On the coupled Maxwell-Bloch system of equations with non-decaying fields at infinity

TL;DR

This paper develops an inverse scattering transform for a coupled Maxwell-Bloch system with non-decaying fields, enabling analysis of solitons and optical phenomena like slow and stopped light in integrable models.

Contribution

It formulates an IST for the coupled Maxwell-Bloch equations with non-vanishing boundary conditions, extending integrability and spectral analysis to finite-width atomic transitions.

Findings

Derived soliton solutions and analyzed their stability.

Identified dark states that do not interact with certain pulses.

Extended the inverse scattering method to non-zero boundary conditions.

Abstract

We study an initial-boundary-value problem (IBVP) for a system of coupled Maxwell-Bloch equations (CMBE) that model two colors or polarizations of light resonantly interacting with a degenerate, two-level, active optical medium with an excited state and a pair of degenerate ground states. We assume that the electromagnetic field approaches non-vanishing plane waves in the far past and future. This type of interaction has been found to underlie nonlinear optical phenomena including electromagnetically induced transparency, slow light, stopped light, and quantum memory. Under the assumptions of unidirectional, lossless propagation of slowly-modulated plane waves, the resulting CMBE become completely integrable in the sense of possessing a Lax Pair. In this paper, we formulate an inverse scattering transform (IST) corresponding to these CMBE and their Lax pair, allowing for the spectral line of the atomic transitions in the active medium to have a finite width. The scattering problem for this Lax pair is the same as for the Manakov system. The main advancement in this IST for CMBE is calculating the nontrivial spatial propagation of the spectral data and determining the state of the optical medium in the distant future from that in the distant past, which is needed for the complete formulation of the IBVP. The Riemann-Hilbert problem is used to extract the spatio-temporal dependence of the solution from the evolving spectral data. We further derive and analyze several types of solitons and determine their velocity and stability, as well as find dark states of the medium which fail to interact with a given pulse.