one-dimensional geometry shows a BEC to BCS crossover upon slowly driving its coupling constant through a confinement-induced resonance. On one side of the crossover the fermions form tightly bound bosonic molecules behaving as a repulsive Bose gas, while on the other they form Cooper pairs, whose size is much larger than the average interparticle distance. Here we consider the situation arising when the coupling constant is varied suddenly from the BEC to the BCS value. Namely, we study a BEC-to-BCS quench. By exploiting a suitable continuum limit of recently discovered solvable quenches in the Hubbard model, we show that the local stationary state reached at large times after the quench can be determined exactly by means of the quench action approach. We provide an experimentally accessible characterization of the stationary state by computing local pair correlation function as well as the quasiparticle distribution functions. We find that the steady state is increasingly dominated by two-particle spin singlet bound states for stronger interaction strength, but that bound state formation is inhibited at larger BEC density. The bound state rapidity distribution displays quartic power-law decay suggesting a violation of Tan's contact relations.

Published

2023

36. Postquantum Quench Growth of Renyi Entropies in Low-Dimensional Continuum Bosonic Systems.

Author

Murciano S, Calabrese P, and Konik RM

Abstract

The growth of Renyi entropies after the injection of energy into a correlated system provides a window upon the dynamics of its entanglement properties. We develop here a simulation scheme by which this growth can be determined in Luttinger liquids systems with arbitrary interactions, even those introducing gaps into the liquid. We apply this scheme to an experimentally relevant quench in the sine-Gordon field theory. While for short times we provide analytic expressions for the growth of the second and third Renyi entropy, to access longer times, we combine our scheme with truncated spectrum methods.

Published

2022

37. Negativity Hamiltonian: An Operator Characterization of Mixed-State Entanglement.

Author

Murciano S, Vitale V, Dalmonte M, and Calabrese P

Abstract

In the context of ground states of quantum many-body systems, the locality of entanglement between connected regions of space is directly tied to the locality of the corresponding entanglement Hamiltonian: the latter is dominated by local, few-body terms. In this work, we introduce the negativity Hamiltonian as the (non-Hermitian) effective Hamiltonian operator describing the logarithm of the partial transpose of a many-body system. This allows us to address the connection between entanglement and operator locality beyond the paradigm of bipartite pure systems. As a first step in this direction, we study the structure of the negativity Hamiltonian for fermionic conformal field theories and a free-fermion chain: in both cases, we show that the negativity Hamiltonian assumes a quasilocal functional form, that is captured by simple functional relations.

Published

2022

38. Shell-filling effect in the entanglement entropies of spinful fermions.

Author

Essler FH, Läuchli AM, and Calabrese P

Abstract

We consider the von Neumann and Rényi entropies of the one-dimensional quarter-filled Hubbard model. We observe that for periodic boundary conditions the entropies exhibit an unexpected dependence on system size: for L=4 mod 8 the results are in agreement with expectations based on conformal field theory, while for L=0 mod 8 additional contributions arise. We explain this observation in terms of a shell-filling effect and develop a conformal field theory approach to calculate the extra term in the entropies. Similar shell-filling effects in entanglement entropies are expected to be present in higher dimensions and for other multicomponent systems.

Published

2013

39. Entanglement entropy of one-dimensional gases.

Author

Calabrese P, Mintchev M, and Vicari E

Abstract

We introduce a systematic framework to calculate the bipartite entanglement entropy of a spatial subsystem in a one-dimensional quantum gas which can be mapped into a noninteracting fermion system. To show the wide range of applicability of the proposed formalism, we use it for the calculation of the entanglement in the eigenstates of periodic systems, in a gas confined by boundaries or external potentials, in junctions of quantum wires, and in a time-dependent parabolic potential.

Published

2011

40. Exact solution for the Kardar-Parisi-Zhang equation with flat initial conditions.

Author

Calabrese P and Le Doussal P

Abstract

We provide the first exact calculation of the height distribution at arbitrary time t of the continuum Kardar-Parisi-Zhang (KPZ) growth equation in one dimension with flat initial conditions. We use the mapping onto a directed polymer with one end fixed, one free, and the Bethe ansatz for the replicated attractive boson model. We obtain the generating function of the moments of the directed polymer partition sum as a Fredholm Pfaffian. Our formula, valid for all times, exhibits convergence of the free energy (i.e., KPZ height) distribution to the Gaussian orthogonal ensemble Tracy-Widom distribution at large time.

Published

2011

41. Quantum quench in the transverse-field Ising chain.

Author

Calabrese P, Essler FH, and Fagotti M

Abstract

We consider the time evolution of observables in the transverse-field Ising chain after a sudden quench of the magnetic field. We provide exact analytical results for the asymptotic time and distance dependence of one- and two-point correlation functions of the order parameter. We employ two complementary approaches based on asymptotic evaluations of determinants and form-factor sums. We prove that the stationary value of the two-point correlation function is not thermal, but can be described by a generalized Gibbs ensemble (GGE). The approach to the stationary state can also be understood in terms of a GGE. We present a conjecture on how these results generalize to particular quenches in other integrable models.

Published

2011

42. Parity effects in the scaling of block entanglement in gapless spin chains.

Author

Calabrese P, Campostrini M, Essler F, and Nienhuis B

Abstract

We consider the Rényi alpha entropies for Luttinger liquids (LL). For large block lengths l, these are known to grow like lnl. We show that there are subleading terms that oscillate with frequency 2k{F} (the Fermi wave number of the LL) and exhibit a universal power-law decay with l. The new critical exponent is equal to K/(2alpha), where K is the LL parameter. We present numerical results for the anisotropic XXZ model and the full analytic solution for the free fermion (XX) point.

Published

2010

43. Static and dynamic structure factors in three-dimensional randomly diluted Ising models.

Author

Calabrese P, Pelissetto A, and Vicari E

Abstract

We consider the three-dimensional randomly diluted Ising model and study the critical behavior of the static and dynamic spin-spin correlation functions (static and dynamic structure factors) at the paramagnetic-ferromagnetic transition in the high-temperature phase. We consider a purely relaxational dynamics without conservation laws, the so-called model A. We present Monte Carlo simulations and perturbative field-theoretical calculations. While the critical behavior of the static structure factor is quite similar to that occurring in pure Ising systems, the dynamic structure factor shows a substantially different critical behavior. In particular, the dynamic correlation function shows a large-time decay rate which is momentum independent. This effect is not related to the presence of the Griffiths tail, which is expected to be irrelevant in the critical limit, but rather to the breaking of translational invariance, which occurs for any sample and which, at the critical point, is not recovered even after the disorder average.

Published

2008

44. Correlation functions of the one-dimensional attractive Bose gas.

Author

Calabrese P and Caux JS

Abstract

The zero-temperature correlation functions of the one-dimensional attractive Bose gas with a delta-function interaction are calculated analytically for any value of the interaction parameter and number of particles, directly from the integrability of the model. We point out a number of interesting features, including zero recoil energy for a large number of particles, analogous to the Mössbauer effect.

Published

2007

45. Time dependence of correlation functions following a quantum quench.

Author

Calabrese P and Cardy J

Abstract

We show that the time dependence of correlation functions in an extended quantum system in d dimensions, which is prepared in the ground state of some Hamiltonian and then evolves without dissipation according to some other Hamiltonian, may be extracted using methods of boundary critical phenomena in d + 1 dimensions. For d = 1 particularly powerful results are available using conformal field theory. These are checked against those available from solvable models. They may be explained in terms of a picture, valid more generally, whereby quasiparticles, entangled over regions of the order of the correlation length in the initial state, then propagate classically through the system.

Published

2006

46. Spin models with random anisotropy and reflection symmetry.

Author

Calabrese P, Pelissetto A, and Vicari E

Abstract

We study the critical behavior of a general class of cubic-symmetric spin systems in which disorder preserves the reflection symmetry s(a) --> -s(a) , s(b) --> s(b) for b not equala . This includes spin models in the presence of random cubic-symmetric anisotropy with probability distribution vanishing outside the lattice axes. Using nonperturbative arguments we show the existence of a stable fixed point corresponding to the random-exchange Ising universality class. The field-theoretical renormalization-group flow is investigated in the framework of a fixed-dimension expansion in powers of appropriate quartic couplings, computing the corresponding beta functions to five loops. This analysis shows that the random Ising fixed point is the only stable fixed point that is accessible from the relevant parameter region. Therefore, if the system undergoes a continuous transition, it belongs to the random-exchange Ising universality class. The approach to the asymptotic critical behavior is controlled by scaling corrections with exponent Delta= -alpha(r) , where alpha(r) approximately -0.05 is the specific-heat exponent of the random-exchange Ising model.

Published

2004

47. Crossover behavior in three-dimensional dilute spin systems.

Author

Calabrese P, Parruccini P, Pelissetto A, and Vicari E

Abstract

We study the crossover behaviors that can be observed in the high-temperature phase of three-dimensional dilute spin systems, using a field-theoretical approach. In particular, for randomly dilute Ising systems we consider the Gaussian-to-random and the pure-Ising-to-random crossover, determining the corresponding crossover functions for the magnetic susceptibility and the correlation length. Moreover, for the physically interesting cases of dilute Ising, XY, and Heisenberg systems, we estimate several universal ratios of scaling-correction amplitudes entering the high-temperature Wegner expansion of the magnetic susceptibility, of the correlation length, and of the zero-momentum quartic couplings.

Published

2004

48. Three-dimensional randomly dilute Ising model: Monte Carlo results.

Author

Calabrese P, Martín-Mayor V, Pelissetto A, and Vicari E

Abstract

We perform a high-statistics simulation of the three-dimensional randomly dilute Ising model on cubic lattices L3 with L< or =256. We choose a particular value of the density, x=0.8, for which the leading scaling corrections are suppressed. We determine the critical exponents, obtaining nu=0.683(3), eta=0.035(2), beta=0.3535(17), and alpha=-0.049(9), in agreement with previous numerical simulations. We also estimate numerically the fixed-point values of the four-point zero-momentum couplings that are used in field-theoretical fixed-dimension studies. Although these results somewhat differ from those obtained using perturbative field theory, the field-theoretical estimates of the critical exponents do not change significantly if the Monte Carlo result for the fixed point is used. Finally, we determine the six-point zero-momentum couplings, relevant for the small-magnetization expansion of the equation of state, and the invariant amplitude ratio R(+)(xi) that expresses the universality of the free-energy density per correlation volume. We find R(+)(xi)=0.2885(15).

Published

2003

49. Dynamic structure factor of the three-dimensional Ising model with purely relaxational dynamics.

Author

Calabrese P, Martín-Mayor V, Pelissetto A, and Vicari E

Abstract

We compute the dynamic structure factor for the three-dimensional Ising model with a purely relaxational dynamics (model A). We perform a perturbative calculation in the epsilon expansion, at two loops in the high-temperature phase and at one loop in the temperature magnetic-field plane, and a Monte Carlo simulation in the high-temperature phase. We find that the dynamic structure factor is very well approximated by its mean-field Gaussian form up to moderately large values of frequency omega and momentum k. In the region we can investigate, k(xi) less than or equal 5, omega(tau) less than or equal 10, where xi is the correlation length and tau is the zero-momentum autocorrelation time, deviations are at most of a few percent.

Published

2003

50. Two-loop critical fluctuation-dissipation ratio for the relaxational dynamics of the O(N) Landau-Ginzburg Hamiltonian.

Author

Calabrese P and Gambassi A

Abstract

The off-equilibrium purely dissipative dynamics (model A) of the O(N) vector model is considered at criticality in an epsilon=4-d>0 expansion up to O(epsilon(2)). The scaling behavior of two-time response and correlation functions at zero momentum, the associated universal scaling functions and the nontrivial limit of the fluctuation-dissipation ratio are determined in the aging regime.

Published

2002