Litcius/Paper detail

Flexible chalcogenide glass large-core multimode fibers for hundred-watt-level mid-infrared 2-5 µm laser transmission

Sisheng Qi, Yuebing Li, Zixuan Huang, He Ren, Wenjuan Sun, Jindan Shi, Fei Wang, Deyuan Shen, Xian Feng, Zhiyong Yang

2022Optics Express22 citationsDOIOpen Access PDF

Abstract

The rapidly-developed high-power mid-infrared 2-5 µm laser technology requires a compact, flexible low-loss glass fiber for power delivery or laser generation. With the broadest bandwidth of low-loss transmission window in mid-infrared region amongst all mid-infrared glass fibers, chalcogenide glass fiber is the best candidate covering the whole 2-5 µm range. Multi-hundred-watt high-power delivery for 5.4-µm CO laser was previously demonstrated in a multimode chalcogenide fiber with a 1-mm-diameter large core, at the cost of giving up one of the most desirable fiber advantages, the flexibility. Indeed, chalcogenide glass fibers with decent flexibility have never exhibited hundred-watt-level power transmitting capability in the 2-5 µm range. In this paper, we have experimentally demonstrated 100-watt-level power transmission in multimode As 2 S 3 chalcogenide fibers, using a customized high-power 2-µm thulium doped silica fiber laser source. With effective forced cooling, the multimode As 2 S 3 fiber with 200 µm core diameter can resist incident laser power of 120 W and deliver transmitted power of 63 W. Nano-sized scattering center related laser damage mechanism and the cylindrical heat transfer model have been proposed to explain the high-power damage process of chalcogenide glass fibers. The calculation is in good agreement with the experiments. It is promising to further enhance the transmitted power above 100 W in flexible chalcogenide glass large-core fibers.

Topics & Concepts

Chalcogenide glassChalcogenideMaterials scienceMulti-mode optical fiberOpticsLaserCore (optical fiber)Fiber laserOptoelectronicsPlastic-clad silica fiberOptical fiberPhotodarkeningPlastic optical fiberComposite materialWavelengthPhysicsPhotonic Crystal and Fiber OpticsSolid State Laser TechnologiesPhase-change materials and chalcogenides