Robust mode-locking in a hybrid ultrafast laser based on nonlinear multimodal interference

TL;DR

This paper demonstrates a robust mode-locked fiber laser using a nonlinear multimodal interference saturable absorber, achieving stable ultrafast pulses with improved noise performance compared to conventional methods.

Contribution

It introduces a novel half-PM fiber laser design with a reflective multimode-interference saturable absorber for stable ultrafast pulse generation.

Findings

Generated 409 fs soliton pulses at 33.3 MHz

Achieved stable mode-locking with superior noise performance

Compared favorably to conventional NPE mode-locking

Abstract

We experimentally demonstrate the realization of a half-polarization-maintaining (half-PM) fiber laser, in which mode-locking is provided by a reflective multimode-interference saturable absorber (SA). In the specially designed SA, linearly polarized light is coupled into a 15-cm-long graded-index multimode fiber (GIMF) through the PM fiber, and then reflected back to the PM structure through a mirror pigtailed with a single-mode fiber (SMF). The modulation depth and saturation peak power are measured to be 1.5% and 0.6 W, respectively. The proposed SA device is incorporated into a novel half-PM erbium-doped fiber oscillator, which generates soliton pulses with 409 fs temporal duration at a 33.3 MHz repetition rate. The proposed fiber laser is compared with a conventional non-PM fiber laser mode-locked by nonlinear polarization evolution (NPE) in terms of optical properties such as spectral bandwidth, pulse duration, and stability performance. Short- and long-time stability tests and superior noise performance corroborate robust mode-locking in this setup.