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Kinetics of Quantum Reaction-Diffusion systems

by Federico Gerbino, Igor Lesanovsky, Gabriele Perfetto

Submission summary

Authors (as registered SciPost users): Federico Gerbino · Gabriele Perfetto
Submission information
Preprint Link: https://arxiv.org/abs/2406.20028v2  (pdf)
Date accepted: 2024-12-18
Date submitted: 2024-12-06 10:54
Submitted by: Gerbino, Federico
Submitted to: SciPost Physics Core
Ontological classification
Academic field: Physics
Specialties:
  • Atomic, Molecular and Optical Physics - Theory
  • Statistical and Soft Matter Physics
Approach: Theoretical

Abstract

We discuss many-body fermionic and bosonic systems subject to dissipative particle losses in arbitrary spatial dimensions $d$, within the Keldysh path-integral formulation of the quantum master equation. This open quantum dynamics represents a generalisation of classical reaction-diffusion dynamics to the quantum realm. We first show how initial conditions can be introduced in the Keldysh path integral via boundary terms. We then study binary annihilation reactions $A+A\to\emptyset$, for which we derive a Boltzmann-like kinetic equation. The ensuing algebraic decay in time for the particle density depends on the particle statistics. In order to model possible experimental implementations with cold atoms, for fermions in $d=1$ we further discuss inhomogeneous cases involving the presence of a trapping potential. In this context, we quantify the irreversibility of the dynamics studying the time evolution of the system entropy for different quenches of the trapping potential. We find that the system entropy features algebraic decay for confining quenches, while it saturates in deconfined scenarios.

Current status:
Accepted in target Journal

Editorial decision: For Journal SciPost Physics Core: Publish
(status: Editorial decision fixed and (if required) accepted by authors)

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