54 research outputs found
Chaos in the thermodynamic Bethe ansatz
We investigate the discretized version of the thermodynamic Bethe ansatz
equation for a variety of 1+1 dimensional quantum field theories. By computing
Lyapunov exponents we establish that many systems of this type exhibit chaotic
behaviour, in the sense that their orbits through fixed points are extremely
sensitive with regard to the initial conditions.Comment: 10 pages, Late
Entanglement entropy of highly degenerate states and fractal dimensions
We consider the bipartite entanglement entropy of ground states of extended
quantum systems with a large degeneracy. Often, as when there is a
spontaneously broken global Lie group symmetry, basis elements of the
lowest-energy space form a natural geometrical structure. For instance, the
spins of a spin-1/2 representation, pointing in various directions, form a
sphere. We show that for subsystems with a large number m of local degrees of
freedom, the entanglement entropy diverges as (d/2) log m, where d is the
fractal dimension of the subset of basis elements with nonzero coefficients. We
interpret this result by seeing d as the (not necessarily integer) number of
zero-energy Goldstone bosons describing the ground state. We suggest that this
result holds quite generally for largely degenerate ground states, with
potential applications to spin glasses and quenched disorder.Comment: 5 pages. v2: Small changes, published versio
Two-Point Functions of Composite Twist Fields in the Ising Field Theory
All standard measures of bipartite entanglement in one-dimensional quantum
field theories can be expressed in terms of correlators of branch point twist
fields, here denoted by and . These are
symmetry fields associated to cyclic permutation symmetry in a replica theory
and having the smallest conformal dimension at the critical point. Recently,
other twist fields (composite twist fields), typically of higher dimension,
have been shown to play a role in the study of a new measure of entanglement
known as the symmetry resolved entanglement entropy. In this paper we give an
exact expression for the two-point function of a composite twist field that
arises in the Ising field theory. In doing so we extend the techniques
originally developed for the standard branch point twist field in free theories
as well as an existing computation due to Horv\'ath and Calabrese of the same
two-point function which focused on the leading large-distance contribution. We
study the ground state two-point function of the composite twist field
and its conjugate . At criticality,
this field can be defined as the leading field in the operator product
expansion of and the disorder field . We find a general
formula for
and for (the derivative of) its analytic continuation to positive real replica
numbers greater than 1. We check our formula for consistency by showing that at
short distances it exactly reproduces the expected conformal dimensionComment: 25 pages and 3 figure
Conductance from Non-perturbative Methods II
This talk provides a natural continuation of the talk presented by Andreas
Fring in this conference. Part I was focused on explaining how the DC
conductance for a free Fermion theory in the presence of different kinds of
defects can be computed by evaluating the Kubo formula. In this talk I will
focus on an alternative method for the computation of the same quantity, that
is the evaluation of Landauer formula. Once again, the integrability of the
theories under consideration will be exploited, since a thermodynamic Bethe
ansatz analysis provides all the input needed in that case, apart from the
corresponding reflection and transmition amplitudes of the defect. The basic
conclusion of our analysis will be the perfect agreement between the two
different theoretical descriptions mentioned.Comment: 17 pages of latex, 5 figures. Talk held at the Workshop on Integrable
Theories, Solitons and Duality IFT-UNESP, Sao Paulo, July 200
Form Factors and Correlation Functions of -Deformed Integrable Quantum Field Theories
The study of -perturbed quantum field
theories is an active area of research with deep connections to fundamental
aspects of the scattering theory of integrable quantum field theories,
generalised Gibbs ensembles, and string theory. Many features of these
theories, such as the peculiar behaviour of their ground state energy and the
form of their scattering matrices, have been studied in the literature.
However, so far, very few studies have approached these theories from the
viewpoint of the form factor program. From the perspective of scattering
theory, the effects of a perturbation (and
higher spin versions thereof) is encoded in a universal deformation of the
two-body scattering matrix by a CDD factor. It is then natural to ask how these
perturbations influence the form factor equations and, more generally, the form
factor program. In this paper, we address this question for free theories,
although some of our results extend more generally. We show that the form
factor equations admit general solutions and how these can help us study the
distinct behaviour of correlation functions at short distances in theories
perturbed by irrelevant operators.Comment: 29 Pages and 4 Figure
Completing the Bootstrap Program for -Deformed Massive Integrable Quantum Field Theories
In recent years a considerable amount of attention has been devoted to the
investigation of 2D quantum field theories perturbed by certain types of
irrelevant operators. These are the composite field
- constructed out of the components of the
stress-energy tensor - and its generalisations - built from higher-spin
conserved currents. The effect of such perturbations on the infrared and
ultraviolet properties of the theory has been extensively investigated. In the
context of integrable quantum field theories, a fruitful perspective is that of
factorised scattering theory. In fact, the above perturbations were shown to
preserve integrability. The resulting deformed scattering matrices -
extensively analysed with the thermodynamic Bethe ansatz - provide the first
step in the development of a complete bootstrap program. In this letter we
present a systematic approach to computing matrix elements of operators in
generalised -perturbed models, based on employing
the standard form factor program. Our approach is very general and can be
applied to all theories with diagonal scattering. We show that the deformed
form factors, just as happens for the -matrix, factorise into the product of
the undeformed ones and of a perturbation- and theory-dependent term. From
these solutions, correlation functions can be obtained and their asymptotic
properties studied. Our results set the foundations of a new research program
for massive integrable quantum field theory perturbed by irrelevant operators.Comment: 5 pages (letter), 3 pages (supplementary material), 1 figure. Version
2 contains 5 additional reference
Entanglement of Stationary States in the Presence of Unstable Quasiparticles
The effect of unstable quasiparticles in the out-of-equilibrium dynamics of
certain integrable systems has been the subject of several recent studies. In
this paper we focus on the stationary value of the entanglement entropy
density, its growth rate, and related functions, after a quantum quench. We
consider several quenches, each of which is characterised by a corresponding
squeezed coherent state. In the quench action approach, the coherent state
amplitudes become input data that fully characterise the large-time
stationary state, thus also the corresponding Yang-Yang entropy. We find that,
as function of the mass of the unstable particle, the entropy growth rate has a
global minimum signalling the depletion of entropy that accompanies a slowdown
of stable quasiparticles at the threshold for the formation of an unstable
excitation. We also observe a separation of scales governed by the interplay
between the mass of the unstable particle and the quench parameter, separating
a non-interacting regime described by free fermions from an interacting regime
where the unstable particle is present. This separation of scales leads to a
double-plateau structure of many functions, where the relative height of the
plateaux is related to the ratio of central charges of the UV fixed points
associated with the two regimes, in full agreement with conformal field theory
predictions. The properties of several other functions of the entropy and its
growth rate are also studied in detail, both for fixed quench parameter and
varying unstable particle mass and viceversa
Higher particle form factors of branch point twist fields in integrable quantum field theories
In this paper we compute higher particle form factors of branch point twist
fields. These fields were first described in the context of massive
1+1-dimensional integrable quantum field theories and their correlation
functions are related to the bi-partite entanglement entropy. We find analytic
expressions for some form factors and check those expressions for consistency,
mainly by evaluating the conformal dimension of the corresponding twist field
in the underlying conformal field theory. We find that solutions to the form
factor equations are not unique so that various techniques need to be used to
identify those corresponding to the branch point twist field we are interested
in. The models for which we carry out our study are characterized by staircase
patterns of various physical quantities as functions of the energy scale. As
the latter is varied, the beta-function associated to these theories comes
close to vanishing at several points between the deep infrared and deep
ultraviolet regimes. In other words, renormalisation group flows approach the
vicinity of various critical points before ultimately reaching the ultraviolet
fixed point. This feature provides an optimal way of checking the consistency
of higher particle form factor solutions, as the changes on the conformal
dimension of the twist field at various energy scales can only be accounted for
by considering higher particle form factor contributions to the expansion of
certain correlation functions.Comment: 25 pages, 4 figures; v2 contains small correction
Tails of instability and decay:A hydrodynamic perspective
In the context of quantum field theory (QFT), unstable particles are associated with complex-valued poles of two-body scattering matrices in the unphysical sheet of rapidity space. The Breit-Wigner formula relates this pole to the mass and life-time of the particle, observed in scattering events. In this paper, we uncover new, dynamical signatures of unstable excitations and show that they have a strong effect on the non-equilibrium properties of QFT. Focusing on a 1+1D integrable model, and using the theory of Generalized Hydrodynamics, we study the formation and decay of unstable particles by analysing the release of hot matter into a low-temperature environment. We observe the formation of tails and the decay of the emitted nonlinear waves, in sharp contrast to the situation without unstable excitations. We also uncover a new phenomenon by which a wave of a stable population of unstable particles may persist without decay for long times. We expect these signatures of the presence of unstable particles to have a large degree of universality. Our study shows that the out-of-equilibrium dynamics of many-body systems can be strongly affected not only by the spectrum, but also by excitations with finite life-times.</p
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