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Gain-controlled broadband tuneability in self-mode-locked Thulium-doped fibre laser

Dennis C. Kirsch, Anastasia Bednyakova, Petr Vařák, Pavel Honzátko, Benoît Cadier, Thierry Robin, Andrei A. Fotiadi, Pavel Peterka, Maria Chernysheva

2022Communications Physics29 citationsDOIOpen Access PDF

Abstract

Abstract Ensuring self-driven mode-locking and broadband wavelength tuneability in all-fibre-integrated femtosecond laser sources enables a new level of their versatility and extends areas of their applications. Principle limitations for this are traditionally available ultrafast modulators and tuneability techniques. Here, we exploit Thulium-doped fibre to perform three roles in the cavity: laser gain, saturable absorber, and tuneability element via controlling its excitation level. We confirmed that Tm-doped fibre saturable absorption is defined by a reinforced quenching of Tm 3+ pairs. As a result, we present both numerically and experimentally a highly stable sub-picosecond pulse generation with a ~90 nm tuneability range spanning from 1873 to 1962 nm via adjusting the cavity feedback. The maximum laser efficiency corresponds to 25% cavity feedback, enabling the highest output energy of 1 nJ in 600-fs solitons at 1877 nm. Overall, the presented laser system establishes a compact and straightforward approach for ultrafast generation, which can be translated to other fibre laser operation wavelengths.

Topics & Concepts

Materials scienceUltrashort pulseLaserFiber laserSaturable absorptionOpticsPicosecondFemtosecondOptoelectronicsMode-lockingBroadbandOptical cavityThuliumDopingWavelengthPhysicsAdvanced Fiber Laser TechnologiesPhotonic Crystal and Fiber OpticsLaser-Matter Interactions and Applications
Gain-controlled broadband tuneability in self-mode-locked Thulium-doped fibre laser | Litcius