Quantum states of dark solitons in the 1D Bose gas
Jun Sato, Rina Kanamoto, Eriko Kaminishi, Tetsuo Deguchi
TL;DR
This paper introduces quantum states called quantum dark soliton states in a 1D Bose gas, demonstrating their classical-quantum correspondence and infinite lifetime in the weak coupling limit.
Contribution
It constructs and analyzes quantum dark soliton states in the 1D Bose gas, revealing their classical-like behavior and infinite lifetime as coupling approaches zero.
Findings
Quantum and classical density profiles overlap over time.
Profiles of the bosonic field operator match classical soliton profiles.
Lifetime of the quantum dark soliton states diverges as coupling approaches zero.
Abstract
We present a series of quantum states that are characterized by dark solitons of the nonlinear Schr\"{o}dinger equation (i.e. the Gross-Pitaevskii equation) for the one-dimensional (1D) Bose gas interacting through the repulsive delta-function potentials. The classical solutions satisfy the periodic boundary conditions and we call them periodic dark solitons. Through exact solutions we show corresponding aspects between the states and the solitons in the weak coupling case: the quantum and classical density profiles completely overlap with each other not only at an initial time but also at later times over a long period of time, and they move together with the same speed in time; the matrix element of the bosonic field operator between the quantum states has exactly the same profiles of the square amplitude and the phase as the classical complex scalar field of a periodic dark soliton…
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