Linear and Nonlinear Pulse Propagations in Lifetime-Broadened Atomic Media with Spontaneously Generated Coherence

TL;DR

This paper theoretically investigates how spontaneously generated coherence affects linear and nonlinear pulse propagation in three-level atomic media, revealing system-dependent effects on dispersion, absorption, and Kerr nonlinearity, enabling stable ultraslow solitons.

Contribution

It provides a comparative analysis of SGC effects in V-, Λ-, and Ξ-type systems, highlighting potential for low-power ultraslow soliton generation in V-type media.

Findings

SGC can eliminate absorption in V-type systems.

SGC enhances Kerr nonlinearity in V-type systems.

Stable ultraslow solitons can be generated with low pump power in V-type media.

Abstract

The linear and nonlinear pulse propagations in lifetime-broadened three-state media with spontaneously generated coherence (SGC) are investigated theoretically. Three generic systems of V-, $\Lambda$-, and $\Xi$-type level configurations are considered and compared. It is shown that in linear propagation regime the SGC in the V-type system can result in a significant change of dispersion and absorption and may be used to completely eliminate the absorption and largely reduce the group velocity of a probe field. However, the SGC has no effect on the dispersion and absorption of the $\Lambda$- and $\Xi$-type systems. In nonlinear propagation regime, the SGC displays different influences on Kerr nonlinearity for different systems. Specifically, it can enhance the Kerr nonlinearity of the V-type system whereas weaken the Kerr nonlinearity of the $\Lambda$-type system. Using the SGC, stable optical solitons with ultraslow propagating velocity and very low pump power can be produced in the V-type system by exploiting only one laser field in the system.