Impact of Intracavity Power Variations toward Ultrashort Pulse Generation

This study demonstrates a passive mode-locked erbium-doped fiber laser with a graphene nanoplatelet-saturable absorber (GNP-SA) that generates ultrashort pulses within femtosecond pulse duration. The GNP-SA is fabricated via a direct transfer approach by mechanically exfoliated graphene on a fiber ferrule. Its characteristics include 0.8% modulation depth, 8.7 MW/cm(2) saturation fluence, and 36.8% absorbance. The quality of ultrashort pulses is studied with a variation of intracavity circulating powers that is controlled through an optical coupler. By changing the light intensity in the cavity, the optical amplification property in the erbium-doped fiber is also impacted. The increment of the output coupling ratio increases the population inversion in the active gain medium, which leads to the change of lasing wavelength from 1558 to 1532 nm. Using a 50% output coupling ratio, the fiber laser generates 960 fs pulse duration, 11.08 MHz repetition rate, and 6.05 mW output power. This study contributes to the understanding of oscillating light behavior while changing its intracavity power that affects the optical amplification properties.

Automated summary

This study presents a passive mode-locked erbium-doped fiber laser using a graphene nanoplatelet-saturable absorber (GNP-SA) to generate femtosecond pulses. The output coupling ratio and intracavity power have been found to affect the optical amplification properties and lasing wavelength of the fiber laser. The results contribute to the understanding of the behavior of oscillating light under varying intracavity power.