Intra-Pulse Intensity Noise Shaping by Saturable Absorbers

TL;DR

This paper investigates how saturable absorbers influence intra-pulse intensity noise shaping in mode-locked lasers, combining theoretical modeling with experimental validation to enable quantum-limited noise suppression.

Contribution

It introduces a theoretical model describing intra-pulse noise transfer functions and demonstrates experimental methods for characterizing and utilizing intra-pulse noise distributions.

Findings

Intra-pulse noise is linked to self-amplitude modulation in mode-locked lasers.

Theoretical models accurately predict intra-pulse noise transfer functions.

Experimental verification confirms the potential for quantum-limited noise suppression.

Abstract

In this work, we identify and characterize intra-pulse intensity noise shaping by saturable absorbers applied in mode-locked lasers and ultra-low noise nonlinear fiber amplifiers. Reshaped intra-pulse intensity noise distributions are shown to be inevitably interconnected with self-amplitude modulation, the fundamental physical mechanism for initiation and stabilization of ultra-short pulses in the steady-state of a mode-locked laser. A theoretical model is used to describe the ultrafast saturation dynamics by an intra-pulse noise transfer function for widely-applied slow and fast saturable absorbers. For experimental verification of the theoretical results, spectrally-resolved relative intensity noise measurements are applied on chirped input pulses to enable the direct measurement of intra-pulse noise transfer functions using a versatile experimental platform. It is further demonstrated, how the characterized intra-pulse intensity noise distribution of ultrafast laser systems can be utilized for quantum-limited intensity noise suppression via tailored optical bandpass filtering.