Many-body localization in Fock space: A local perspective

We present a semiclassical approach to many-body quantum propagation in terms of coherent sums over quantum amplitudes associated with the solutions of corresponding classical nonlinear wave equations. This approach adequately describes interference effects in the many-body space of interacting bosonic systems. The main quantity of interest, the transition amplitude between Fock states when the dynamics is driven by both single-particle contributions and many-body interactions of similar magnitude, is non-perturbatively constructed in the spirit of Gutzwiller’s derivation of the van Vleck propagator from the path integral representation of the time evolution operator, but lifted to the space of symmetrized many-body states. Effects beyond mean-field, here representing the classical limit of the theory, are semiclassically described by means of interfering amplitudes where the action and stability of the classical solutions enter. In this way, a genuinely many-body echo phenomenon, coherent backscattering in Fock space, is presented arising due to coherent quantum interference between classical solutions related by time reversal.

Download Full-text

Distillation of maximally correlated bosonic matter from many-body quantum coherence

Quantum ◽

10.22331/q-2020-09-24-330 ◽

2020 ◽

Vol 4 ◽

pp. 330

Author(s):

Tyler J. Volkoff

Keyword(s):

Quantum Coherence ◽

Particle Number ◽

Fock Space ◽

Continuous Variable ◽

Squeezed States ◽

Discrete Variable ◽

Many Body ◽

Information Theoretic ◽

Bose Einstein ◽

Single Particle Basis

We construct quantum coherence resource theories in symmetrized Fock space (QCRTF), thereby providing an information-theoretic framework that connects analyses of quantum coherence in discrete-variable (DV) and continuous variable (CV) bosonic systems. Unlike traditional quantum coherence resource theories, QCRTF can be made independent of the single-particle basis and allow to quantify coherence within and between particle number sectors. For example, QCRTF can be formulated in such a way that neither Bose-Einstein condensates nor Heisenberg-Weyl coherent states are considered as quantum many-body coherence resources, whereas spin-squeezed and quadrature squeezed states are. The QCRTF framework is utilized to calculate the optimal asymptotic distillation rate of maximally correlated bosonic states both for particle number conserving resource states and resource states of indefinite particle number. In particular, we show how to generate a uniform superposition of maximally correlated bosonic states from a state of maximal bosonic coherence with asymptotically unit efficiency using only free operations in the QCRTF.

Download Full-text

Symplectic Schrödinger equation for many-body systems

International Journal of Modern Physics A ◽

10.1142/s0217751x20500335 ◽

2020 ◽

Vol 35 (06) ◽

pp. 2050033

Author(s):

R. G. G. Amorim ◽

M. C. B. Fernandes ◽

F. C. Khanna ◽

A. E. Santana ◽

J. D. M. Vianna

Keyword(s):

Phase Space ◽

Schrödinger Equation ◽

Schrodinger Equation ◽

Fock Space ◽

Basic Element ◽

Space Representation ◽

Many Body ◽

Many Body Systems ◽

The Green Function ◽

Phase Space Representation

Using elements of symmetry, as gauge invariance, many aspects of a Schrödinger equation in phase space are analyzed. The number (Fock space) representation is constructed in phase space and the Green function, directly associated with the Wigner function, is introduced as a basic element of perturbative procedure. This phase space representation is applied to the Landau problem and the Liouville potential.

Download Full-text

Hybrid nature of the abnormal solutions of the Bethe–Salpeter equation in the Wick–Cutkosky model

The European Physical Journal C ◽

10.1140/epjc/s10052-021-08850-1 ◽

2021 ◽

Vol 81 (1) ◽

Author(s):

J. Carbonell ◽

V. A. Karmanov ◽

H. Sazdjian

Keyword(s):

Schrödinger Equation ◽

Schrodinger Equation ◽

Fock Space ◽

Form Factors ◽

Massless Particle ◽

Ladder Approximation ◽

Many Body ◽

Relativistic Limit ◽

Elastic Form ◽

The Many

AbstractIn the Wick–Cutkosky model, where two scalar massive constituents interact by means of the exchange of a scalar massless particle, the Bethe–Salpeter equation has solutions of two types, called “normal” and “abnormal”. In the non-relativistic limit, the normal solutions correspond to the usual Coulomb spectrum, whereas the abnormal ones do not have non-relativistic counterparts – they are absent in the Schrödinger equation framework. We have studied, in the formalism of the light-front dynamics, the Fock-space content of the abnormal solutions. It turns out that, in contrast to the normal ones, the abnormal states are dominated by the massless exchange particles (by 90 % or more), what provides a natural explanation of their decoupling from the two-body Schrödinger equation. Assuming that one of the massive constituents is charged, we have calculated the electromagnetic elastic form factors of the normal and abnormal states, as well as the transition form factors. The results on form factors confirm the many-body nature of the abnormal states, as found from the Fock-space analysis. The abnormal solutions have thus properties similar to those of hybrid states, made here essentially of two massive constituents and several or many massless exchange particles. They could also be interpreted as the Abelian scalar analogs of the QCD hybrid states. The question of the validity of the ladder approximation of the model is also examined.

Download Full-text