Self-induced transparency and optical transients in atomic vapors

TL;DR

This paper investigates the transient oscillations and formation of damped solitons in atomic vapors triggered by rapid turn-on of strong resonant laser fields, using theoretical models and Maxwell-Bloch equations.

Contribution

It provides a detailed theoretical analysis of transient dynamics, including damped solitons and simultons, in rubidium vapor with full hyperfine structure considerations.

Findings

Transient oscillations resemble trains of damped solitons.

Doubly resonant V-systems produce trains of damped simultons.

Comparison shows agreement with stationary dnoidal fields under certain conditions.

Abstract

The rapid turn-on of a strong, resonant, continuous wave laser field may trigger the formation of a transient oscillation akin to a train of damped solitons, before the vapor-field system relaxes into a stationary state. We study this transient dynamic on theoretical models of a rubidium vapor. We also consider doubly resonant V-systems, for which the transients take the form of trains of damped simultons. We compute the propagating field(s) by solving the Maxwell-Bloch equations, taking homogeneous broadening, Doppler broadening and the full hyperfine structure of the atoms into account. We also compare the actual fields to the stationary dnoidal fields predicted by the Maxwell-Bloch equations in conditions of self-induced transparency. A similar dynamics is expected to occur in any atomic vapor at the turn-on of a strong resonant continuous wave field provided the turn-on is sufficiently fast compared to relaxation.