Abstract
In sufficiently strong scattering media, light transport is suppressed and modes are exponentially localized. Anderson-like localized states have long been recognized as potential candidates for high- Q optical modes for low-threshold, cost-effective random lasers. Operating in this regime remains, however, a challenge since Anderson localization is difficult to achieve in optics, and nonlinear mode interaction compromises its observation. Here, we exhibit individually each lasing mode of a low-dimension solid-state random laser by applying a non-uniform optical gain. By undoing gain competition and cross-saturation, we demonstrate that all lasing modes are spatially localized. We find that selective excitation significantly reduces the lasing threshold, while lasing efficiency is greatly improved. We show further how their spatial locations are critical to boost laser power efficiency. By efficiently suppressing the spatial hole burning effect, we can turn on the optimally outcoupled random lasing modes. Our demonstration opens the road to the exploration of linear and nonlinear mode interactions in the presence of gain, as well as disorder-engineering for laser applications.
Highlights
Light transport in strongly scattering disordered systems is governed by the nature of the underlying eigenmodes, their spatial extension within the scattering medium
We investigate random lasing in a strongly scattering active medium and demonstrate disorder-induced Anderson localization of lasing modes
We propose to pump non-uniformly the random laser to force it in singlemode operation
Summary
Light transport in strongly scattering disordered systems is governed by the nature of the underlying eigenmodes, their spatial extension within the scattering medium. We investigate random lasing in a strongly scattering active medium and demonstrate disorder-induced Anderson localization of lasing modes. We expect the spatially-modulated pump intensity to excite selectively a particular lasing mode, while rejecting all others below threshold.
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