Dynamical Many-Body Localization in an Integrable Model

We derive an exact formula for the scaled cumulant generating function of the time-integrated current associated to an arbitrary ballistically transported conserved charge. Our results rely on the Euler-scale description of interacting, many-body, integrable models out of equilibrium given by the generalized hydrodynamics, and on the large deviation theory. Crucially, our findings extend previous studies by accounting for inhomogeneous and dynamical initial states in interacting systems. We present exact expressions for the first three cumulants of the time-integrated current. Considering the non-interacting limit of our general expression for the scaled cumulant generating function, we further show that for the partitioning protocol initial state our result coincides with previous results of the literature. Given the universality of the generalized hydrodynamics, the expression obtained for the scaled cumulant generating function is applicable to any interacting integrable model obeying the hydrodynamic equations, both classical and quantum.

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The importance of being integrable: Out of the paper, into the lab

International Journal of Modern Physics B ◽

10.1142/s0217979214300102 ◽

2014 ◽

Vol 28 (18) ◽

pp. 1430010 ◽

Cited By ~ 5

Author(s):

Murray T. Batchelor

Keyword(s):

Quantum Physics ◽

Three Dimensional ◽

Integrable Model ◽

Theoretical Physics ◽

Many Body ◽

One Dimensional ◽

S Matrix ◽

Many Body Systems ◽

Low Dimensional ◽

Traditional Setting

The scattering matrix (S-matrix), relating the initial and final states of a physical system undergoing a scattering process, is a fundamental object in quantum mechanics and quantum field theory. The study of factorized S-matrices, in which many-body scattering factorizes into a product of two-body terms to yield an integrable model, has long been considered the domain of mathematical physics. Many beautiful results have been obtained over several decades for integrable models of this kind, with far reaching implications in both mathematics and theoretical physics. The viewpoint that these were only toy models changed dramatically with brilliant experimental advances in realizing low-dimensional quantum many-body systems in the lab. These recent experiments involve both the traditional setting of condensed matter physics and the trapping and cooling of atoms in optical lattices to engineer and study quasi-one-dimensional systems. In some cases the quantum physics of one-dimensional systems is arguably more interesting than their three-dimensional counterparts, because the effect of interactions is more pronounced when atoms are confined to one dimension. This article provides a brief overview of these ongoing developments, which highlight the fundamental importance of integrability.

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QUANTUM INTEGRABLE SYSTEM WITH MULTI-COMPONENTS IN TWO DIMENSIONS

Modern Physics Letters B ◽

10.1142/s021798490200441x ◽

2002 ◽

Vol 16 (23n24) ◽

pp. 871-883

Author(s):

MU-LIN YAN ◽

BAO-HENG ZHAO

Keyword(s):

Body Problem ◽

Integrable Model ◽

Two Dimensions ◽

One Dimension ◽

Two Dimensional ◽

Dimensional Problem ◽

Many Body ◽

One Dimensional ◽

N Body Problem ◽

Color Components

A quantum N-body problem with 2-component in (2 + 1) dimensions deduced from an integrable model in (2 + 1) dimensions is investigated. The Davey–Stewartson 1 (DS1) system9 is an integrable model in two dimensions. A quantum DS1 system with 2 color components in two dimensions has been formulated. This two-dimensional problem has been reduced to two one-dimensional many-body problems with 2 color components. The solutions of the two-dimensional problem under consideration has been constructed from the resulting problems in one dimension. For the latter with δ-function interactions and being solved by the Bethe–Yang ansatz, we introduce symmetrical and anti-symmetrical Young operators of the permutation group and obtain the exact solutions for the quantum DS1 system. The application of the solutions is discussed.

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