Light Transport and Localization in Diffusive Random Lasers

TL;DR

This paper presents an analytical theory for diffusive random lasers, linking wave transport in disordered media with laser dynamics, revealing new length scales and the importance of surface loss for stable lasing.

Contribution

It introduces a novel length scale related to mode size and emphasizes the role of surface loss in stabilizing random laser operation.

Findings

Derived a new length scale for lasing modes.

Showed surface loss is crucial for stationary lasing.

Predicted intensity correlation length dependence on pump rate.

Abstract

We develop an analytical theory for diffusive random lasers by coupling the transport theory of the disordered medium to the semiclassical laser rate equations, accounting for (coherent) stimulated and (incoherent) spontaneous emission. From the causality of wave propagation in an amplifying, diffusive medium we derive a novel length scale which we identify with the average mode radius of the lasing quasi-modes. We show further that loss at the surface of the laser-active medium is crucial in order to stabilize a stationary lasing state. The solution of the transport theory of random lasers for a layer geometry with appropriate surface boundary conditions yields the spatial profile of the light intensity and of the population inversion. The dependence of the intensity correlation length on the pump rate is in qualitative agreement with experimental and numerical findings.