Sensitivity and spectral control of network lasers

TL;DR

This paper demonstrates that network lasers exhibit high sensitivity to pump profiles and can be spectrally programmed, enabling advanced control over lasing modes for integrated photonic applications.

Contribution

It introduces a theoretical and experimental framework showing spectral control of network lasers via pump shaping, leveraging network complexity for efficient mode selection.

Findings

High sensitivity of network lasers to pump profile variations.

Selective lasing of approximately 90% of top modes.

Effective spectral programming through non-uniform pumping.

Abstract

Recently, random lasing in complex networks has shown efficient lasing over more than 50 localised modes, promoted by multiple scattering over the underlying graph. If controlled, these network lasers can lead to fast-switching multifunctional light sources with synthesised spectrum. Here, we observe both in experiment and theory high sensitivity of the network laser to the spatial shape of the pump profile, with mode intensity variation of up to 280% for a non-homogeneous 7% pump decrease. We solve the nonlinear equations within the steady state ab-initio laser theory (SALT) approximation over a graph and we show selective lasing of around 90% of the top modes, effectively programming the spectrum of the lasing networks. In our experiments with polymer networks, this high sensitivity enables control of the lasing spectrum through non-uniform pump patterns. We propose the underlying complexity of the network modes as the key element behind efficient spectral control opening the way for the development of optical devices with wide impact for on-chip photonics for communication, sensing and computation.