Wavefront Shaping of the Pump in Multimode Fiber Amplifiers; The Gain-Dependent Transmission Matrix

TL;DR

This paper introduces a theoretical model for wavefront shaping of pump light in multimode fiber amplifiers, demonstrating how pump shaping influences signal control and revealing physical mechanisms that limit this control.

Contribution

A new theoretical model for the gain-dependent transmission matrix in multimode fiber amplifiers pumped by coherent light is proposed and numerically explored.

Findings

Pump shaping significantly affects the spatial control of amplified light.

Cross-mode interactions are crucial for understanding signal sensitivity.

Physical mechanisms limit the extent of pump-based control.

Abstract

Wavefront shaping techniques allow the control of the transport of light through many types of scattering or complex media, among them multimode fibers. The case of a multimode fiber which is also a gain medium presents further intriguing prospects for control, due to the possibility of wavefront shaping not only the signal light amplified by the medium, but also the pump light absorbed within it. Provided that the lightwave used for pumping is coherent, its shaping prior to injection will affect the complex, speckle-like spatial patterns of excitation within the amplifier volume, which in turn will act upon the signal as heterogeneous gain. We introduce a new theoretical model which captures the essential features of a multimode amplifying fiber pumped by a coherent beam with configurable modal content, allowing the calculation of the gain-dependent transmission matrix. We numerically implement our model to explore the extent to which one may control the amplified light in the spatial-domain, by shaping the pump; we demonstrate a significant ability of manipulation, as well as several interesting physical mechanisms limiting it. In particular, we show how taking into account the cross-contributions between all guided modes within the fiber is essential for understanding the full range of the signal sensitivity to the choice of pump shaping.