Novel Specialty Optical Fibers and Applications

© 2022 by the authors; CC BY-NC-ND license

optical amplifiers; doped fiber amplifiers; near-infrared; molecular gas spectroscopy; photothermal spectroscopy; heterodyne detection; specialty fiber; anti-resonant effect; hollow structure; sensing applications; orbital angular momentum; optical fiber; fiber mode crosstalk; vortex mode generator; fiber optics; plasmonic gratings; nanodot; light collection; hollow-core fibers; anti-resonant hollow-core fibers; tapered fibers; fiber gas lasers; fiber end cap; SiO₂-Au-TiO₂ heterostructure; long-range surface plasmon resonance; microstructured optical fiber; fiber sensor; photonic crystal fibers; hollow-core fibers; fiber lasers; stimulated Raman scattering; gas Raman lasers; specialty fibers; Brillouin optical time domain analysis; BOTDA; distributed fiber sensor; photonic crystal fiber; strain and temperature sensing; liquid crystal; dual-core photonic crystal fiber; polarization beam splitter; extinction ratio; polarization filter; surface plasmon resonance; photonic crystal fiber; gold-coated; crosstalk; mid-infrared (mid-IR); chalcogenide glasses (ChGs); optical microfibers (MFs); supercontinuum (SC); molecular sensing; Raman spectroscopy; capillary-based hollow core fibers; hollow core photonic crystal fiber; detection; specialty fibers; distributed acoustic sensing; DAS; distributed fiber sensor; scattering enhancement fiber; fiber-optic sensors; few-mode fiber; microfiber; Mach–Zehnder interferometer; critical wavelength; multicore fiber; fiber Bragg grating; long period grating; fiber grating sensors; n/a